This document defines a set of ECMAScript APIs in WebIDL to extend the WebRTC 1.0 API
to enable user agents to support scalable video coding (SVC).
Status of This Document
This section describes the status of this
document at the time of its publication. A list of current W3C
publications and the latest revision of this technical report can be found
in the W3C technical reports index at
https://www.w3.org/TR/.
The API is based on preliminary work done in the W3C ORTC Community Group.
Publication as a Working Draft does not
imply endorsement by W3C and its Members.
This is a draft document and may be updated, replaced or obsoleted by other
documents at any time. It is inappropriate to cite this document as other
than work in progress.
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Essential Claim(s)
must disclose the information in accordance with
section 6 of the W3C Patent Policy.
This specification extends the WebRTC specification [WEBRTC] to
enable configuration of encoding parameters for Scalable Video
Coding (SVC). Discovery of SVC encoder and decoder capabilities
is out of scope.
Since this specification does not change the behavior of WebRTC
objects and methods, restrictions relating to Offer/Answer negotiation and
encoding parameters remain, as described in [WEBRTC] Section 5.2:
"setParameters() does not cause SDP renegotiation and can
only be used to change what the media stack is sending or receiving within the
envelope negotiated by Offer/Answer."
The configuration of SVC-capable codecs implemented in browsers fits within this
restriction. Codecs such as VP8 [RFC6386], VP9 [VP9] and AV1 [AV1] do not
negotiate SVC support within Offer/Answer, enabling encoding parameters to be used
for SVC configuration.
2. Conformance
As well as sections marked as non-normative, all authoring guidelines, diagrams, examples, and notes in this specification are non-normative. Everything else in this specification is normative.
The key words MAY, MUST, and SHOULD in this document
are to be interpreted as described in
BCP 14
[RFC2119] [RFC8174]
when, and only when, they appear in all capitals, as shown here.
This specification defines conformance criteria that apply to a single
product: the user agent that implements the interfaces that it
contains.
Conformance requirements phrased as algorithms or specific steps may be
implemented in any manner, so long as the end result is equivalent. In
particular, the algorithms defined in this specification are intended to be
easy to follow, and not intended to be performant.
Implementations that use ECMAScript to implement the APIs defined in
this specification MUST implement them in a manner consistent with the
ECMAScript Bindings defined in the Web IDL specification [WEBIDL], as
this specification uses that specification and terminology.
3. Terminology
The term "simulcast envelope" is defined in [WEBRTC] Section 5.4.1.
This specification references objects, methods, internal slots
and dictionaries defined in [WEBRTC].
For Scalable Video Coding (SVC), the terms "single-session transmission"
(SST) and "multi-session transmission" (MST) are
defined in [RFC6190]. This specification only supports SST but
not MST.
The term "Single Real-time Transport Protocol stream Single Transport"
(SRST), defined in [RFC7656] Section 3.7, refers to SVC
implementations that transmit all layers within a single transport,
using a single Real-time Transport Protocol (RTP) stream and
synchronization source (SSRC). The term "Multiple RTP stream Single
Transport" (MRST), also defined in [RFC7656] Section 3.7,
refers to implementations that transmit all layers within a single
transport, using multiple RTP streams with a distinct SSRC for each layer.
This specification only supports SRST, not MRST. Codecs
with RTP payload specifications supporting SRST include VP8
[RFC7741], VP9 [VP9-PAYLOAD], AV1 [AV1-RTP-SPEC] and H.264/SVC
[RFC6190].
If RTCRtpEncodingParameters stored in
sendEncodings contains more than 1
encoding with an active
member with a value of true and
sendEncodings contains any encoding whose
scalabilityMode value
represents an "S mode" and whose
active member has a
value of true, throw an
OperationError.
When the addTransceiver() and
setCodecPreferences() methods are called
prior to conclusion of the Offer/Answer negotiation, the negotiated
codec and its capabilities may not be known. In this situation the
scalabilityMode values configured
in sendEncodings may not be supported
by the eventually negotiated codec. However, an error will only result
if the requested scalabilityMode value is
invalid for any supported codec, or if mixed simulcast transport is requested.
So as to ensure that the desired scalabilityMode
values can be applied, setCodecPreferences() can be
used to prefer or only include codecs supporting the desired configuration.
For example, if temporal scalability is desired along with spatial simulcast,
when addTransceiver() is called,
sendEncodings can be configured to send multiple
simulcast streams with different resolutions, with each stream
utilizing temporal scalability. If only the VP8, VP9 and AV1 codec implementations
support temporal scalability, setCodecPreferences()
can be used to remove the H.264/AVC codec from the Offer, improving the
chances that a codec supporting temporal scalability is negotiated.
When sendEncodings is used to
request the sending of multiple simulcast streams using
addTransceiver(), an "S mode" cannot
be requested. The browser may only be configured to send
simulcast encodings with multiple SSRCs and RIDs, or
alternatively, to send all simulcast encodings on a single
RTP stream. Simultaneously using both simulcast transport
techniques is not permitted.
If encodings contains any encoding with an existng
RTCRtpEncodingParameters.codec value codec, where the same encoding's
scalabilityMode value is not supported by codec.
Else if sender.[[SendCodecs]]is not empty
and encodings contains an encoding whose
scalabilityMode value is
not supported by the codec used for the encoding's RTP stream.
If RTCRtpEncodingParameters stored in
encodings contains more than one
encoding with an active
member with a value of true and
encodings contains any encoding whose
scalabilityMode value
represents an "S mode" and whose
active member has a
value of true.
After the initial negotiation has completed, getParameters()
returns the currently configured scalabilityMode
value for each encoding in encodings which had a value before the
initial negotiation. This MAY be different from the values requested in
addTransceiver() or setParameters().
For example, if the codecs selected during negotiation do not include an
encoder supporting the desired scalabilityMode
value, the user agent MAY select another value. If the configuration is not
satisfactory, setParameters() can be used to change it.
The [Media-Capabilities] API enables discovery of encoder and decoder
support for scalable video coding. scalabilityMode
is used to query whether an encoder supports a particular
scalabilityMode value. The API indicates
whether the scalabilityMode value
is "supported", "smooth" and "power efficient".
The [Media-Capabilities] API also provides information on decoder support
for spatial scalablity modes. spatialScalability
indicates whether a decoder has the ability to support spatial prediction,
which requires the ability to use frames of a resolution different than
the current resolution as a dependency. If spatialScalability
is set to true, the decoder can decode any
scalabilityMode value supported by the encoder.
If spatialScalability is set to false
or is absent, the decoder cannot decode spatial scalability modes, but can
can decode all other scalabilityMode values
supported by the encoder.
5.1 Negotiation with an SFM
This section is non-normative.
The SFM
can provide information on the codecs and scalability modes it can
decode by providing its receiver capabilities.
After exchanging capabilities, the application can compute the
intersection of codecs and scalabilityMode
values supported by the browser's RTCRtpSender and the
SFM's receiver. This
can be used to determine the arguments passed to the browser's
addTransceiver() and setParameters()
methods.
There are situations where an SFM
may only support reception of a subset of codecs and scalability modes.
For example, an SFM that parses
codec payloads may only support the H.264/AVC codec without scalability and
the VP8 codec with temporal scalability. On the other hand, the browser
may be able to encode VP8 with temporal scalability, VP9 with temporal
and spatial scalability and or H.264/AVC with temporal scalability.
In such a situation, an application desiring to use SVC would only
be able to encode VP8 with temporal scalability.
Since sending simulcast encodings on a single stream is not negotiated within
Offer/Answer, an application using SDP signaling needs to determine whether
single stream simulcast transport is supported prior to the Offer/Answer negotiation.
This can be handled by having the SFM
send it's receiver capabilities to the application prior to Offer/Answer.
This allows the application to determine whether single stream simulcast is
supported, and if so, what scalability modes the
SFM can handle. For example,
an SFM that can only support
reception of a maximum of 2 simulcast encodings on a single SSRC with the
AV1 codec would only indicate support for the "S2T1" and "S2T1h" scalability
modes in its receiver capabilities.
For an SFM the supported
scalabilityMode values may depend on the negotiated RTP
header extensions. For example, if the SFM
cannot parse codec payloads (either because it is not designed to do so, or
because the payloads are encrypted), then negotiation of an RTP header extension
(such as the AV1 Dependency Descriptor defined in Appendix A of [AV1-RTP-SPEC])
could be a prerequisite for the SFM
to forward a scalabilityMode value. As a result,
the scalabilityMode values supported by an
SFM may not be determined until
completion of the Offer/Answer negotiation.
6. Scalability modes
The scalabilityMode values supported in this specification,
as well as their associated identifiers and characteristics, are provided in the table
below. The names of the scalabilityMode values (which are
case sensitive) are provided, along with the scalability mode identifiers assigned in
[AV1] Section 6.7.5, and links to dependency diagrams provided in Section 10.
While the [AV1] and VP9 [VP9] specifications support all the
scalabilityMode values defined in the table, other codec
specifications do not. For example, VP8 [RFC6386] only supports temporal scalability
(e.g. "L1T2", "L1T3"); H.264/SVC [RFC6190], which supports both temporal and
spatial scalability, only permits transport of simulcast on distinct SSRCs, so that it
does not support "S" modes, where multiple encodings are transported on a single RTP stream.
When proposing a scalabilityMode value, the following principles should be followed:
The proposed scalabilityModeMUST define entries to the table in
Section 6, including values for the Scalabilty Mode Identifier, spatial and
temporal layers, Resolution Ratio, Inter-layer dependency and the corresponding
AV1 scalability_mode_idc value (if assigned).
The Scalability Mode Identifier SHOULD be consistent with the existing naming scheme, which
utilizes LxTy to denote a scalabilityMode with x
spatial layers using a 2:1 resolution ratio and y temporal layers.
LxTyh denotes x spatial layers with a 1.5:1 resolution ratio and
y temporal layers. SxTy denotes a scalabilityMode
with x simulcast encodings with a 2:1 resolution ratio, with each
simulcast encoding containing y temporal layers. SxTyh denotes
a 1.5:1 resolution ratio. LxTy_KEY denotes a scalabilityMode
with x spatial layers using a 2:1 resolution ratio and y temporal layers in which spatial layers only
depend on lower spatial layers at a key frame. LxTy_KEY_SHIFT modes denotes a
scalabilityMode with x spatial layers using a 2:1 resolution ratio and
y temporal layers in which spatial layers only depend on lower spatial layers at a key frame and subsequent
frames have their temporal identifier shifted upward.
A dependency diagram MUST be supplied, in the format provided in Section 10.
7. Examples
7.1 Spatial Simulcast and Temporal Scalability
This section is non-normative.
This example extends [WEBRTC] Section 7.1 (Example 1) to demonstrate sending three spatial
simulcast layers each with three temporal layers, using an SSRC and RID for each simulcast
layer. Only the "sendEncodings" attribute is changed from the original example.
This section is non-normative; it specifies no new behaviour, but
instead summarizes information already present in other parts of the
specification. The privacy considerations
for the WebRTC APIs are described in [WEBRTC] Section 13.
8.1 Persistent information
In WebRTC, the use of scalable coding tools is not
negotiated between peers, so neither supported
scalabilityMode values nor
decoder support for spatial prediction is exposed in SDP.
By attempting to set
scalabilityMode values for
each codec using the setParameters() API,
an application can determine the values supported by the
encoder, by noting which configuration attempts succeed
and which ones fail. However, this does not indicate
whether a scalabilityMode
value is supported by a hardware or software encoder
(or both). Since setParameters()
is not supported for the RTCRtpReceiver, equivalent
experiments cannot be run to determine decoder support.
Since the scalabilityMode
values supported by software encoders are typically
a superset of those supported in hardware, the information
available from these experiments has a high correlation
with the browser in use, which is already available to
web pages. Once media is flowing, information on
performance characteristics or whether a
scalabilityMode value
is decodable for the codec in use can be obtained,
which provides more information on hardware capabilities.
As noted in [Media-Capabilities] Section 3.1, the Media
Capabilities API "will likely provide more accurate and
consistent information" than is available from the
WebRTC-SVC API. Media Capabilities provides information
on encoder and decoder capabilities, indicating whether
a proposed configuration (including a
scalabilityMode value) is
"supported", "smooth" and "power efficient".
[Media-Capabilities] API also indicates whether the
decoder supports spatial prediction. As noted in
[Media-Capabilities] Section 3.1, "This information is
expected to have a high correlation with other information
already available to the web pages as a given class of
device is expected to have very similar decoding/encoding
capabilities."
9. Security Considerations
This section is non-normative.
This section is non-normative; it specifies no new behaviour, but
instead summarizes information already present in other parts of the
specification. WebRTC protocol security considerations are described
in [RFC8827] and the security and privacy considerations
for the WebRTC APIs are described in [WEBRTC] Section 13.
10. Scalability Mode Dependency Diagrams
Dependency diagrams for the scability modes defined in this specification
are provided below.
Figure 19
L3T3_KEY_SHIFT: 3-layer spatial and 3-layer temporal scalability K-SVC with temporal shift
10.20 S2T1 and S2T1h
Figure 20
S2T1 and S2T1h: 2-layer spatial simulcast encoding
10.21 S2T2 and S2T2h
Figure 21
S2T2 and S2T2h: 2-layer spatial simulcast and 2-layer temporal scalability encoding
10.22 S2T3 and S2T3h
Figure 22
S2T3 and S2T3h: 2-layer spatial simulcast and 3-layer temporal scalability encoding
10.23 S3T1 and S3T1h
Figure 23
S3T1 and S3T1h: 3-layer spatial simulcast encoding
10.24 S3T2 and S3T2h
Figure 24
S3T2 and S3T2h: 3-layer spatial simulcast and 2-layer temporal scalability encoding
10.25 S3T3 and S3T3h
Figure 25
S3T3 and S3T3h: 3-layer spatial simulcast and 3-layer temporal scalability encoding
A. Acknowledgements
The editors wish to thank Robin Raymond, Michael Horowitz, Harald Alvestrand,
Chris Cunningham, Danil Chapovalov, Florent Castelli and Henrik Boström for their
contributions to this specification, which evolved from the ORTC API
developed in the W3C ORTC CG.
