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262 lines
12 KiB
Markdown
262 lines
12 KiB
Markdown
# RTP
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These design docs detail some of the lower-level mechanism of certain parts
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of GStreamer's RTP stack. For a higher-level overview see the [RTP and RTSP
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support](rtp.md) section.
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# RTP auxiliary stream design
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## Auxiliary elements
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There are two kind of auxiliary elements, sender and receiver. Let's
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call them rtpauxsend and rtpauxreceive.
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rtpauxsend has always one sink pad and can have unlimited requested src
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pads. If only src pad then it works in SSRC-multiplexed mode, if several
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src pads then it works in session multiplexed mode.
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rtpauxreceive has always one ssrc pad and can have unlimited requested
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sink pads. If only one sink pad then it works in SSRC-multiplexed mode,
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if several sink pads then it works in session multiplexed mode.
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## Rtpbin and auxiliary elements
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### Basic mechanism
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rtpbin knows for which session ids the given auxiliary element belong
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to. It's done through "set-aux-send", for rtpauxsend kind, and through
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"set-aux-receive" for rtpauxreceive kind. You can call those signals as
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much as needed for each auxiliary element. So for aux elements that work
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in SSRC-multiplexed mode this signal action is called only one time.
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The user has to call those action signals before to request the
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differents rtpbin pads. rtpbin is in charge to link those auxiliary
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elements with the sessions, and on receiver side, rtpbin has also to
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handle the link with ssrcdemux.
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rtpbin never knows if the given rtpauxsend is actually a rtprtxsend
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element or another aux element. rtpbin never knows if the given
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rtpauxreceive is actually a rtprtxreceive element or another aux
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element. rtpbin has to be kept generic so that more aux elements can be
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added later without changing rtpbin.
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It's currently not possible to use rtpbin with auxiliary stream from
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gst-launch. We can discuss about having the ability for rtpbin to
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instanciate itself the special aux elements rtprtxsend and rtprtxreceive
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but they need to be configured ("payload-type" and "payload-types"
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properties) to make retransmission work. So having several rtprtxsend
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and rtprtxreceive in a rtpbin would require a lot of properties to
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manage them form rtpbin. And for each auxiliary elements.
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If you want to use rtprtxreceive and rtprtpsend from gst-launch you have
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to use rtpsession, ssrcdemux and rtpjitterbuffer elements yourself. See
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gtk-doc of rtprtxreceive for an example.
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### Requesting the rtpbin's pads on the pipeline receiver side
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If rtpauxreceive is set for session, i, j, k then it has to call
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rtpbin::"set-aux-receive" 3 times giving those ids and this aux element.
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It has to be done before requesting the `recv_rtp_sink_i`,
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`recv_rtp_sink_j`, `recv_rtp_sink_k`. For a concrete case
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rtprtxreceive, if the user wants it for session i, then it has to call
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rtpbin::"set-aux-receive" one time giving i and this aux element. Then
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the user can request `recv_rtp_sink_i` pad.
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Calling rtpbin::"set-aux-receive" does not create the session. It add
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the given session id and aux element to a hashtable(key:session id,
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value: aux element). Then when the user ask for
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`rtpbin.recv_rtp_sink_i`, rtpbin lookup if there is an aux element for
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this i session id. If yes it requests a sink pad to this aux element and
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links it with the `recv_rtp_src` pad of the new gstrtpsession. rtpbin
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also checks that this aux element is connected only one time to
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ssrcdemux. Because rtpauxreceive has only one source pad. Each call to
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request `rtpbin.recv_rtp_sink_k` will also creates
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`rtpbin.recv_rtp_src_k_ssrc_pt` as usual. So that the user have it
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when then it requests rtpbin. (from gst-launch) or using
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`on_rtpbinreceive_pad_added` callback from an application.
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### Requesting the rtpbin's pads on the pipeline sender side
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For the sender this is similar but a bit more complicated to implement.
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When the user asks for `rtpbin.send_rtp_sink_i`, rtpbin will lookup in
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its second map (key:session id, value: aux send element). If there is
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one aux element, then it will set the sink pad of this aux sender
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element to be the ghost pad `rtpbin.send_rtp_sink_i` that the user
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asked. rtpbin will also request a src pad of this aux element to connect
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it to `gstrtpsession_i`. It will automatically create
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`rtpbin.send_rtp_src_i` the usuall way. Then if the user asks
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`rtpbin.send_rtp_src_k`, then rtpbin will also lookup in that map and
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request another source pad of the aux element and connect it to the new
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`gstrtpsession_k`.
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# RTP collision design
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## GstRTPCollision
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Custon upstream event which contains the ssrc marked as collided.
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This event is generated on both pipeline sender and receiver side by the
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gstrtpsession element when it detects a conflict between ssrc. (same
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session id and same ssrc)
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It's an upstream event so that means this event is for now only useful
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on pipeline sender side. Because elements generating packets with the
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collided SSRC are placed upstream from the gstrtpsession.
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## rtppayloader
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When handling a `GstRTPCollision` event, the rtppayloader has to choose
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another ssrc.
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## BYE only the corresponding source, not the whole session.
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When a collision happens for the given ssrc, the associated source is
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marked bye. But we make sure that the whole session is not itself set
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bye. Because internally, gstrtpsession can manages several sources and
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all have their own distinct ssrc.
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# RTP retransmission design
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## GstRTPRetransmissionRequest
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Custom upstream event which mainly contains the ssrc and the seqnum of
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the packet which is asked to be retransmisted.
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On the pipeline receiver side this event is generated by the
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gstrtpjitterbuffer element. Then it is translated to a NACK to be sent
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over the network.
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On the pipeline sender side, this event is generated by the
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gstrtpsession element when it receives a NACK from the network.
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## rtprtxsend element
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### Basic mechanism
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rtprtxsend keeps a history of rtp packets that it has already sent. When
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it receives the event `GstRTPRetransmissionRequest` from the downstream
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gstrtpsession element, it loopkup the requested seqnum in its stored
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packets. If the packet is present in its history, it will create a RTX
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packet according to RFC 4588. Then this rtx packet is pushed to its src
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pad as other packets.
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rtprtxsend works in SSRC-multiplexed mode, so it has one always sink and
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src pad.
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### Building retransmission packet fron original packet
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A rtx packet is mostly the same as an orignal packet, except it has its
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own ssrc and its own seqnum. That's why rtprtxsend works in
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SSRC-multiplexed mode. It also means that the same session is used.
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Another difference between rtx packet and its original is that it
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inserts the original seqnum (OSN: 2 bytes) at the beginning of the
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payload. Also rtprtxsend builds rtx packet without padding, to let other
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elements do that. The last difference is the payload type. For now the
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user has to set it through the rtx-payload-type property. Later it will
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be automatically retreive this information from SDP. See fmtp field as
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specifies in the RPC4588 (a=fmtp:99 apt=98) fmtp is the payload type of
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the retransmission stream and apt the payload type of its associated
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master stream.
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### Retransmission ssrc and seqnum
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To choose `rtx_ssrc` it randomly selects a number between 0 and 2^32-1
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until it is different than `master_ssrc`. `rtx_seqnum` is randomly
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selected between 0 and 2^16-1
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### Deeper in the stored buffer history
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For the history it uses a GSequence with 2^15-1 as its maximum size.
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Which is resonable as the default value is 100. It contains the packets
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in reverse order they have been sent (head:newest, tail:oldest)
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GSequence allows to add and remove an element in constant time (like a
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queue). Also GSequence allows to do a binary search when rtprtxsend
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lookup in its history. It's important if it receives a lot of requests
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or if the history is large.
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### Pending rtx packets
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When looking up in its history, if seqnum is found then it pushes the
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buffer into a GQueue to its tail. Before to send the current master
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stream packet, rtprtxsend sends all the buffers which are in this
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GQueue. Taking care of converting them to rtx packets. This way, rtx
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packets are sent in the same order they have been requested.
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(`g_list_foreach` traverse the queue from head to tail) The `GQueue` is
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cleared between sending 2 master stream packets. So for this `GQueue` to
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contain more than one element, it means that rtprtxsend receives more
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than one rtx request between sending 2 master packets.
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### Collision
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When handling a `GstRTPCollision` event, if the ssrc is its rtx ssrc then
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rtprtxsend clear its history and its pending retransmission queue. Then
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it chooses a `rtx_ssrc` until it's different than master ssrc. If the
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`GstRTPCollision` event does not contain its rtx ssrc, for example its
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master ssrc or other, then it just forwards the event to upstream. So
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that it can be handled by the rtppayloader.
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## Rtprtxreceive element
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### Basic mechanism
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The same rtprtxreceive instance can receive several master streams and
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several retransmission streams. So it will try to dynamically associate
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a rtx ssrc with its master ssrc. So that it can reconstruct the original
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from the proper rtx packet.
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The algorithm is based on the fact that seqnums of different streams
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(considering all master and all rtx streams) evolve at a different rate.
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It means that the initial seqnum is random for each one and the offset
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could also be different. So that they are statistically all different at
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a given time. If bad luck then the association is delayed to the next
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rtx request.
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The algorithm also needs to know if a given packet is a rtx packet or
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not. To know this information there is the `rtx-payload-types` property.
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For now the user as to configure it but later it will be automatically
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retreive this information from SDP. It needs to know if the current
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packet is rtx or not in order to know if it can extract the OSN from the
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payload. Otherwise it would extract the OSN even on master streams which
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means nothing and so it could do bad things. In theory maybe it could
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work but we have this information in SDP so why not using it to avoid
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bad associations.
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Note that it also means that several master streams can have the same
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payload type. And also several rtx streams can have the same payload
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type. So the information from SDP which gives us which rtx payload type
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belong to a give master payload type is not enough to do the association
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between rtx ssrc and master ssrc.
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rtprtxreceive works in SSRC-multiplexed mode, so it has one always sink
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and src pad.
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### Deeper in the association algorithm
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When it receives a `GstRTPRetransmissionRequest` event it will remember
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the ssrc and the seqnum from this request.
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On incoming packets, if the packet has its ssrc already associated then
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it knows if the ssrc is an rtx ssrc or a master stream ssrc. If this is
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a rtx packet then it recontructs the original and pushs the result to
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src pad as if it was a master packet.
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If the ssrc is not yet associated rtprtxreceive checks the payload type.
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if the packet has its payload type marked as rtx then it will extract
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the OSN (original seqnum number) and lookup in its stored requests if a
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seqnum matchs. If found, then it associates the current ssrc to the
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master ssrc marked in the request. If not found it just drops the
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packet. Then it removes the request from the stored requests.
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If there are 2 requests with the same seqnum and different ssrc, then
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the couple seqnum,ssrc is removed from the stored requests. A stored
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request actually means that actually the couple seqnum,ssrc is stored.
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If it's happens the request is droped but it avoids to do bad
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associations. In this case the association is just delayed to the next
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request.
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### Building original packet from rtx packet
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Header, extensions, payload and padding are mostly the same. Except that
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the OSN is removed from the payload. Then ssrc, seqnum, and original
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payload type are correctly set. Original payload type is actually also
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stored when the rtx request is handled.
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