Network Working Group A. B. Roach
Internet-Draft Mozilla
Intended status: Informational J. Uberti
Expires: January 16, 2014 Google
M. Thomson
Microsoft
July 15, 2013
A Unified Plan for Using SDP with Large Numbers of Media Flows
draft-roach-mmusic-unified-plan-00
Abstract
A recurrent theme in emerging real-time communications use cases,
such as RTCWEB, has been the need to handle very large numbers of
media flows. Unfortunately, naive uses of SDP do not handle this
case particularly well. This document describes a modest set of
extensions to SDP which allow it to cleanly handle arbitrary numbers
of flows while still retaining a large degree of backward
compatibility with existing and non-RTCWEB endpoints.
Status of This Memo
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This Internet-Draft will expire on January 16, 2014.
Copyright Notice
Copyright (c) 2013 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
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publication of this document. Please review these documents
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carefully, as they describe your rights and restrictions with respect
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Design Goals . . . . . . . . . . . . . . . . . . . . . . 4
1.1.1. Support for a large number of arbitrary sources . . . 4
1.1.2. Support for fine-grained receiver control of sources 5
1.1.3. Glareless addition and removal of sources . . . . . . 5
1.1.4. Interworking with other devices . . . . . . . . . . . 5
1.1.5. Avoidance of excessive port allocation . . . . . . . 6
1.1.6. Simple binding of MediaStreamTrack to SDP . . . . . . 6
1.1.7. Support for RTX, FEC, simulcast, layered coding . . . 6
1.2. Terminology . . . . . . . . . . . . . . . . . . . . . . . 6
1.3. Syntax Conventions . . . . . . . . . . . . . . . . . . . 7
2. Solution Overview . . . . . . . . . . . . . . . . . . . . . . 7
3. Detailed Description . . . . . . . . . . . . . . . . . . . . 8
3.1. Bundle-Only M-Lines . . . . . . . . . . . . . . . . . . . 8
3.2. Correlation . . . . . . . . . . . . . . . . . . . . . . . 12
3.2.1. Correlating RTP Sources with m-lines . . . . . . . . 12
3.2.1.1. RTP Header Extension Correlation . . . . . . . . 13
3.2.1.2. Payload Type Correlation . . . . . . . . . . . . 14
3.2.2. Correlating Media Stream Tracks with m-lines . . . . 16
3.2.3. Correlating Media Stream Tracks with RTP Sources . . 16
3.3. Handling of Simulcast, Forward Error Correction, and
Retransmission Streams . . . . . . . . . . . . . . . . . 16
3.4. Glare Minimization . . . . . . . . . . . . . . . . . . . 18
3.4.1. Adding a Stream . . . . . . . . . . . . . . . . . . . 19
3.4.2. Changing a Stream . . . . . . . . . . . . . . . . . . 19
3.4.3. Removing a Stream . . . . . . . . . . . . . . . . . . 20
3.5. Negotiation of Stream Ordinality . . . . . . . . . . . . 20
3.6. Compatibility with Legacy uses . . . . . . . . . . . . . 22
4. Examples . . . . . . . . . . . . . . . . . . . . . . . . . . 23
4.1. Simple example with one audio and one video . . . . . . . 23
4.2. Multiple Videos . . . . . . . . . . . . . . . . . . . . . 26
4.3. Many Videos . . . . . . . . . . . . . . . . . . . . . . . 28
4.4. Multiple Videos with Simulcast . . . . . . . . . . . . . 30
4.5. Video with Simulcast and RTX . . . . . . . . . . . . . . 31
4.6. Video with Simulcast and FEC . . . . . . . . . . . . . . 32
4.7. Video with Layered Coding . . . . . . . . . . . . . . . . 33
5. Security Considerations . . . . . . . . . . . . . . . . . . . 35
6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 35
7. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 35
8. References . . . . . . . . . . . . . . . . . . . . . . . . . 35
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8.1. Normative References . . . . . . . . . . . . . . . . . . 35
8.2. Informative References . . . . . . . . . . . . . . . . . 36
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 37
1. Introduction
A recurrent theme in new RTC technologies has been the need to
cleanly handle very large numbers of media flows. For instance, a
videoconferencing application might have a main display plus
thumbnails for 10 or more other speakers all displayed at the same
time. If each video source is encoded in multiple resolutions (e.g.,
simulcast or layered coding) and also has FEC or RTX, this could
easily add up to 30 or more independent RTP flows.
This document focuses on the WebRTC use cases, and uses its
terminology to discuss key concepts. The approach described herein,
however, is not intended to be WebRTC specific, and should be
generalize to other SDP-using applications.
The standard way of encoding this information in SDP is to have each
RTP flow (i.e., SSRC) appear on its own m-line. For instance, the
SDP for two cameras with audio from a device with a public IP address
could look something like:
v=0
o=- 20518 0 IN IP4 203.0.113.1
s=
t=0 0
c=IN IP4 203.0.113.1
a=ice-ufrag:F7gI
a=ice-pwd:x9cml/YzichV2+XlhiMu8g
a=fingerprint:sha-1
42:89:c5:c6:55:9d:6e:c8:e8:83:55:2a:39:f9:b6:eb:e9:a3:a9:e7
m=audio 54400 RTP/SAVPF 0 96
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 52595
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
a=sendrecv
a=candidate:0 1 UDP 2113667327 203.0.113.1 54400 typ host
a=candidate:1 2 UDP 2113667326 203.0.113.1 54401 typ host
m=video 55400 RTP/SAVPF 96 97
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 56036
a=rtpmap:96 H264/90000
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a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:97 VP8/90000
a=sendrecv
a=candidate:0 1 UDP 2113667327 203.0.113.1 55400 typ host
a=candidate:1 2 UDP 2113667326 203.0.113.1 55401 typ host
m=video 56400 RTP/SAVPF 96 97
a=msid:ma tc
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 21909
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:97 VP8/90000
a=sendrecv
a=candidate:0 1 UDP 2113667327 203.0.113.1 56400 typ host
a=candidate:1 2 UDP 2113667326 203.0.113.1 56401 typ host
Unfortunately, as the number of independent media sources starts to
increase, the scaling properties of this approach become problematic.
In particular, SDP currently requires that each m-line have its own
transport parameters (port, ICE candidates, etc.), which can get
expensive. For instance, the [RFC5245] pacing algorithm requires
that new STUN transactions be started no more frequently than 20 ms;
with 30 RTP flows, which would add 600 ms of latency for candidate
gathering alone. Moreover, having 30 persistent flows might lead to
excessive consumption of NAT binding resources.
This document specifies a small number of modest extensions to SDP
which are intended to reduce the transport impact of using a large
number of flows. The general design philosophy is to maintain the
existing SDP negotiation model (inventing as few new mechanisms as
possible) while simply reducing the consumption of network resources.
1.1. Design Goals
The mechanism described in this document is meant to address the
following goals:
1.1.1. Support for a large number of arbitrary sources
In cases such as a video conference, there may be dozens or hundreds
of participants, each with their own audio and video sources. A
participant may even want to browse conferences before joining one,
meaning that there may be cases where there are many such conferences
displayed simultaneously.
In these conferences, participants may have varying capabilities and
therefore video resolutions. In addition, depending on conference
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policy, user preference, and the desired UI, participants may be
displayed in various layouts, including:
o A single large main speaker with thumbnails for other participants
o Multiple medium-sized main speakers, with or without thumbnails
o Large slides + medium speaker, without thumbnails
These layouts can change dynamically, depending on the conference
content and the preferences of the receiver. As such, there are not
well-defined 'roles', that could be used to group sources into
specific 'large' or 'thumbnail' categories. As such, the requirement
we attempt to satisfy is support for sending and receiving up to
hundreds of simultaneous, heterogeneous sources.
1.1.2. Support for fine-grained receiver control of sources
Since there may be large numbers of sources, which can be displayed
in different layouts, it is imperative that the receiver can easily
control which sources are received, and what resolution or quality is
desired for each (for both audio and video). The receiver should
also be able to prioritize the source it requests, so that if system
limits or bandwidth force a reduction in quality, the sources chosen
by the receiver as important will receive the best quality. These
details must be exposed to the application via the API.
1.1.3. Glareless addition and removal of sources
Sources may come and go frequently, as is the case in a conference
where various participants are presenting, or an interaction between
multiple distributed conference servers. Because of this, it is
desirable that sources can be added to SDP in a way that avoids
signaling glare.
1.1.4. Interworking with other devices
When interacting with devices that do not apply all of the techniques
described in this document, it must be possible to degrade gracefully
to a usable basic experience. At a minimum, this basic experience
should support setting up one audio stream and more than one video
stream with existing videoconferencing equipment designed to
establish a small number of simultaneous audio and video flows. For
the remainder of this document, we will call these devices "legacy
devices," although it should be understood that statements about
legacy devices apply equally to future devices that elect not to use
the techniques described in this document.
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1.1.5. Avoidance of excessive port allocation
When there are dozens or hundreds of streams, it is desirable to
avoid creating dozens or hundreds of transports, as empirical data
shows a clear inverse relationship between number of transports (NAT
bindings) and call success rate. While BUNDLE helps avoid creating
large numbers of transports, it is also desirable to avoid creating
large numbers of ports during call setup.
1.1.6. Simple binding of MediaStreamTrack to SDP
In WebRTC, each media source is identified by a MediaStreamTrack
object. In order to ensure that the MSTs created by the sender show
up at the receiver, each MST's id attribute needs to be reflected in
SDP.
1.1.7. Support for RTX, FEC, simulcast, layered coding
For robust applications, techniques like RTX and FEC are used to
protect media, and simulcast/layered coding can be used to provide
support to heterogeneous receivers. It needs to be possible to
support these techniques, allow the recipient to optionally use or
not use them on a source-by-source basis; and for simulcast/layered
scenarios, to control which simulcast streams or layers are received.
1.2. Terminology
The key words "MUST", "MUST NOT", "REQUIRED", "SHOULD", "SHOULD NOT",
"RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be
interpreted as described in [RFC2119].
This draft uses the API and terminology described in [webrtc-api].
5-tuple: A collection of the following values: source IP address,
source transport port, destination IP address, destination transport
port and transport protocol.
Transport-Flow: An transport 5 Tuple representing the UDP source and
destination IP address and port over which RTP is flowing.
m-line: An SDP [RFC4566] media description identifier that starts
with an "m=" field and conveys the following values: media type,
transport port, transport protocol and media format descriptions.
Offer: An [RFC3264] SDP message generated by the participant who
wishes to initiate a multimedia communication session. An Offer
describes the participant's capabilities for engaging in a multimedia
session.
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Answer: An [RFC3264] SDP message generated by the participant in
response to an Offer. An Answer describes the participant's
capabilities in continuing with the multimedia session with in the
constraints of the Offer.
This draft avoids using terms that implementors do not have a clear
idea of exactly what they are - for example RTP Session.
1.3. Syntax Conventions
The SDP examples given in this document deviate from actual on-the-
wire SDP notation in several ways. This is done to facilitate
readability and to conform to the restrictions imposed by the RFC
formatting rules. These deviations are as follows:
o Any line that is indented (compared to the initial line in the SDP
block) is a continuation of the preceding line. The line break
and indent are to be interpreted as a single space character.
o Empty lines in any SDP example are inserted to make functional
divisions in the SDP clearer, and are not actually part of the SDP
syntax.
o Excepting the above two conventions, line endings are to be
interpreted as <CR><LF> pairs (that is, an ASCII 13 followed by an
ASCII 10).
o Any text starting with the string "//" to the end of the line is
inserted for the benefit of the reader, and is not actually part
of the SDP syntax.
2. Solution Overview
At a high level, the solution described in this document can be
summarized as follows:
1. Each media stream track is represented by its own unique m-line.
This is a strict one-to-one mapping; a single media stream track
cannot be spread across several m-lines, nor may a single m-line
represent multiple media stream tracks. Note that this requires
a modification to the way simulcast is currently defined by the
individual draft [I-D.westerlund-avtcore-rtp-simulcast]. This
does not preclude "application level" simulcasting; i.e., the
creation of multiple media stream tracks from a single source.
2. Each m-line is marked with an a=ssrc attribute to correlate it
with its RTP packets. Absent any other signaled extension,
multiple SSRCs in a single m-line are interpreted as alternate
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sources for the same media stream track: although senders can
switch between the SSRCs as frequently as desired, only one
should be sent at any given time.
3. Each m-line contains an MSID value to correlate it with a Media
Stream ID and the Media Stream Track ID.
4. To minimize port allocation during a call, we rely on the BUNDLE
[I-D.ietf-mmusic-sdp-bundle-negotiation] mechanism.
5. To reduce port allocation during call set-up, applications can
mark less-critical media stream tracks in such a way that they
will not require any port allocation, with the resulting property
that such streams only work in the presence of the BUNDLE
mechanism.
6. To address glare, we define a procedure via which partial offer/
answer exchanges may take place. These exchanges operate on a
single m-line at a time, rather than an entire SDP body. These
operations are defined in a way that can completely avoid glare
for stream additions and removals, and which reduces the chance
of glare for changes to active streams. This approach requires
all m-lines to contain an a=mid attribute.
7. All sources in a single bundle are required to contain identical
attributes except for those that apply directly to a media stream
track (such as label, msid, and resolution). See those
attributes marked "IDENTICAL" in
[I-D.nandakumar-mmusic-sdp-mux-attributes] for details.
8. RTP and RTCP streams are demultiplexed strictly based on their
SSRC. However, to handle legacy cases and signaling/media races,
correlation of streams to m-sections can use other mechanisms, as
described in Section 3.2.
3. Detailed Description
3.1. Bundle-Only M-Lines
Even with the use of BUNDLE, it is expensive to allocate ICE
candidates for a large number of m-lines. An offer can contain
"bundle-only" m-lines which will be negotiated only by endpoints
which implement this specification and ignored by other endpoints.
OPEN ISSUE: While it's probably pretty clear that this behavior
will be controlled, in WebRTC, via a constraint, the "default"
behavior -- that is, whether a line is "bundle-only" when there is
no constraint present -- needs to be settled. This is a balancing
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act between maximizing interoperation with legacy equipment by
default or minimizing port use during call setup by default.
In order to offer such an m-line, the offerer does two things:
o Sets the port in the m-line to 0. This indicates to old endpoints
that the m-line is not to be negotiated.
o Adds an a=bundle-only line. This indicates to new endpoints that
the m-line is to be negotiated if (and only if) bundling is used.
An example offer that uses this feature looks like this:
v=0
o=- 20518 0 IN IP4 203.0.113.1
s=
t=0 0
c=IN IP4 203.0.113.1
a=group:BUNDLE S1 S2 S3
a=ice-ufrag:F7gI
a=ice-pwd:x9cml/YzichV2+XlhiMu8g
a=fingerprint:sha-1
42:89:c5:c6:55:9d:6e:c8:e8:83:55:2a:39:f9:b6:eb:e9:a3:a9:e7
m=audio 54400 RTP/SAVPF 0 96
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 20970
a=mid:1
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
a=sendrecv
a=rtcp-mux
a=ssrc:53280
a=candidate:0 1 UDP 2113667327 203.0.113.1 54400 typ host
a=candidate:1 2 UDP 2113667326 203.0.113.1 54401 typ host
m=video 0 RTP/SAVPF 96 97
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 1714
a=mid:2
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:97 VP8/90000
a=sendrecv
a=rtcp-mux
a=ssrc:49152
a=bundle-only
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m=video 0 RTP/SAVPF 96 97
a=msid:ma tc
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 57067
a=mid:3
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:97 VP8/90000
a=sendrecv
a=rtcp-mux
a=ssrc:32768
a=bundle-only
An old endpoint simply rejects the bundle-only m-lines by responding
with a 0 port. (This isn't a normative statement, just a description
of the way the older endpoints are expected to act.)
v=0
o=- 20518 0 IN IP4 203.0.113.1
s=
t=0 0
c=IN IP4 203.0.113.2
a=ice-ufrag:F7gI
a=ice-pwd:x9cml/YzichV2+XlhiMu8g
a=fingerprint:sha-1
42:89:c5:c6:55:9d:6e:c8:e8:83:55:2a:39:f9:b6:eb:e9:a3:a9:e7
m=audio 55400 RTP/SAVPF 0 96
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
a=sendrecv
a=candidate:0 1 UDP 2113667327 203.0.113.2 55400 typ host
a=candidate:1 2 UDP 2113667326 203.0.113.2 55401 typ host
m=video 0 RTP/SAVPF 96 97
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:97 VP8/90000
a=sendrecv
m=video 0 RTP/SAVPF 96 97
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:97 VP8/90000
a=sendrecv
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A new endpoint accepts the m-lines (both bundle-only and regular) by
offering m-lines with a valid port, though this port may be
duplicated as specified in Section 6 of
[I-D.ietf-mmusic-sdp-bundle-negotiation]. For instance:
v=0
o=- 20518 0 IN IP4 203.0.113.2
s=
t=0 0
c=IN IP4 203.0.113.2
a=group:BUNDLE B1 B2 B3
a=ice-ufrag:F7gI
a=ice-pwd:x9cml/YzichV2+XlhiMu8g
a=fingerprint:sha-1
42:89:c5:c6:55:9d:6e:c8:e8:83:55:2a:39:f9:b6:eb:e9:a3:a9:e7
m=audio 55400 RTP/SAVPF 0 96
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 24860
a=mid:1
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
a=sendrecv
a=rtcp-mux
a=ssrc:35987
a=candidate:0 1 UDP 2113667327 203.0.113.2 55400 typ host
m=video 55400 RTP/SAVPF 96 97
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 49811
a=mid:B2
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:97 VP8/90000
a=sendrecv
a=rtcp-mux
a=ssrc:9587
a=bundle-only
m=video 55400 RTP/SAVPF 96 97
a=msid:ma tc
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 9307
a=mid:3
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:97 VP8/90000
a=sendrecv
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a=rtcp-mux
a=ssrc:21389
a=bundle-only
Endpoints MUST NOT accept bundle-only m-lines if they are not part of
an accepted bundle group.
3.2. Correlation
The system under consideration has three constructs the need to be
mutually correlated for proper functioning: m-lines, media stream
tracks, and RTP sources. These correlations are described in the
following sections.
3.2.1. Correlating RTP Sources with m-lines
Sending several media streams over a single transport 5-tuple can
pose challenges in the form of stream identification and correlation.
This proposal maintains the use of SSRC as the single demultiplexing
point for multiple streams sent between a transport 5-tuple.
Nominally, this correlation is performed by including a=ssrc
attributes in the SDP. Under ideal circumstances, the use of a=ssrc
in the SDP exchanged between endpoints is sufficient to correlate a
demultiplexed stream to its m-line. However, at least three
unrelated situations can arise that make correlation using an
alternate mechanism advantageous.
During call establishment, circumstances may arise under which an
endpoint can send an offer for a new stream, and begin receiving that
media stream prior to receiving the SDP that correlates its SSRC to
the m-line. For such cases, the endpoint will not know how to handle
the media, and will most probably be forced to discard it. This can
lead to media stream "clipping," which has a strongly negative impact
on user experience. For audio streams, an the "hello" of the
answering party can be lost; for video streams, the initial I-frame
can be lost, leading to corrupted or missing video until another
I-frame is sent.
In the rare circumstance that a SSRC change for an existing media
source is required, then any party that has changed its SSRC needs to
inform the remote participants of the updated mapping, e.g. via a
new SDP offer. Since any media sent with the new SSRC cannot be
rendered until the new offer/answer exchange takes place, the
clipping concern mentioned above exists here as well.
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A different problem can arise when interoperating with legacy
equipment. A number of circumstances can lead to the inability of a
legacy endpoint to include SSRC information in its SDP. For example,
in a system that decomposes signaling and media into different
network devices, the protocol used to communicate between the boxes
frequently will not include SSRC information, making it impossible to
include in the SDP. If these devices choose to implement bundling,
correlation of media streams to m-lines requires an alternate
correlator.
These cases (and possibly other similar situations) can be
ameliorated by using information in the media stream itself as a
correlator to the SDP offer. If a packet arrives with an SSRC that
is not yet associated with an m-line, we would ideally have some
means of correlating it prior to the arrival of the answer.
The authors reiterate and emphasize that this technique is used
solely for the purposes of correlation of an RTP stream to an SDP
m-line after that stream has already been demultiplexed.
Demultiplexing of multiple streams on a single transport address
continues to be based on SSRC values.
3.2.1.1. RTP Header Extension Correlation
The preferred mechanism for such correlation is a new RTP header
extension [RFC5285] that can be used near the beginning of an RTP
stream to correlate RTP packets for which SSRC mapping information is
not available. We propose that WebRTC implementations MUST implement
this mechanism. We expect and that all other users of the BUNDLE
extension SHOULD make use of it.
Although additional specification for this mechanism would be
required for interoperability, the thumbnail sketch of such
correlation is described below.
An implementation making use of this mechanism for local correlation
includes an a=extmap attribute in the m-lines for which it wishes to
use the mechanism. This attribute includes a mapping from the RTP
header ID to the URL, as well as a 16-bit identifier (expressed as an
integer) used for correlation; one such m-line would look like this:
m=audio 55400 RTP/SAVPF 0 96
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 7582 // NEW
a=mid:1
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
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a=sendrecv
a=rtcp-mux
a=ssrc:35987
a=candidate:0 1 UDP 2113667327 203.0.113.2 55400 typ host
The remote endpoint, if it supports this extension, MUST include an
RTP header extension in several (on the order of 3 to 10) of the
initial RTP packets in the stream. The value of this header
extension will contain the correlator from the extmap line (in the
above example, 7582).
3.2.1.2. Payload Type Correlation
To support implementations that cannot implement the RTP header
extension described in Section 3.2.1.1 but which wish to use the
BUNDLE mechanism, we allow an alternate (but less-preferred) means of
correlation using payload type. This approach takes advantage of the
fact that the offer contains payload types chosen by its creator,
which will be present in any RTP received from the remote party. If
these payload types are unique, then they can be used to reliably
correlate incoming RTP streams to their m= lines.
Because of its inherent limitations, it is advisable to use other
correlation techniques than PT multiplexing if at all possible. In
order to accomplish this, we propose, for WebRTC, that use of this
technique be controlled by an additional constraint passed to
createOffer by the Web application.
If this constraint is set, the browser MUST behave as described in
this section. If the constraint is not set, the browser MUST use
identical PTs for the same codec values within each m-line bundle.
When such a constraint is present, implementations attempt to
entirely exhaust the dynamic payload type numbering space before re-
using a payload type within the scope of a local transport address.
If such a constraint is present and the payload type space would
ordinarily be exhausted within the scope of a local transport
address, the implementation MAY (at its discretion) take any of the
following actions:
1. Bind to multiple local transport addresses (using different
BUNDLE groups) for the purpose of keeping the {payload type,
transport address} combination unique.
2. Signal a failure to the application.
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OPEN ISSUE: The above text specifically calls out "dynamic payload
type numbering space," which consists of payload types 96 through
127. This is the most conservative range of payload types
possible, with the greatest chance of exhaustion in normal use.
In practice, it may make more sense to use a different range. The
canonical description of payload type allocation strategies for
RTP/AVP and its related profiles is given in section 3 of
[RFC3551]. Roughly summarized: all values from 0 to 127 can be
dynamically bound to codecs; codes from 96 to 127 should be
preferred, followed by previously unassigned values, followed by
statically assigned values. This is, however, modified by
[RFC5761], which effectively eliminates payload types 64 through
95. Given these constraints, reasonable proposals (in order of
most conservative to most aggressive) would include:
1. The dynamic range (96-127), for 32 usable payload types. This
is meant to accommodate the most naive implementation
possible, which is only capable of dynamically binding payload
types in the dynamic range. Although not supported by current
specifications, such limitations are suspected to exist in
some modern RTP libraries.
2. The dynamic range (96-127), followed by the contiguous
unassigned range (35-63), for 61 usable payload types. This
approach is intended to accommodate those implementations that
do not support dynamic binding for payload types for which an
"audio/video" type is registered in the IANA registry.
3. The dynamic range (96-127) followed by all unassigned payload
types (20-24, 27, 29, 30, and 35-63), for 69 usable payload
types. This approach is intended to accommodate those
implementations that are incapable of re-binding statically
assigned payload types, while making use of all other
available values.
4. The dynamic range (96-127) followed by all unassigned payload
types (20-24, 27, 29, 30, and 35-63), followed by the
statically assigned payload types (0-19, 25, 26, 28, and
31-34) for 96 usable payload types. This approach is most
consistent with current IETF specifications, but is expected
to cause interoperability issues with existing implementations
(including libraries currently in use in early WebRTC
implementations).
Note that the presence or absence of the aforementioned flag does not
affect how incoming streams are correlated: if the RTP header
extension for correlation is present, it is used in preference to the
payload type. Conversely, if the flag is absent, and the RTP
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contains no such header, then the payload type may be used for
correlation inasmuch as a media line can be unambiguously identified.
Of course, if the SSRC information has been made available in SDP
prior to a need for stream correlation, then it can also be used for
this purpose.
3.2.2. Correlating Media Stream Tracks with m-lines
Media Stream Tracks IDs are correlated with M-Lines directly by
including an MSID in each m-line. The MSID also provides the Media
Stream ID. (Note the format of the MSID used here is slightly
different than what was proposed in the current MSID draft as that
draft assumed multiple tracks in a single m-line and this proposal
moves to a solution where there is a one to one relation between the
Track and MSID. This work assumes the MSID draft will be updated to
match the syntax used user which simply provides the value of the
MediaStream ID and MediaStreamTrack ID on an "a=msid" line. )
3.2.3. Correlating Media Stream Tracks with RTP Sources
Media Stream Tracks are correlated with RTP sources transitively
through the RTP-Source <=> M-Line <=> Media-Stream-Track
relationship. Since the Media-Stream-Track <=> M-Line binding is
established in the SDP offer, and the M-Line <=> RTP-Source binding
can be handled as described in Section 3.2.1, none of the previously
identified issues arise.
3.3. Handling of Simulcast, Forward Error Correction, and
Retransmission Streams
Simulcast refers to taking a single capture (e.g., a camera), and
encoding it multiple times at different resolutions and / or frame
rates. For example, a device with a single HD camera may send one
version of the video at full HD resolution, and a second version
encoded at a low resolution. This would allow a video conferencing
bridge to be able to send the high resolution copy to some
destination and low resolution copy to other destinations without
having to recode the video at the conference bridge.
Forward Error Correction (FEC) and Retransmission (RTX) streams are
techniques that can provide stream robustness in the face of packet
loss. These approaches frequently make use of different payload
types and different SSRC values than the stream to which they apply.
In cases where a media source needs to correspond to more than one
RTP flow, e.g. RTX, FEC, or simulcast, the a=ssrc-group [RFC5576]
concept is used to create a grouping of SSRCs for a single media
stream track. Each SSRC is declared using a=ssrc attributes, the
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same MSID is shared between the SSRCs, and the a=ssrc-group attribute
defines the behavior of the grouped SSRCs.
These groupings are used to perform demux of the incoming RTP streams
and associate them (by SSRC) with their primary flows (modulo the
behavior described in Section 3.2.1, if applicable). This
multiplexing of RTX and FEC in a single RTP session is already well-
defined; RTX SSRC-multiplexing behavior is defined in [RFC4588], and
FEC SSRC-multiplexing behavior is defined in [RFC5956].
Note that both RTC and FEC also include SDP expressions that use
different m= lines for the correction streams (cf. [RFC4588],
section 8.7 and [RFC5956], section 4.2). These formats intend for
correlation of streams to be based on transport addresses, which is
inapplicable for bundled media streams. Our specific proposal is:
(1) bundling implementations will never generate such a format; and
(2) bundling implementations MAY choose to accept SDP in such a
format or MAY simply reject the repair streams and proceed as if the
indicated repair format is not supported.
For multi-resolution simulcast, we can create a similar ssrc-group,
and adapt the imageattr attribute defined in [RFC6236] for the a=ssrc
line attribute to indicate the send resolution for a given simulcast
stream. (This will be added to
[I-D.westerlund-avtcore-rtp-simulcast], as outlined in Section 2,
bullet 1). In the example below, the SDP advertises a simulcast of a
camera source at two different resolutions, as well as a screen-share
source that supports RTX; a=ssrc-group is used to correlate the
different SSRCs as part of a single media source.
Note that a characteristic of this approach is that it does not allow
for independently setting attributes for simulcast, FEC, and RTX
streams aside from those in fmtp. In particular, attributes such as
ptime and framerate are shared between the streams that are grouped
together for a simulcast group.
m=video 62537 RTP/SAVPF 96 // main video
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 15955
a=mid:1
a=rtpmap:96 VP8/90000
a=sendrecv
a=rtcp-mux
a=ssrc:29154 imageattr:96 [x=1280,y=720]
a=ssrc:47182 imageattr:96 [x=640,y=360]
a=ssrc-group:SIMULCAST 29154 47182
m=video 0 RTP/SAVPF 96 97 // slide video
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a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 26267
a=mid:2
a=rtpmap:96 VP8/90000
a=rtpmap:97 rtx/90000
a=sendrecv
a=rtcp-mux
a=fmtp:97 apt=96;rtx-time=3000
a=ssrc:45982
a=ssrc:9827
a=ssrc-group:FID 45982 9827 // FID provides SSRC correlation
a=bundle-only
Providing explicit resolutions on a per-SSRC basis for SIMULCAST
groupings allows an intermediary (such as a Media Translator
[RFC5117]) to be able to select an appropriate SIMULCAST layer
without inspecting the media stream, which could otherwise require
decrypting and possibly partially decoding media packets.
3.4. Glare Minimization
To allow for guaranteed glareless addition and removal of streams,
and to provide for a reduced chance of glare in stream attribute
changes, we propose a technique that allows for m-lines to be changed
independently of each other.
The proposal for doing so is performed using "partial offers" and
"partial answers." Using this technique has two key prerequisites:
(1) all offer/answer exchanges in the session have contained "a=mid"
attributes [RFC5888] for each m-line, and (2) both sides are known to
support the partial offer/answer technique (either because they are
part of a single domain of control, or because use of this technique
has been explicitly signaled).
The use of a partial SDP body will be explicitly signaled, e.g.,
using a different MIME type for SIP, or using a different "type" for
the WebRTC API.
The authors recognize that further formal definition would be
required to describe this technique. These are left as future study
for the appropriate venues, such as the W3C WebRTC WG and the SIPCORE
WG. As a thumbnail sketch: For WebRTC, we envision that we would add
a new constraint to createOffer, requesting that a partial offer be
generated (if possible). The resulting RTCSessionDescription would
contain only the m-lines that have changed since the most recent
offer/answer exchange, and would have a type of "partialOffer." When
createAnswer is called after receipt of a partialOffer, it would
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create a partialAnswer, containing only the m-lines referenced in the
partial offer, that can be provided to the remote party.
3.4.1. Adding a Stream
To add a stream glarelessly, a party creates a "partial offer"
consisting of an m-line and all of its attributes. This m-line
contains an mid that has not yet been used in the session. To reduce
the chance of collision to effectively zero, this mid MUST contain at
least 32 characters chosen randomly from full set of 79 characters
allowed in a token. It then sends this partial offer to the remote
party and awaits a partial answer.
Upon receipt of a partial offer, an implementation examines the mid
in it. If the mid does not match any existing mid in the session,
then it represents a new media stream. Assuming the recipient does
not have an outstanding, unanswered partial offer that also adds a
stream, this new m-line is simply appended to the end of the existing
session description, the SDP version is incremented by one, and a
partial answer is created. This partial answer consists of an m-line
and its attributes, and has an mid matching the one from the partial
offer.
If the recipient of a partial offer that contains a new mid has also
sent a partial offer adding a new stream to the session, then
ambiguity can arise regarding the canonical ordering of m-lines
within the session. In this situation, both partial offer/answer
exchanges are allowed to complete independently (as no fundamental
data glare has occurred). However, the order in which they are
appended to the session description is synchronized by performing a
lexical comparison between each m-lines mid attribute: the m-line
with the lexically smaller mid attribute is appended first, while the
other m-line is appended after it.
3.4.2. Changing a Stream
Partial offers may also be generated for modification of an existing
stream. In this case, the mid in the partial offer will match an
existing mid in the session description.
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Upon receipt of a partial offer, an implementation examines the mid
in it. If the mid matches any existing mid in the session, then it
represents a modification to that m-line. Assuming the recipient
does not have an outstanding, unanswered partial offer that also
modifies that exact same stream, this m-line is treated as an
independent renegotiation of that stream (only). The SDP version is
incremented by one, and a partial answer is created. This partial
answer consists of an m-line and its attributes, and has an mid
matching the one from the partial offer.
If the recipient of a partial offer that contains an existing mid has
also sent a partial offer to change that exact same stream, and
neither the received nor the sent partial offer contains an
"a=inactive" attribute, then a legitimate glare condition has arisen.
Normal glare recovery procedures -- e.g., using a tie-breaker token
or a back-off timer -- must be engaged to resolve the conflict.
3.4.3. Removing a Stream
To remove a stream in a way that eliminates the chance of glare, an
implementation generates a new partial offer, with an mid matching
the m-line it wants to remove. This partial offer contains an
a=inactive attribute, indicating that the stream is being
deactivated.
If the recipient of a partial offer that contains an existing mid has
also sent a partial offer to change that exact same stream, and
either one of the received or the sent partial offer contains an
"a=inactive" attribute, then a the stream is deactivated. At this
point, both partial offers are discarded, the corresponding m-line in
the session is modified by changing any a=sendonly, a=recvonly, or
a=sendrecv attribute to a=inactive (or, if no such attributes are
present, an a=inactive attribute is added), and a partial answer is
generated representing this single change.
3.5. Negotiation of Stream Ordinality
Within advanced applications, circumstances can easily arise in which
the party creating the offer does not know ahead of time the number
of streams the remote party will desire. For example, in a meet-me
videoconference application that sends a separate stream for each
participant, a client creating an offer to send to the conference
focus does not necessarily know how many video streams to indicate in
its SDP. Although this can be potentially be solved in an
application-specific way (e.g., by always offering the maximum number
of streams known to be supported by the application), this is not
always desirable or even possible.
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To address this situation, a three-way handshake can be employed.
Calling Party Called Party
| |
Calling party |--- Offer (1 video, 1 audio) -->|
creates offer | |
with audio and | |
video. Since | |
it does not | |
know how many | |
streams, it | |
"guesses" one | |
of each. | |
| |
|<-- Answer (1 video, 1 audio) --| Called party
[Call starts now] |<-- Offer (8 video, 1 audio) ---| desires eight
| | video streams.
| | So it creates
| | an answer for
| | the "one of
| | each" offer
| | and an offer
| | for the total
| | number of
| | streams it
| | wants.
| |
Calling party |-- Answer (8 video, 1 audio) -->|
answers for | |
all eight | |
video streams. | |
| |
The first leg of this handshake consists of an offer sent by the
calling party. This offer contains at least one m-line for each type
of media the offerer wishes to use in the session. The authors draw
special attention to the clause "at least" in the preceding sentence:
offerers can use external knowledge, hinting, or simple guesses to
offer additional m-lines.
Upon receipt of such an offer, the called party examines the number
of streams of each media type being requested. If the number of
streams is equal to or greater than the number of total streams that
the called party desires at this time, it simply forms an answer to
complete the offer/answer exchange [RFC3264], and the call is set up.
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On the other hand, if the called party determines that more streams
are necessary than are indicated in the initial offer, it responds by
first creating an answer with the same number of streams as were
present in the initial offer. It additionally creates a new answer
that contains the number of streams it desires. This answer/offer
pair is sent to the calling party, in a single message if supported
by the signaling protocol (as will frequently be the case for
WebRTC), or in two consecutive messages in a way that guarantees in-
order delivery.
When the calling party receives this answer, it establishes the
session, and all of the streams that were negotiated in this first
offer/answer exchange. So, within a single signaling round trip, the
initial set of streams (consisting of those the calling party
included in its initial offer) are established.
When the calling party receives the subsequent offer, it comprises
the beginning of a completely new RFC 3264 offer/answer exchange
[RFC3264]. The calling party creates an answer that fully describes
all of the streams in the session, and sends it to the called party.
Consequently, within 1.5 round trips, the entire call is set up and
all associated streams can be sent and received.
Of particular note is the fact that this model does not deviate from
normal RFC3264 offer/answer handling, even when three-way handshaking
is necessary.
3.6. Compatibility with Legacy uses
Due to the fact that this approach re-uses existing SDP constructs
for indicating parameters in a media section, it remains compatible
with legacy clients. Of particular note is the handling of "bundle-
only" media sections, described in Section 3.1. Offers generated by
an RTCWEB client and sent to a legacy client will simply negotiate
those media the RTCWEB client did not use the "bundle-only" extension
with. This allows RTCWEB clients to select which media streams are
important for interoperability with legacy clients (by not making
them bundle-only), and which ones are not. Offers generated by
legacy clients will simply omit any bundle-related attributes, and
the RTCWEB client will be able to process the SDP otherwise
identically to the SDP received from RTCWEB clients: each m-line
represents a different media stream, and contains a description of
that stream in a syntax identical to the syntax used between RTCWEB
clients.
With the bundle-only approach, only those streams that are "important
for interoperability" will require allocation of ports and ICE
exchanges. By doing so, working with non-multiplexing clients is
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enabled without requiring excess resource allocation for those
streams that are not critical for proper user experience.
4. Examples
In all of these examples, there are many lines that are wrapped due
to column width limitation. It should be understood these lines are
not wrapped in the real SDP.
The convention used for IP addresses in this drafts is that private
IP behind a NAT come from 192.0.2.0/24, the public side of a NAT
comes from 198.51.100.0/24 and the TURN servers have addresses from
203.0.113.0/24. Typically the offer has an IP ending in .1 and the
answer has an IP ending in .2.
The examples do not include all the parts of SDP that are used in
RTCWeb (See [I-D.ietf-rtcweb-rtp-usage]) as that makes the example
unwieldy to read but instead focuses on showing the parts that are
key for the multiplexing.
4.1. Simple example with one audio and one video
The following SDP shows an offer that offers one audio stream and one
video steam with both a STUN and TURN address. It also shows unique
payload across the audio and video m=lines for the Answerer that does
not support BUNDLE semantics.
v=0
o=- 20518 0 IN IP4 198.51.100.1
s=
t=0 0
c=IN IP4 203.0.113.1
a=ice-ufrag:074c6550
a=ice-pwd:a28a397a4c3f31747d1ee3474af08a068
a=fingerprint:sha-1
99:41:49:83:4a:97:0e:1f:ef:6d:f7:c9:c7:70:9d:1f:66:79:a8:07
a=group:BUNDLE m1 m2
m=audio 56600 RTP/SAVPF 0 109
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 33424
a=mid:m1
a=ssrc:53280
a=rtpmap:0 PCMU/8000
a=rtpmap:109 opus/48000
a=ptime:20
a=sendrecv
a=rtcp-mux
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a=candidate:0 1 UDP 2113667327 192.0.2.1 54400 typ host
a=candidate:1 2 UDP 2113667326 192.0.2.1 54401 typ host
a=candidate:0 1 UDP 694302207 198.51.100.1 55500 typ srflx raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 169430220 198.51.100.1 55501 typ srflx raddr
192.0.2.1 rport 54401
a=candidate:0 1 UDP 73545215 203.0.113.1 56600 typ relay raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 51989708 203.0.113.1 56601 typ relay raddr
192.0.2.1 rport 54401
m=video 56602 RTP/SAVPF 99 120
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 35969
a=mid:m2
a=ssrc:49843
a=rtpmap:99 H264/90000
a=fmtp:99 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:120 VP8/90000
a=sendrecv
a=rtcp-mux
a=candidate:3 1 UDP 2113667327 192.0.2.1 54402 typ host
a=candidate:4 2 UDP 2113667326 192.0.2.1 54403 typ host
a=candidate:3 1 UDP 694302207 198.51.100.1 55502 typ srflx raddr
192.0.2.1 rport 54402
a=candidate:4 2 UDP 169430220 198.51.100.1 55503 typ srflx raddr
192.0.2.1 rport 54403
a=candidate:3 1 UDP 73545215 203.0.113.1 56602 typ relay raddr
192.0.2.1 rport 54402
a=candidate:4 2 UDP 51989708 203.0.113.1 56603 typ relay raddr
192.0.2.1 rport 54403
The following shows an answer to the above offer from a device that
does not support bundle or rtcp-mux.
v=0
o=- 16833 0 IN IP4 198.51.100.2
s=
t=0 0
c=IN IP4 203.0.113.2
a=ice-ufrag:c300d85b
a=ice-pwd:de4e99bd291c325921d5d47efbabd9a2
a=fingerprint:sha-1
91:41:49:83:4a:97:0e:1f:ef:6d:f7:c9:c7:70:9d:1f:66:79:a8:03
m=audio 60600 RTP/SAVPF 109
a=msid:ma ta
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a=rtpmap:109 opus/48000
a=ptime:20
a=sendrecv
a=candidate:0 1 UDP 2113667327 192.0.2.2 60400 typ host
a=candidate:1 2 UDP 2113667326 192.0.2.2 60401 typ host
a=candidate:0 1 UDP 1694302207 198.51.100.2 60500 typ srflx raddr
192.0.2.2 rport 60400
a=candidate:1 2 UDP 1694302206 198.51.100.2 60501 typ srflx raddr
192.0.2.2 rport 60401
a=candidate:0 1 UDP 73545215 203.0.113.2 60600 typ relay raddr
192.0.2.1 rport 60400
a=candidate:1 2 UDP 51989708 203.0.113.2 60601 typ relay raddr
192.0.2.1 rport 60401
m=video 60602 RTP/SAVPF 99
a=msid:ma tb
a=rtpmap:99 H264/90000
a=fmtp:99 profile-level-id=4d0028;packetization-mode=1
a=sendrecv
a=candidate:2 1 UDP 2113667327 192.0.2.2 60402 typ host
a=candidate:3 2 UDP 2113667326 192.0.2.2 60403 typ host
a=candidate:2 1 UDP 694302207 198.51.100.2 60502 typ srflx raddr
192.0.2.2 rport 60402
a=candidate:3 2 UDP 169430220 198.51.100.2 60503 typ srflx raddr
192.0.2.2 rport 60403
a=candidate:2 1 UDP 73545215 203.0.113.2 60602 typ relay raddr
192.0.2.2 rport 60402
a=candidate:3 2 UDP 51989708 203.0.113.2 60603 typ relay raddr
192.0.2.2 rport 60403
The following shows answer to the above offer from a device that does
support bundle.
v=0
o=- 16833 0 IN IP4 198.51.100.2
s=
t=0 0
c=IN IP4 203.0.113.2
a=ice-ufrag:c300d85b
a=ice-pwd:de4e99bd291c325921d5d47efbabd9a2
a=fingerprint:sha-1
91:41:49:83:4a:97:0e:1f:ef:6d:f7:c9:c7:70:9d:1f:66:79:a8:03
a=group:BUNDLE m1 m2
m=audio 60600 RTP/SAVPF 109
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 39829
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a=mid:m1
a=ssrc:35856
a=rtpmap:109 opus/48000
a=ptime:20
a=sendrecv
a=rtcp-mux
a=candidate:0 1 UDP 2113667327 192.0.2.2 60400 typ host
a=candidate:0 1 UDP 1694302207 198.51.100.2 60500 typ srflx raddr
192.0.2.2 rport 60400
a=candidate:0 1 UDP 73545215 203.0.113.2 60600 typ relay raddr
192.0.2.1 rport 60400
m=video 60600 RTP/SAVPF 99
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 45163
a=mid:m2
a=ssrc:2638
a=rtpmap:99 H264/90000
a=fmtp:99 profile-level-id=4d0028;packetization-mode=1
a=sendrecv
a=rtcp-mux
a=candidate:3 1 UDP 2113667327 192.0.2.2 60400 typ host
a=candidate:3 1 UDP 694302207 198.51.100.2 60500 typ srflx raddr
192.0.2.2 rport 60400
a=candidate:3 1 UDP 73545215 203.0.113.2 60600 typ relay raddr
192.0.2.2 rport 60400
4.2. Multiple Videos
Simple example showing an offer with one audio stream and two video
streams.
v=0
o=- 20518 0 IN IP4 198.51.100.1
s=
t=0 0
c=IN IP4 203.0.113.1
a=ice-ufrag:F7gI
a=ice-pwd:x9cml/YzichV2+XlhiMu8g
a=fingerprint:sha-1
42:89:c5:c6:55:9d:6e:c8:e8:83:55:2a:39:f9:b6:eb:e9:a3:a9:e7
a=group:BUNDLE m1 m2 m3
m=audio 56600 RTP/SAVPF 0 96
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 47434
a=mid:m1
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a=ssrc:32385
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
a=sendrecv
a=rtcp-mux
a=candidate:0 1 UDP 2113667327 192.0.2.1 54400 typ host
a=candidate:1 2 UDP 2113667326 192.0.2.1 54401 typ host
a=candidate:0 1 UDP 694302207 198.51.100.1 55500 typ srflx raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 169430220 198.51.100.1 55501 typ srflx raddr
192.0.2.1 rport 54401
a=candidate:0 1 UDP 73545215 203.0.113.1 56600 typ relay raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 51989708 203.0.113.1 56601 typ relay raddr
192.0.2.1 rport 54401
m=video 56602 RTP/SAVPF 96 98
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 22705
a=mid:m2
a=ssrc:43985
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:98 VP8/90000
a=sendrecv
a=rtcp-mux
a=candidate:2 1 UDP 2113667327 192.0.2.1 54402 typ host
a=candidate:3 2 UDP 2113667326 192.0.2.1 54403 typ host
a=candidate:2 1 UDP 694302207 198.51.100.1 55502 typ srflx raddr
192.0.2.1 rport 54402
a=candidate:3 2 UDP 169430220 198.51.100.1 55503 typ srflx raddr
192.0.2.1 rport 54403
a=candidate:2 1 UDP 73545215 203.0.113.1 56602 typ relay raddr
192.0.2.1 rport 54402
a=candidate:3 2 UDP 51989708 203.0.113.1 56603 typ relay raddr
192.0.2.1 rport 54403
a=ssrc:11111 cname:45:5f:fe:cb:81:e9
m=video 56604 RTP/SAVPF 96 98
a=msid:ma tc
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 64870
a=mid:m3
a=ssrc:54269
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:98 VP8/90000
a=sendrecv
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a=rtcp-mux
a=candidate:4 1 UDP 2113667327 192.0.2.1 54404 typ host
a=candidate:5 2 UDP 2113667326 192.0.2.1 54405 typ host
a=candidate:4 1 UDP 694302207 198.51.100.1 55504 typ srflx raddr
192.0.2.1 rport 54404
a=candidate:5 2 UDP 169430220 198.51.100.1 55505 typ srflx raddr
192.0.2.1 rport 54405
a=candidate:4 1 UDP 73545215 203.0.113.1 56604 typ relay raddr
192.0.2.1 rport 54404
a=candidate:5 2 UDP 51989708 203.0.113.1 56605 typ relay raddr
192.0.2.1 rport 54405
a=ssrc:22222 cname:45:5f:fe:cb:81:e9
4.3. Many Videos
This section adds three video streams and one audio. The video
streams are sent in such a way that they they are only accepted if
the far side supports bundle using the "bundle only" approach
described in Section 3.1. The video streams also use the same
payload types so it will not be possible to demux the video streams
from each other without using the SSRC values.
v=0
o=- 20518 0 IN IP4 198.51.100.1
s=
t=0 0
c=IN IP4 203.0.113.1
a=ice-ufrag:F7gI
a=ice-pwd:x9cml/YzichV2+XlhiMu8g
a=fingerprint:sha-1
42:89:c5:c6:55:9d:6e:c8:e8:83:55:2a:39:f9:b6:eb:e9:a3:a9:e7
a=group:BUNDLE m0 m1 m2 m3
m=audio 56600 RTP/SAVPF 0 96
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 6614
a=mid:m0
a=ssrc:12359
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
a=sendrecv
a=rtcp-mux
a=ssrc:12359 cname:45:5f:fe:cb:81:e9
a=candidate:0 1 UDP 2113667327 192.0.2.1 54400 typ host
a=candidate:1 2 UDP 2113667326 192.0.2.1 54401 typ host
a=candidate:0 1 UDP 694302207 198.51.100.1 55500 typ srflx raddr
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192.0.2.1 rport 54400
a=candidate:1 2 UDP 169430220 198.51.100.1 55501 typ srflx raddr
192.0.2.1 rport 54401
a=candidate:0 1 UDP 73545215 203.0.113.1 56600 typ relay raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 51989708 203.0.113.1 56601 typ relay raddr
192.0.2.1 rport 54401
m=video 0 RTP/SAVPF 96 98
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 24147
a=mid:m1
a=ssrc:26989
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:98 VP8/90000
a=sendrecv
a=rtcp-mux
a=bundle-only
a=ssrc:26989 cname:45:5f:fe:cb:81:e9
m=video 0 RTP/SAVPF 96 98
a=msid:ma tc
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 33989
a=mid:m2
a=ssrc:32986
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:98 VP8/90000
a=sendrecv
a=rtcp-mux
a=bundle-only
a=ssrc:32986 cname:45:5f:fe:cb:81:e9
m=video 0 RTP/SAVPF 96 98
a=msid:ma td
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 61408
a=mid:m3
a=ssrc:46986
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1
a=rtpmap:98 VP8/90000
a=sendrecv
a=rtcp-mux
a=bundle-only
a=ssrc:46986 cname:45:5f:fe:cb:81:e9
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4.4. Multiple Videos with Simulcast
This section shows an offer with with audio and two video each of
which can send it two resolutions as described in Section 3.3. One
video stream supports VP8, while the other supports H.264. All the
video is bundle-only. Note that the use of different codec-specific
parameters causes two different payload types to be used.
v=0
o=- 20518 0 IN IP4 198.51.100.1
s=
t=0 0
c=IN IP4 203.0.113.1
a=ice-ufrag:F7gI
a=ice-pwd:x9cml/YzichV2+XlhiMu8g
a=fingerprint:sha-1
42:89:c5:c6:55:9d:6e:c8:e8:83:55:2a:39:f9:b6:eb:e9:a3:a9:e7
a=group:BUNDLE m0 m1 m2
m=audio 56600 RTP/SAVPF 0 96
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 31727
a=mid:m0
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
a=sendrecv
a=rtcp-mux
a=candidate:0 1 UDP 2113667327 192.0.2.1 54400 typ host
a=candidate:1 2 UDP 2113667326 192.0.2.1 54401 typ host
a=candidate:0 1 UDP 694302207 198.51.100.1 55500 typ srflx raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 169430220 198.51.100.1 55501 typ srflx raddr
192.0.2.1 rport 54401
a=candidate:0 1 UDP 73545215 203.0.113.1 56600 typ relay raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 51989708 203.0.113.1 56601 typ relay raddr
192.0.2.1 rport 54401
m=video 0 RTP/SAVPF 96 100
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 41664
b=AS:1756
a=mid:m1
a=rtpmap:96 VP8/90000
a=ssrc-group:SIMULCAST 58949 28506
a=ssrc:58949 imageattr:96 [x=1280,y=720]
a=ssrc:28506 imageattr:96 [x=640,y=480]
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a=sendrecv
a=rtcp-mux
a=bundle-only
m=video 0 RTP/SAVPF 96 100
a=msid:ma tc
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 14460
b=AS:1756
a=mid:m2
a=rtpmap:96 H264/90000
a=fmtp:96 profile-level-id=4d0028;packetization-mode=1;max-fr=30
a=rtpmap:100 H264/90000
a=fmtp:100 profile-level-id=4d0028;packetization-mode=1;max-fr=15
a=ssrc-group:SIMULCAST 18875 54986
a=ssrc:18875
a=ssrc:54986
a=sendrecv
a=rtcp-mux
a=bundle-only
4.5. Video with Simulcast and RTX
This section shows an SDP offer that has an audio and a single video
stream. The video stream that is simulcast at two resolutions and
has [RFC4588] style re-transmission flows.
v=0
o=- 20518 0 IN IP4 198.51.100.1
s=
t=0 0
c=IN IP4 203.0.113.1
a=ice-ufrag:F7gI
a=ice-pwd:x9cml/YzichV2+XlhiMu8g
a=fingerprint:sha-1
42:89:c5:c6:55:9d:6e:c8:e8:83:55:2a:39:f9:b6:eb:e9:a3:a9:e7
a=group:BUNDLE m0 m1
m=audio 56600 RTP/SAVPF 0 96
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 42123
a=mid:m0
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
a=sendrecv
a=rtcp-mux
a=candidate:0 1 UDP 2113667327 192.0.2.1 54400 typ host
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a=candidate:1 2 UDP 2113667326 192.0.2.1 54401 typ host
a=candidate:0 1 UDP 694302207 198.51.100.1 55500 typ srflx raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 169430220 198.51.100.1 55501 typ srflx raddr
192.0.2.1 rport 54401
a=candidate:0 1 UDP 73545215 203.0.113.1 56600 typ relay raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 51989708 203.0.113.1 56601 typ relay raddr
192.0.2.1 rport 54401
m=video 0 RTP/SAVPF 96 101
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 60725
b=AS:2500
a=mid:m1
a=rtpmap:96 VP8/90000
a=rtpmap:101 rtx/90000
a=fmtp:101 apt=96;rtx-time=3000
a=ssrc-group:SIMULCAST 78909 43567
a=ssrc-group:FID 78909 56789
a=ssrc-group:FID 43567 13098
a=ssrc:78909
a=ssrc:43567
a=ssrc:13098
a=ssrc:56789
a=sendrecv
a=rtcp-mux
a=bundle-only
4.6. Video with Simulcast and FEC
This section shows an SDP offer that has an audio and a single video
stream. The video stream that is simulcast at two resolutions and
has [RFC5956] style FEC flows.
v=0
o=- 20518 0 IN IP4 198.51.100.1
s=
t=0 0
c=IN IP4 203.0.113.1
a=ice-ufrag:F7gI
a=ice-pwd:x9cml/YzichV2+XlhiMu8g
a=fingerprint:sha-1
42:89:c5:c6:55:9d:6e:c8:e8:83:55:2a:39:f9:b6:eb:e9:a3:a9:e7
a=group:BUNDLE m0 m1
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m=audio 56600 RTP/SAVPF 0 96
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 42123
a=mid:m0
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
a=sendrecv
a=rtcp-mux
a=candidate:0 1 UDP 2113667327 192.0.2.1 54400 typ host
a=candidate:1 2 UDP 2113667326 192.0.2.1 54401 typ host
a=candidate:0 1 UDP 694302207 198.51.100.1 55500 typ srflx raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 169430220 198.51.100.1 55501 typ srflx raddr
192.0.2.1 rport 54401
a=candidate:0 1 UDP 73545215 203.0.113.1 56600 typ relay raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 51989708 203.0.113.1 56601 typ relay raddr
192.0.2.1 rport 54401
m=video 0 RTP/SAVPF 96 101
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 60725
b=AS:2500
a=mid:m1
a=rtpmap:96 VP8/90000
a=rtpmap:101 1d-interleaved-parityfec/90000
a=fmtp:96 max-fr=30;max-fs=8040
a=fmtp:101 L=5; D=10; repair-window=200000
a=ssrc-group:SIMULCAST 56780 34511
a=ssrc-group:FEC-FR 56780 48675
a=ssrc-group:FEC-FR 34511 21567
a=ssrc:56780
a=ssrc:34511
a=ssrc:21567
a=ssrc:48675
a=sendrecv
a=rtcp-mux
a=bundle-only
4.7. Video with Layered Coding
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This section shows an SDP offer that has an audio and a single video
stream. The video stream that is layered coding at 3 different
resolutions based on [RFC5583]. The video m=lines shows 3 streams
with last stream (payload 100) dependent on streams with payload 96
and 97 for decoding.
v=0
o=- 20518 0 IN IP4 198.51.100.1
s=
t=0 0
c=IN IP4 203.0.113.1
a=ice-ufrag:F7gI
a=ice-pwd:x9cml/YzichV2+XlhiMu8g
a=fingerprint:sha-1
42:89:c5:c6:55:9d:6e:c8:e8:83:55:2a:39:f9:b6:eb:e9:a3:a9:e7
a=group:BUNDLE m0 m1
m=audio 56600 RTP/SAVPF 0 96
a=msid:ma ta
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 42123
a=mid:m0
a=rtpmap:0 PCMU/8000
a=rtpmap:96 opus/48000
a=ptime:20
a=sendrecv
a=rtcp-mux
a=candidate:0 1 UDP 2113667327 192.0.2.1 54400 typ host
a=candidate:1 2 UDP 2113667326 192.0.2.1 54401 typ host
a=candidate:0 1 UDP 694302207 198.51.100.1 55500 typ srflx raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 169430220 198.51.100.1 55501 typ srflx raddr
192.0.2.1 rport 54401
a=candidate:0 1 UDP 73545215 203.0.113.1 56600 typ relay raddr
192.0.2.1 rport 54400
a=candidate:1 2 UDP 51989708 203.0.113.1 56601 typ relay raddr
192.0.2.1 rport 54401
m=video 0 RTP/SAVPF 96 97 100
a=msid:ma tb
a=extmap:1 urn:ietf:params:rtp-hdrext:stream-correlator 60725
b=AS:2500
a=mid:m1
a=rtpmap:96 H264/90000
a=fmtp:96 max-fr=30;max-fs=8040
a=rtpmap:97 H264/90000
a=fmtp:97 max-fr=15;max-fs=1200
a=rtpmap:100 H264-SVC/90000
a=fmtp:100 max-fr=30;max-fs=8040
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a=depend:100 lay m1:96,97;
a=ssrc:48970
a=ssrc:90898
a=ssrc:66997
a=sendrecv
a=rtcp-mux
a=bundle-only
5. Security Considerations
TBD
6. IANA Considerations
TBD
7. Acknowledgements
Thanks to Cullen Jennings and Suhas Nandakumar for their assistance
in generating the SDP examples in this document.
Some of the material in this document was taken from
[I-D.jennings-rtcweb-plan].
8. References
8.1. Normative References
[I-D.ietf-mmusic-sdp-bundle-negotiation]
Holmberg, C., Alvestrand, H., and C. Jennings,
"Multiplexing Negotiation Using Session Description
Protocol (SDP) Port Numbers", draft-ietf-mmusic-sdp-
bundle-negotiation-03 (work in progress), February 2013.
[I-D.jennings-mmusic-media-req]
Jennings, C., Uberti, J., and E. Rescorla, "Requirements
from various WG for MMUSIC", draft-jennings-mmusic-media-
req-00 (work in progress), February 2013.
[I-D.nandakumar-mmusic-sdp-mux-attributes]
Nandakumar, S., "A Framework for SDP Attributes when
Multiplexing", draft-nandakumar-mmusic-sdp-mux-
attributes-02 (work in progress), April 2013.
[I-D.westerlund-avtcore-rtp-simulcast]
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Westerlund, M., Lindqvist, M., and F. Jansson, "Using
Simulcast in RTP Sessions", draft-westerlund-avtcore-rtp-
simulcast-02 (work in progress), February 2013.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC3264] Rosenberg, J. and H. Schulzrinne, "An Offer/Answer Model
with Session Description Protocol (SDP)", RFC 3264, June
2002.
[RFC4566] Handley, M., Jacobson, V., and C. Perkins, "SDP: Session
Description Protocol", RFC 4566, July 2006.
[RFC5576] Lennox, J., Ott, J., and T. Schierl, "Source-Specific
Media Attributes in the Session Description Protocol
(SDP)", RFC 5576, June 2009.
[RFC5888] Camarillo, G. and H. Schulzrinne, "The Session Description
Protocol (SDP) Grouping Framework", RFC 5888, June 2010.
8.2. Informative References
[I-D.ietf-rtcweb-rtp-usage]
Perkins, C., Westerlund, M., and J. Ott, "Web Real-Time
Communication (WebRTC): Media Transport and Use of RTP",
draft-ietf-rtcweb-rtp-usage-06 (work in progress),
February 2013.
[I-D.jennings-rtcweb-plan]
Jennings, C., "Proposed Plan for Usage of SDP and RTP",
draft-jennings-rtcweb-plan-01 (work in progress), February
2013.
[RFC3550] Schulzrinne, H., Casner, S., Frederick, R., and V.
Jacobson, "RTP: A Transport Protocol for Real-Time
Applications", STD 64, RFC 3550, July 2003.
[RFC3551] Schulzrinne, H. and S. Casner, "RTP Profile for Audio and
Video Conferences with Minimal Control", STD 65, RFC 3551,
July 2003.
[RFC4588] Rey, J., Leon, D., Miyazaki, A., Varsa, V., and R.
Hakenberg, "RTP Retransmission Payload Format", RFC 4588,
July 2006.
[RFC5117] Westerlund, M. and S. Wenger, "RTP Topologies", RFC 5117,
January 2008.
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[RFC5245] Rosenberg, J., "Interactive Connectivity Establishment
(ICE): A Protocol for Network Address Translator (NAT)
Traversal for Offer/Answer Protocols", RFC 5245, April
2010.
[RFC5285] Singer, D. and H. Desineni, "A General Mechanism for RTP
Header Extensions", RFC 5285, July 2008.
[RFC5583] Schierl, T. and S. Wenger, "Signaling Media Decoding
Dependency in the Session Description Protocol (SDP)", RFC
5583, July 2009.
[RFC5761] Perkins, C. and M. Westerlund, "Multiplexing RTP Data and
Control Packets on a Single Port", RFC 5761, April 2010.
[RFC5956] Begen, A., "Forward Error Correction Grouping Semantics in
the Session Description Protocol", RFC 5956, September
2010.
[iana.rtp-pt]
IANA, "RTP Payload types (PT) for standard audio and video
encodings", July 2013.
Available at http://www.iana.org/assignments/rtp-
parameters/rtp-parameters.xhtml#rtp-parameters-1
[webrtc-api]
Bergkvist, Burnett, Jennings, Narayanan, , "WebRTC 1.0:
Real-time Communication Between Browsers", October 2011.
Available at http://dev.w3.org/2011/webrtc/editor/
webrtc.html
Authors' Addresses
Adam Roach
Mozilla
Dallas, TX
US
Phone: +1 650 903 0800 x863
Email: adam@nostrum.com
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Justin Uberti
Google
747 6th St. S
Kirkland, WA 98033
USA
Email: justin@uberti.name
Martin Thomson
Microsoft
3210 Porter Drive
Palo Alto, CA 94304
US
Phone: +1 650 353 1925
Email: martin.thomson@skype.net
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