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Original commit message from CVS: more notes, getting there
233 lines
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Text
233 lines
12 KiB
Text
ELEMENTS (v4lsrc, alsasrc, osssrc)
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--------
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- capturing elements should not do fps/sample rate correction themselves
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they should timestamp buffers according to "a clock", period.
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- if the element is the clock provider:
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- timestamp buffers based on the internals of the clock it's providing,
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without calling the exposed clock functions
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- do this by getting a measure of elapsed time based on the internal clock
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that is being wrapped. Ie., count the number of samples the *device*
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has processed/dropped/...
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If there are no underruns, the produced buffers are a contiguous data
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stream.
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- possibilities:
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- the device has a method to query for the absolute time related to
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a buffer you're about to capture or just have captured:
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Use that time as the timestamp on the capture buffer
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(it's important that this time is related to the capture buffer;
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ie. it's a time that "stands still" if you're not capturing)
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- since you're providing the clocking, but don't have the previous method,
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you should open the device with a given rate and continuously read
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samples from it, even in PAUSED. This allows you to update an internal
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clock.
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You use this internal clock as well to timestamp the buffers going out,
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so you again form a contiguous set of buffers.
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The only acceptable way to continuously read samples then is in a private
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thread.
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- as long as no underruns happen, the flow being output is a perfect stream:
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the flow is data-contiguous and time-contiguous.
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- underruns should be handled like this:
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- if the code can detect how many samples it dropped, it should just
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send the next buffer with the new correct offset. Ie, it produced
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a data gap, and since it provides the clock, it produces a perfect
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data gap (the timestamp will be correctly updated too).
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- if it cannot detect how many samples it dropped, there's a fallback
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algorithm. The element uses another GstClock (for example, system clock)
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on which it corrects the skew and drift continuously as long as it
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doesn't drop. When it detected a drop, it can get the time delta
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on the other GstClock since the last time it captured and the current
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time, and use that delta to guesstimate the number of samples dropped.
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- if the element is not the clock provider
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- the element should always respect the clock it is given.
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- the element should timestamp outgoing buffers based on time given by
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the provided clock, by querying for the time on that clock, and
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comparing to the base time.
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- the element should NOT drop/add frames. Rather, it should just
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- timestamp the buffers with the current time according to the provided
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clock
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- set the duration according to the *theoretical/nominal* framerate
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- when underruns happen (the device has lost capture data because our
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element is not handling them quickly enough), this should be detectable
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by the element through the device. On underrun, the offset of your
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next buffer will not match the end_offset of your previous one
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(ie, the data flow is no longer contiguous).
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If the exact number of samples dropped is detectable, this is the
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difference between new offset and old offset_end.
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If it's not detectable, it should be guessed based on the elapsed time
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between now and the last capture.
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- a second element can be responsible for making the stream time-contiguous.
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(ie, T1 + D1 = T2 for all buffers). This way they are made
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acceptible for gapless presentation (which is useful for audio).
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- The element treats the incoming stream as data-contiguous but not
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necessarily time-contiguous.
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- If the timestamps are contiguous as well, then everything is fine and
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nothing needs to be done. This is the case where a file is being read
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from disk, or capturing was done by an element that provided the clock.
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- If they are not contiguous, then this element must make them so.
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Since it should respect the nominal framerate, it has to stretch or
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shorten the incoming data to match the timestamps set on the data.
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For audio and video, this means it could interpolate or add/drop samples.
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For audio, resampling/interpolation is preferred.
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For video, a simple mechanism that chooses the frame with a timestamp as
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close as possible to the theoretical timestamp could be used.
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- When it receives a new buffer that is not data-contiguous with the
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previous one, the capture element dropped samples/frames.
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The adjuster can correct this by sending out as much "no-signal" data
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(for audio, e.g. silence or background noise; for video, sending out
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black frames) as it wants, since a data discontinuity is unrepairable.
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So it can use these to catch up more aggressively.
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It should just make sure that the next buffer it gets again goes
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back to respecting the nominal framerate.
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- To achieve the best possible long-time capture, the following can be done:
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- audiosrc captures audio and provides the clock. It does contiguous
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timestamping by default.
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- videosrc captures video timestamped with the audiosrc's clock. This data
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feed doesn't match the nominal framerate. If there is an encoding format
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that supports storing the actual timestamps instead of pretending the
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data flow respects the nominal framerate, this can be corrected after
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recording.
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- at the end of recording, the absolute length in time of both streams,
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measured against a common clock, is the same or can be made the same by
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chopping off data.
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- the nominal rate of both audio and video is also known.
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- given the length and the nominal rate, we have an evenly spaced list
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of theoretical sampling points.
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- video frames can now be matched to these theoretical sampling points by
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interpolating or reusing/dropping frames. It can choose the best
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possible algorithm for this to decrease the visible effects
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(interpolating results in blur, add/drop frames results in jerkiness).
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- with the video resampled at the theoretical framerate, and the audio
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already correct, the recording can now be muxed correctly into a format
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that implicitly assumes a data rate matching the nominal framerate.
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- One possibility is to use the GDP to store the recording, because that
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retains all of the timestamping information.
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- The process is symmetrical; if you want to use the clock provided by
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the video capturer, you can stretch/shrink the audio at the end of
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recording to match.
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TERMINOLOGY
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-----------
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- nominal rate
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the framerate/samplerate
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exposed in the caps; ie. the theoretical framerate of the
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data flow. This is the fps reported by the device or set for the encoder,
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or the sampling rate of the audio device.
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- contiguous data flow
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offset_end of old buffer matches offset of new buffer
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for audio, this is a more important requirement, since you configure
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output devices for a contiguous data flow.
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- contiguous time flow
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T1 + D1 = T2
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for video, this is a more important requirement, because the sampling
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period is bigger, so it is more important to match the presentation time
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- "perfect stream"
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data and time are contiguous and match the nominal rate
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videotestsrc, sinesrc, filesrc ! decoder produce this
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NETWORK
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-------
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- elements can be synchronized by writing a NTP clock subclass that listens
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to an ntp server, and tries to match its own clock against the NTP server
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by doing gradual rate adjustment, compared with the own system clock.
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- sending audio and video over the network using tcpserversink is possible
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when the streams are made to be perfect streams and synchronized.
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Since the streams are perfect and synchronized, the timestamps transmitted
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along with the buffers can be trusted. The client just has to make
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sure that it respects the timestamps.
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- One good way of doing that is to make an element that provides a clock
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based on the timestamps of the data stream, interpolating using another
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GstClock inbetween those time points. This allows you to create
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a perfect network stream player (one that doesn't lag (increasing buffers))
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or play too fast (having an empty network queue).
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- On the client side, a GStreamer-ish way to do that is to cut the playback
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pipeline in half, and have a decoupled element that converts
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timestamps/durations (by resampling/interpolating/...) so that the sinks
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consume data at the same rate the tcp sources provide it.
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tcpclientsrc ! theoradec ! clocker name=clocker { clocker. ! xvimagesink }
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SYNCHRONISATION
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---------------
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- low rate source with high rate source:
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the high rate source can drop samples so it starts with the same phase
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as the low rate source. This could be done in a synchronizer element.
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example:
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- audio, 8000 Hz, and video, 5 fps
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- pipeline goes to playing
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- video src does capture and receives its first frame 50 ms after playing
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-> phase is -90 or 270 degrees
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- to compensate, the equivalent of 150 ms of audio could be dropped so
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that the first videoframe's timestamp coincides with the timestamp of
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the first audio buffer
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- this should be done in the raw audio domain since it's typically not
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possible to chop off samples in the encoded domain
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- two low rate sources:
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not possible to do this correctly, maybe something in the middle can be
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found ?
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IMPROVING QUALITY
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-----------------
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- video src can capture at a higher framerate than will be encoded
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- this gives the corrector more frames to choose from or interpolate with
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to match the target framerate, reducing jerkiness.
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e.g. capturing at 15 fps for 5 fps framerate.
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LIVE CHANGES IN PIPELINE
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------------------------
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- case 1: video recording for some time, user wants to add audio recording on
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the fly
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- user sets complete pipeline to paused
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- user adds element for audio recording
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- new element gets same base time as video element
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- on PLAYING, new element will be in sync and the first buffer produced
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will have a non-zero timestamp that is the same as the first new video
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buffer
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- case 2: video recording for some time, user wants to add in an audio file
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from disk.
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- two possible expectations:
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A) user expects the audio file to "start playing now" and be muxed
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together with the current video frames
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B) user expects the audio file to "start playing from the point where the
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video currently is" (ie, video is at 10 seconds, so mux with audio
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starting from 10 secs)
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- case A):
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- complete pipeline gets paused
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- filesrc ! dec added
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- both get base_time same as video element
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- pipeline to playing
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- all elements receive new "now" as base_time so timestamps are reset
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- muxer will receive synchronized data from both
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- case B):
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nothing gets paused
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- filesrc ! dec added
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- both get base_time that is the current clock time
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- pipeline to playing
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- core sets
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1) - new audio part starts sending out data with timestamp 0 from start
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of file
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- muxer receives a whole set of frames from the audio side that are late
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(since the timestamps start at 0), so keeps dropping until it has
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caught up with the current set).
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OR
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2) - audio part does clock query
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THINGS TO DIG UP
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----------------
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- is there a better way to get at "when was this frame captured" then doing
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a clock query after capturing ?
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Imagine a video device with a hardware buffer of four frames. If you
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haven't asked for a frame from it in a while, three frames could be
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queued up. So three consecutive frame gets result in immediate returns
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with pretty much the same clock query for each of them.
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So we should find a way to get "a comparable clock time" corresponding
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to the captured frame.
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- v4l2 api returns a gettimeofday() timestamp with each buffer.
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Given that, you can timestamp the buffer by subtracting the delta
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between the buffer's clock timestamp with the current system clock time,
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from the current time reported by the provided clock.
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