Trickmodes
GStreamer provides API for performing various trickmode playback. This includes:
-
server side trickmodes
-
client side fast/slow forward playback
-
client side fast/slow backwards playback
Server side trickmodes mean that a source (network source) can provide a stream with different playback speed and direction. The client does not have to perform any special algorithms to decode this stream.
Client side trickmodes mean that the decoding client (GStreamer) performs the needed algorithms to change the direction and speed of the media file.
Seeking can both be done in a playback pipeline and a transcoding pipeline.
General seeking overview
Consider a typical playback pipeline:
+---------+ +------+
+-------+ | decoder |->| sink |
+--------+ | |-->+---------+ +------+
| source |->| demux |
+--------+ | |-->+---------+ +------+
+-------+ | decoder |->| sink |
+---------+ +------+
The pipeline is initially configured to play back at speed 1.0 starting from position 0 and stopping at the total duration of the file.
When performing a seek, the following steps have to be taken by the application:
Create a seek event
The seek event contains:
-
various
GstSeekFlags
flags describing: -
where to seek to (
KEY_UNIT
) -
how accurate the seek should be (
ACCURATE
) -
how to perform the seek (
FLUSH
) -
what to do when the stop position is reached (
SEGMENT
). -
extra playback options (
SKIP
) -
a format to seek in, this can be time, bytes, units (frames, samples), …
-
a playback rate, 1.0 is normal playback speed, positive values bigger than 1.0 mean fast playback. negative values mean reverse playback. A playback speed of 0.0 is not allowed (but is equivalent to PAUSING the pipeline).
-
a start position, this value has to be between 0 and the total duration of the file. It can also be relative to the previously configured start value.
-
a stop position, this value has to be between 0 and the total duration. It can also be relative to the previously configured stop value.
See also gst_event_new_seek()
.
Send the seek event
Send the new seek event to the pipeline with
gst_element_send_event()
.
By default the pipeline will send the event to all sink elements. By
default an element will forward the event upstream on all sinkpads.
Elements can modify the format of the seek event. The most common format
is GST_FORMAT_TIME
.
One element will actually perform the seek, this is usually the demuxer or source element. For more information on how to perform the different seek types see seeking.
For client side trickmode a SEGMENT
event will be sent downstream with
the new rate and start/stop positions. All elements prepare themselves
to handle the rate (see below). The applied rate of the SEGMENT event
will be set to 1.0 to indicate that no rate adjustment has been done.
for server side trick mode a SEGMENT
event is sent downstream with a
rate of 1.0 and the start/stop positions. The elements will configure
themselves for normal playback speed since the server will perform the
rate conversions. The applied rate will be set to the rate that will be
applied by the server. This is done to insure that the position
reporting performed in the sink is aware of the trick mode.
When the seek succeeds, the _send_event()
function will return TRUE.
Server side trickmode
The source element operates in push mode. It can reopen a server connection requesting a new byte or time position and a new playback speed. The capabilities can be queried from the server when the connection is opened.
We assume the source element is derived from the GstPushSrc
base class.
The base source should be configured with:
gst_base_src_set_format (src, GST_FORMAT_TIME);
The do_seek()
method will be called on the GstPushSrc
subclass with the
seek information passed in the GstSegment
argument.
The rate value in the segment should be used to reopen the connection to the server requesting data at the new speed and possibly a new playback position.
When the server connection was successfully reopened, set the rate of the segment to 1.0 so that the client side trickmode is not enabled. The applied rate in the segment is set to the rate transformation done by the server.
Alternatively a combination of client side and serverside trickmode can be used, for example if the server does not support certain rates, the client can perform rate conversion for the remainder.
source server
do_seek | |
----------->| |
| reopen connection |
|-------------------->|
| .
| success .
|<--------------------|
modify | |
rate to 1.0 | |
| |
return | |
TRUE | |
| |
After performing the seek, the source will inform the downstream elements of the new segment that is to be played back. Since the segment will have a rate of 1.0, no client side trick modes are enabled. The segment will have an applied rate different from 1.0 to indicate that the media contains data with non-standard playback speed or direction.
client side forward trickmodes
The seek happens as stated above. a SEGMENT
event is sent downstream
with a rate different from 1.0. Plugins receiving the SEGMENT
can decide
to perform the rate conversion of the media data (retimestamp video
frames, resample audio, …).
If a plugin decides to resample or retimestamp, it should modify the
SEGMENT
with a rate of 1.0 and update the applied rate so that
downstream elements don’t resample again but are aware that the media
has been modified.
The GStreamer base audio and video sinks will resample automatically if they receive a SEGMENT event with a rate different from 1.0. The position reporting in the base audio and video sinks will also depend on the applied rate of the segment information.
When the SKIP
flag is set, frames can be dropped in the elements. If S
is the speedup factor, a good algorithm for implementing frame skipping
is to send audio in chunks of Nms (usually 300ms is good) and then skip
((S-1) * Nns) of audio data. For the video we send only the keyframes
in the (S * Nns) interval. In this case, the demuxer would scale the
timestamps and would set an applied rate of S.
client side backwards trickmode
For backwards playback the following rules apply:
-
the rate in the
SEGMENT
is less than 0.0. -
the
SEGMENT
start position is less than the stop position, playback will however happen from stop to start in reverse. -
the time member in the
SEGMENT
is set to the stream time of the start position.
For plugins the following rules apply:
-
A source plugin sends data in chunks starting from the last chunk of the file. The actual bytes are not reversed. Each chunk that is not forward continuous with the previous chunk is marked with a
DISCONT
flag. -
A demuxer accumulates the chunks. As soon as a keyframe is found, everything starting from the keyframe up to the accumulated data is sent downstream. Timestamps on the buffers are set starting from the stop position to start, effectively going backwards. Chunks are marked with
DISCONT
when they are not forward continuous with the previous buffer. -
A video decoder decodes and accumulates all decoded frames. If a buffer with a
DISCONT
,SEGMENT
orEOS
is received, all accumulated frames are sent downsteam in reverse. -
An audio decoder decodes and accumulates all decoded audio. If a buffer with a
DISCONT
,SEGMENT
orEOS
is received, all accumulated audio is sent downstream in reverse order. Some audio codecs need the previous data buffer to decode the current one, in that case, the previous DISCONT buffer needs to be combined with the last non-DISCONT buffer to generate the last bit of output. -
A sink reverses (for audio) and retimestamps (audio, video) the buffers before playing them back. Retimestamping occurs relative to the stop position, making the timestamps increase again and suitable for synchronizing against the clock. Audio sinks also have to perform simple resampling before playing the samples.
-
for transcoding, audio and video resamplers can be used to reverse, resample and retimestamp the buffers. Any rate adjustments performed on the media must be added to the
applied_rate
and subtracted from the rate members in theSEGMENT
event.
In SKIP
mode, the same algorithm as for forward SKIP
mode can be used.
Notes
-
The clock/
running_time
keeps running forward. -
backwards playback potentially uses a lot of memory as frames and undecoded data gets buffered.
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