From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc6679.txt | 3251 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 3251 insertions(+) create mode 100644 doc/rfc/rfc6679.txt (limited to 'doc/rfc/rfc6679.txt') diff --git a/doc/rfc/rfc6679.txt b/doc/rfc/rfc6679.txt new file mode 100644 index 0000000..17cd251 --- /dev/null +++ b/doc/rfc/rfc6679.txt @@ -0,0 +1,3251 @@ + + + + + + +Internet Engineering Task Force (IETF) M. Westerlund +Request for Comments: 6679 I. Johansson +Category: Standards Track Ericsson +ISSN: 2070-1721 C. Perkins + University of Glasgow + P. O'Hanlon + University of Oxford + K. Carlberg + G11 + August 2012 + + + Explicit Congestion Notification (ECN) for RTP over UDP + +Abstract + + This memo specifies how Explicit Congestion Notification (ECN) can be + used with the Real-time Transport Protocol (RTP) running over UDP, + using the RTP Control Protocol (RTCP) as a feedback mechanism. It + defines a new RTCP Extended Report (XR) block for periodic ECN + feedback, a new RTCP transport feedback message for timely reporting + of congestion events, and a Session Traversal Utilities for NAT + (STUN) extension used in the optional initialisation method using + Interactive Connectivity Establishment (ICE). Signalling and + procedures for negotiation of capabilities and initialisation methods + are also defined. + +Status of This Memo + + This is an Internet Standards Track document. + + This document is a product of the Internet Engineering Task Force + (IETF). It represents the consensus of the IETF community. It has + received public review and has been approved for publication by the + Internet Engineering Steering Group (IESG). Further information on + Internet Standards is available in Section 2 of RFC 5741. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + http://www.rfc-editor.org/info/rfc6679. + + + + + + + + + + + +Westerlund, et al. Standards Track [Page 1] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +Copyright Notice + + Copyright (c) 2012 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 + (http://trustee.ietf.org/license-info) in effect on the date of + publication of this document. Please review these documents + carefully, as they describe your rights and restrictions with respect + to this document. Code Components extracted from this document must + include Simplified BSD License text as described in Section 4.e of + the Trust Legal Provisions and are provided without warranty as + described in the Simplified BSD License. + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Westerlund, et al. Standards Track [Page 2] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +Table of Contents + + 1. Introduction ....................................................4 + 2. Conventions, Definitions, and Acronyms ..........................5 + 3. Discussion, Requirements, and Design Rationale ..................6 + 3.1. Requirements ...............................................8 + 3.2. Applicability ..............................................8 + 3.3. Interoperability ..........................................12 + 4. Overview of Use of ECN with RTP/UDP/IP .........................13 + 5. RTCP Extensions for ECN Feedback ...............................16 + 5.1. RTP/AVPF Transport-Layer ECN Feedback Packet ..............16 + 5.2. RTCP XR Report Block for ECN Summary Information ..........19 + 6. SDP Signalling Extensions for ECN ..............................21 + 6.1. Signalling ECN Capability Using SDP .......................21 + 6.2. RTCP ECN Feedback SDP Parameter ...........................26 + 6.3. XR Block ECN SDP Parameter ................................26 + 6.4. ICE Parameter to Signal ECN Capability ....................27 + 7. Use of ECN with RTP/UDP/IP .....................................27 + 7.1. Negotiation of ECN Capability .............................27 + 7.2. Initiation of ECN Use in an RTP Session ...................28 + 7.3. Ongoing Use of ECN within an RTP Session ..................35 + 7.4. Detecting Failures ........................................38 + 8. Processing ECN in RTP Translators and Mixers ...................42 + 8.1. Transport Translators .....................................42 + 8.2. Fragmentation and Reassembly in Translators ...............43 + 8.3. Generating RTCP ECN Feedback in Media Transcoders .........45 + 8.4. Generating RTCP ECN Feedback in Mixers ....................46 + 9. Implementation Considerations ..................................47 + 10. IANA Considerations ...........................................47 + 10.1. SDP Attribute Registration ...............................47 + 10.2. RTP/AVPF Transport-Layer Feedback Message ................47 + 10.3. RTCP Feedback SDP Parameter ..............................48 + 10.4. RTCP XR Report Blocks ....................................48 + 10.5. RTCP XR SDP Parameter ....................................48 + 10.6. STUN Attribute ...........................................48 + 10.7. ICE Option ...............................................48 + 11. Security Considerations .......................................48 + 12. Examples of SDP Signalling ....................................51 + 12.1. Basic SDP Offer/Answer ...................................52 + 12.2. Declarative Multicast SDP ................................54 + 13. Acknowledgments ...............................................54 + 14. References ....................................................55 + 14.1. Normative References .....................................55 + 14.2. Informative References ...................................56 + + + + + + + +Westerlund, et al. Standards Track [Page 3] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +1. Introduction + + This memo outlines how Explicit Congestion Notification (ECN) + [RFC3168] can be used for Real-time Transport Protocol (RTP) + [RFC3550] flows running over UDP/IP that use the RTP Control Protocol + (RTCP) as a feedback mechanism. The solution consists of feedback of + ECN congestion experienced markings to the sender using RTCP, + verification of ECN functionality end-to-end, and procedures for how + to initiate ECN usage. Since the initiation process has some + dependencies on the signalling mechanism used to establish the RTP + session, a specification for signalling mechanisms using the Session + Description Protocol (SDP) [RFC4566] is included. + + ECN can be used to minimise the impact of congestion on real-time + multimedia traffic. The use of ECN provides a way for the network to + send congestion control signals to the media transport without having + to impair the media. Unlike packet loss, ECN signals unambiguously + indicate congestion to the transport as quickly as feedback delays + allow and without confusing congestion with losses that might have + occurred for other reasons such as transmission errors, packet-size + errors, routing errors, badly implemented middleboxes, policy + violations, and so forth. + + The introduction of ECN into the Internet requires changes to both + the network and transport layers. At the network layer, IP + forwarding has to be updated to allow routers to mark packets, rather + than discarding them in times of congestion [RFC3168]. In addition, + transport protocols have to be modified to inform the sender that + ECN-marked packets are being received, so it can respond to the + congestion. The Transmission Control Protocol (TCP) [RFC3168], + Stream Control Transmission Protocol (SCTP) [RFC4960], and Datagram + Congestion Control Protocol (DCCP) [RFC4340] have been updated to + support ECN, but to date, there is no specification describing how + UDP-based transports, such as RTP [RFC3550], can use ECN. This is + due to the lack of feedback mechanisms in UDP. Instead, the + signalling control protocol on top of UDP needs to provide that + feedback. For RTP, that feedback is provided by RTCP. + + The remainder of this memo is structured as follows. We start by + describing the conventions, definitions, and acronyms used in this + memo in Section 2 and the design rationale and applicability in + Section 3. Section 4 gives an overview of how ECN is used with RTP + over UDP. RTCP extensions for ECN feedback are defined in Section 5 + and SDP signalling extensions in Section 6. The details of how ECN + is used with RTP over UDP are defined in Section 7. In Section 8, we + describe how ECN is handled in RTP translators and mixers. Section 9 + discusses some implementation considerations; Section 10 lists IANA + considerations; and Section 11 discusses security considerations. + + + +Westerlund, et al. Standards Track [Page 4] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + Finally, Section 12 provides some examples of SDP signalling for ECN + feedback + +2. Conventions, Definitions, and Acronyms + + The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", + "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and + "OPTIONAL" in this document are to be interpreted as described in RFC + 2119 [RFC2119]. + + Definitions and Abbreviations: + + Sender: A sender of RTP packets carrying an encoded media stream. + The sender can change how the media transmission is performed by + varying the media coding or packetisation. It is one endpoint of + the ECN control loop. + + Receiver: A receiver of RTP packets with the intention to consume + the media stream. It sends RTCP feedback on the received stream. + It is the other endpoint of the ECN control loop. + + ECN-Capable Host: A sender or receiver of a media stream that is + capable of setting and/or processing ECN marks. + + ECN-Capable Transport (ECT): A transport flow where both sender and + receiver are ECN-capable hosts. Packets sent by an ECN-capable + transport will be marked as ECT(0) or ECT(1) on transmission. See + [RFC3168] for the definition of the ECT(0) and ECT(1) marks. + + ECN-CE: ECN Congestion Experienced mark (see [RFC3168]). + + ECN-Capable Packets: Packets with ECN mark set to either ECT(0), + ECT(1), or ECN-CE. + + Not-ECT packets: Packets that are not sent by an ECN-capable + transport and are not ECN-CE marked. + + ECN-Capable Queue: A queue that supports ECN-CE marking of ECN- + capable packets to indicate congestion. + + ECN-Blocking Middlebox: A middlebox that discards ECN-capable + packets. + + ECN-Reverting Middlebox: A middlebox that changes ECN-capable + packets to not-ECT packets by removing the ECN mark. + + + + + + +Westerlund, et al. Standards Track [Page 5] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + Note that RTP mixers or translators that operate in such a manner + that they terminate or split the ECN control loop will take on the + role of receivers or senders. This is further discussed in + Section 3.2. + +3. Discussion, Requirements, and Design Rationale + + ECN has been specified for use with TCP [RFC3168], SCTP [RFC4960], + and DCCP [RFC4340] transports. These are all unicast protocols that + negotiate the use of ECN during the initial connection establishment + handshake (supporting incremental deployment and checking if ECN- + marked packets pass all middleboxes on the path). ECN-CE marks are + immediately echoed back to the sender by the receiving endpoint using + an additional bit in feedback messages, and the sender then + interprets the mark as equivalent to a packet loss for congestion + control purposes. + + If RTP is run over TCP, SCTP, or DCCP, it can use the native ECN + support provided by those protocols. This memo does not concern + itself further with these use cases. However, RTP is more commonly + run over UDP. This combination does not currently support ECN, and + we observe that it has significant differences from the other + transport protocols for which ECN has been specified. These include: + + Signalling: RTP relies on separate signalling protocols to negotiate + parameters before a session can be created and doesn't include an + in-band handshake or negotiation at session setup time (i.e., + there is no equivalent to the TCP three-way handshake in RTP). + + Feedback: RTP does not explicitly acknowledge receipt of datagrams. + Instead, the RTP Control Protocol (RTCP) provides reception + quality feedback, and other back channel communication, for RTP + sessions. The feedback interval is generally on the order of + seconds, rather than once per network round-trip time (RTT) + (although the RTP Audio-Visual Profile with Feedback (RTP/AVPF) + profile [RFC4585] allows more rapid feedback in most cases). RTCP + is also very much oriented around counting packets, which makes + byte-counting congestion algorithms difficult to utilise. + + Congestion Response: While it is possible to adapt the transmission + of many audio/visual streams in response to network congestion, + and such adaptation is required by [RFC3550], the dynamics of the + congestion response may be quite different to that of TCP or other + transport protocols. + + Middleboxes: The RTP framework explicitly supports the concept of + mixers and translators, which are middleboxes that are involved in + media transport functions. + + + +Westerlund, et al. Standards Track [Page 6] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + Multicast: RTP is explicitly a group communication protocol and was + designed from the start to support IP multicast (primarily Any- + Source Multicast (ASM) [RFC1112], although a recent extension + supports Source-Specific Multicast (SSM) [RFC3569] with unicast + feedback [RFC5760]). + + Application Awareness: When ECN support is provided within the + transport protocol, the ability of the application to react to + congestion is limited, since it has little visibility into the + transport layer. By adding support of ECN to RTP using RTCP + feedback, the application is made aware of congestion, allowing a + wider range of reactions in response to that congestion + indication. + + Counting vs. Detecting Congestion: TCP, and the protocols derived + from it, are mainly designed to respond in the same way whether + they experience a burst of congestion indications within one RTT + or just a single congestion indication, whereas real-time + applications may be concerned with the amount of congestion + experienced and whether it is distributed smoothly or in bursts. + When feedback of ECN was added to TCP [RFC3168], the receiver was + designed to flip the echo congestion experienced (ECE) flag to 1 + for a whole RTT then flop it back to zero. ECN feedback in RTCP, + however, will need to report a count of how much congestion has + been experienced within an RTCP reporting period, irrespective of + round-trip times. + + These differences significantly alter the shape of ECN support in RTP + over UDP compared to ECN support in TCP, SCTP, and DCCP but do not + invalidate the need for ECN support. + + ECN support is more important for RTP sessions than, for instance, is + the case for many applications over TCP. This is because the impact + of packet loss in real-time audio-visual media flows is highly + visible to users. For TCP-based applications, however, TCP will + retransmit lost packets, and while extra delay is incurred by having + packets dropped rather than ECN-CE marked, the loss is repaired. + Effective ECN support for RTP flows running over UDP will allow real- + time audio-visual applications to respond to the onset of congestion + before routers are forced to drop packets, allowing those + applications to control how they reduce their transmission rate and + hence media quality, rather than responding to and trying to conceal + the effects of unpredictable packet loss. Furthermore, widespread + deployment for ECN and active queue management in routers, should it + occur, can potentially reduce unnecessary queuing delays in routers, + lowering the round-trip time and benefiting interactive applications + of RTP, such as voice telephony. + + + + +Westerlund, et al. Standards Track [Page 7] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +3.1. Requirements + + Considering ECN, transport protocols supporting ECN, and RTP-based + applications, one can create a set of requirements that must be + satisfied to at least some degree if ECN is to be used by RTP over + UDP. + + o REQ 1: A mechanism must exist to negotiate and initiate the use of + ECN for RTP/UDP/IP sessions so that an RTP sender will not send + packets with ECT in the IP header unless it knows that all + potential receivers will understand any ECN-CE indications they + might receive. + + o REQ 2: A mechanism must exist to feed back the reception of any + packets that are ECN-CE marked to the packet sender. + + o REQ 3: The provided mechanism should minimise the possibility of + cheating (either by the sender or receiver). + + o REQ 4: Some detection and fallback mechanism should exist to avoid + loss of communication due to the attempted usage of ECN in case an + intermediate node clears ECT or drops packets that are ECT marked. + + o REQ 5: Negotiation of ECN should not significantly increase the + time taken to negotiate and set up the RTP session (an extra RTT + before the media can flow is unlikely to be acceptable for some + use cases). + + o REQ 6: Negotiation of ECN should not cause media clipping at the + start of a session. + + The following sections describe how these requirements can be met for + RTP over UDP. + +3.2. Applicability + + The use of ECN with RTP over UDP is dependent on negotiation of ECN + capability between the sender and receiver(s) and validation of ECN + support in all elements on the network path(s) traversed. RTP is + used in a heterogeneous range of network environments and topologies, + with different signalling protocols. The mechanisms defined here + make it possible to verify support for ECN in each of these + environments, irrespective of the topology. + + Due to the need for each RTP sender that intends to use ECN with RTP + to track all participants in the RTP session, the sub-sampling of the + group membership as specified by "Sampling of the Group Membership in + RTP" [RFC2762] MUST NOT be used. + + + +Westerlund, et al. Standards Track [Page 8] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + The use of ECN is further dependent on a capability of the RTP media + flow to react to congestion signalled by ECN-marked packets. + Depending on the application, media codec, and network topology, this + adaptation can occur in various forms and at various nodes. As an + example, the sender can change the media encoding, the receiver can + change the subscription to a layered encoding, or either reaction can + be accomplished by a transcoding middlebox. [RFC5117] identifies + seven topologies in which RTP sessions may be configured and which + may affect the ability to use ECN: + + Topo-Point-to-Point: This utilises standard unicast flows. ECN may + be used with RTP in this topology in an analogous manner to its + use with other unicast transport protocols, with RTCP conveying + ECN feedback messages. + + Topo-Multicast: This is either an Any-Source Multicast (ASM) group + [RFC3569] with potentially several active senders and multicast + RTCP feedback or a Source-Specific Multicast (SSM) group [RFC4607] + with a single distribution source and unicast RTCP feedback from + receivers. RTCP is designed to scale to large group sizes while + avoiding feedback implosion (see Section 6.2 of [RFC3550], + [RFC4585], and [RFC5760]) and can be used by a sender to determine + if all its receivers, and the network paths to those receivers, + support ECN (see Section 7.2). It is somewhat more difficult to + determine if all network paths from all senders to all receivers + support ECN. Accordingly, we allow ECN to be used by an RTP + sender using multicast UDP provided the sender has verified that + the paths to all its known receivers support ECN, irrespective of + whether the paths from other senders to their receivers support + ECN ("all its known receivers" are all the synchronisation sources + (SSRCs) from which the RTP sender has received RTP or RTCP in the + last five reporting intervals, i.e., they have not timed out). + Note that group membership may change during the lifetime of a + multicast RTP session, potentially introducing new receivers that + are not ECN capable or have a path that doesn't support ECN. + Senders must use the mechanisms described in Section 7.4 to check + that all receivers, and the network paths traversed to reach those + receivers, continue to support ECN, and they need to fallback to + non-ECN use if any receivers join that do not. + + SSM groups that use unicast RTCP feedback [RFC5760] do need a few + extra considerations. This topology can have multiple media + senders that provide traffic to the distribution source (DS) and + are separated from the DS. There can also be multiple feedback + targets. The requirement for using ECN for RTP in this topology + is that the media sender must be provided the feedback from the + receivers. It may be in aggregated form from the feedback + targets. We will not mention this SSM use case in the below text + + + +Westerlund, et al. Standards Track [Page 9] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + specifically, but when actions are required by the media source, + they also apply to the case of SSM where the RTCP feedback goes to + the feedback target. + + The mechanisms defined in this memo support multicast groups but + are known to be conservative and don't scale to large groups. + This is primarily because we require all members of the group to + demonstrate that they can make use of ECN before the sender is + allowed to send ECN-marked packets, since allowing some non-ECN- + capable receivers causes fairness issues when the bottleneck link + is shared by ECN and non-ECN flows that we have not (yet) been + able to satisfactorily address. The rules regarding Determination + of ECN Support in Section 7.2.1 may be relaxed in a future version + of this specification to improve scaling once these issues have + been resolved. + + Topo-Translator: An RTP translator is an RTP-level middlebox that is + invisible to the other participants in the RTP session (although + it is usually visible in the associated signalling session). + There are two types of RTP translators: those that do not modify + the media stream and are concerned with transport parameters, for + example, a multicast to unicast gateway; and those that do modify + the media stream, for example, transcoding between different media + codecs. A single RTP session traverses the translator, and the + translator must rewrite RTCP messages passing through it to match + the changes it makes to the RTP data packets. A legacy, ECN- + unaware, RTP translator is expected to ignore the ECN bits on + received packets and to set the ECN bits to not-ECT when sending + packets, thus causing ECN negotiation on the path containing the + translator to fail (any new RTP translator that does not wish to + support ECN may do so similarly). An ECN-aware RTP translator may + act in one of three ways: + + * If the translator does not modify the media stream, it should + copy the ECN bits unchanged from the incoming to the outgoing + datagrams, unless it is overloaded and experiencing congestion, + in which case it may mark the outgoing datagrams with an ECN-CE + mark. Such a translator passes RTCP feedback unchanged. See + Section 8.1. + + * If the translator modifies the media stream to combine or split + RTP packets but does not otherwise transcode the media, it must + manage the ECN bits in a way analogous to that described in + Section 5.3 of [RFC3168]. See Section 8.2 for details. + + * If the translator is a media transcoder, or otherwise modifies + the content of the media stream, the output RTP media stream + may have radically different characteristics than the input RTP + + + +Westerlund, et al. Standards Track [Page 10] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + media stream. Each side of the translator must then be + considered as a separate transport connection, with its own ECN + processing. This requires the translator to interpose itself + into the ECN negotiation process, effectively splitting the + connection into two parts with their own negotiation. Once + negotiation has been completed, the translator must generate + RTCP ECN feedback back to the source based on its own reception + and must respond to RTCP ECN feedback received from the + receiver(s) (see Section 8.3). + + It is recognised that ECN and RTCP processing in an RTP translator + that modifies the media stream is non-trivial. + + Topo-Mixer: A mixer is an RTP-level middlebox that aggregates + multiple RTP streams, mixing them together to generate a new RTP + stream. The mixer is visible to the other participants in the RTP + session and is also usually visible in the associated signalling + session. The RTP flows on each side of the mixer are treated + independently for ECN purposes, with the mixer generating its own + RTCP ECN feedback and responding to ECN feedback for data it + sends. Since unicast transport between the mixer and any endpoint + are treated independently, it would seem reasonable to allow the + transport on one side of the mixer to use ECN, while the transport + on the other side of the mixer is not ECN capable, if this is + desired. See Section 8.4 for details on how mixers should process + ECN. + + Topo-Video-switch-MCU: A video-switching Multipoint Control Unit + (MCU) receives several RTP flows, but forwards only one of those + flows onwards to the other participants at a time. The flow that + is forwarded changes during the session, often based on voice + activity. Since only a subset of the RTP packets generated by a + sender are forwarded to the receivers, a video-switching MCU can + break ECN negotiation (the success of the ECN negotiation may + depend on the voice activity of the participant at the instant the + negotiation takes place - shout if you want ECN). It also breaks + congestion feedback and response, since RTP packets are dropped by + the MCU depending on voice activity rather than network + congestion. This topology is widely used in legacy products but + is NOT RECOMMENDED for new implementations and SHALL NOT be used + with ECN. + + Topo-RTCP-terminating-MCU: In this scenario, each participant runs + an RTP point-to-point session between itself and the MCU. Each of + these sessions is treated independently for the purposes of ECN + and RTCP feedback, potentially with some using ECN and some not. + + + + + +Westerlund, et al. Standards Track [Page 11] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + Topo-Asymmetric: It is theoretically possible to build a middlebox + that is a combination of an RTP mixer in one direction and an RTP + translator in the other. To quote [RFC5117], "This topology is so + problematic and it is so easy to get the RTCP processing wrong, + that it is NOT RECOMMENDED to implement this topology". + + These topologies may be combined within a single RTP session. + + The ECN mechanism defined in this memo is applicable to both sender- + and receiver-controlled congestion algorithms. The mechanism ensures + that both senders and receivers will know about ECN-CE markings and + any packet losses. Thus, the actual decision point for the + congestion control is not relevant. This is a great benefit as the + rate of an RTP session can be varied in a number of ways, for + example, a unicast media sender might use TCP Friendly Rate Control + (TFRC) [RFC5348] or some other algorithm, while a multicast session + could use a sender-based scheme adapting to the lowest common + supported rate or a receiver-driven mechanism using layered coding to + support more heterogeneous paths. + + To ensure timely feedback of ECN-CE-marked packets when needed, this + mechanism requires support for the RTP/AVPF profile [RFC4585] or any + of its derivatives, such as RTP/SAVPF [RFC5124]. The standard RTP/ + AVP profile [RFC3551] does not allow any early or immediate + transmission of RTCP feedback and has a minimal RTCP interval whose + default value (5 seconds) is many times the normal RTT between sender + and receiver. + +3.3. Interoperability + + To ensure interoperability for this specification, there is need for + at least one common initialisation method for all implementations. + Since initialisation using RTP and RTCP (Section 7.2.1) is the one + method that works in all cases, although it is not optimal for all + uses, it is selected as the mandatory-to-implement initialisation + method. This method requires both the RTCP XR extension and the ECN + feedback format, which require the RTP/AVPF profile to ensure timely + feedback. + + When one considers all the uses of ECN for RTP, it is clear that + congestion control mechanisms exist that are receiver driven only + (Section 7.3.3). These congestion control mechanisms do not require + timely feedback of congestion events to the sender. If such a + congestion control mechanism is combined with an initialisation + method that also doesn't require timely feedback using RTCP, like the + leap-of-faith method (Section 7.2.3) or the ICE-based method + (Section 7.2.2), then neither the ECN feedback format nor the RTP/ + AVPF profile would appear to be needed. However, fault detection can + + + +Westerlund, et al. Standards Track [Page 12] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + be greatly improved by using receiver-side detection (Section 7.4.1) + and early reporting of such cases using the ECN feedback mechanism. + + For interoperability, we mandate the implementation of the RTP/AVPF + profile, with both RTCP extensions and the necessary signalling to + support a common operations mode. This specification recommends the + use of RTP/AVPF in all cases as negotiation of the common + interoperability point requires RTP/AVPF, mixed negotiation of RTP/ + AVP and RTP/AVPF depending on other SDP attributes in the same media + block is difficult, and the fact that fault detection can be improved + when using RTP/AVPF. + + The use of the ECN feedback format is also recommended, but cases + exist where its use is not required because timely feedback is not + needed. These will be explicitly noted using the phrase "no timely + feedback required" and generally occur in combination with receiver- + driven congestion control and with the leap-of-faith and ICE-based + initialisation methods. We also note that any receiver-driven + congestion control solution that still requires RTCP for signalling + of any adaptation information to the sender will still require RTP/ + AVPF for timeliness. + +4. Overview of Use of ECN with RTP/UDP/IP + + The solution for using ECN with RTP over UDP/IP consists of four + different pieces that together make the solution work: + + 1. Negotiation of the capability to use ECN with RTP/UDP/IP + + 2. Initiation and initial verification of ECN-capable transport + + 3. Ongoing use of ECN within an RTP session + + 4. Handling of dynamic behaviour through failure detection, + verification, and fallback + + Before an RTP session can be created, a signalling protocol is used + to negotiate or at least configure session parameters (see + Section 7.1). In some topologies, the signalling protocol can also + be used to discover the other participants. One of the parameters + that must be agreed is the capability of a participant to support + ECN. Note that all participants having the capability of supporting + ECN does not necessarily imply that ECN is usable in an RTP session, + since there may be middleboxes on the path between the participants + that don't pass ECN-marked packets (for example, a firewall that + blocks traffic with the ECN bits set). This document defines the + information that needs to be negotiated and provides a mapping to SDP + for use in both declarative and offer/answer contexts. + + + +Westerlund, et al. Standards Track [Page 13] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + When a sender joins a session for which all participants claim to + support ECN, it needs to verify that the ECN support is usable. + There are three ways in which this verification can be done: + + o The sender may generate a (small) subset of its RTP data packets + with the ECN field of the IP header set to ECT(0) or ECT(1). Each + receiver will then send an RTCP feedback packet indicating the + reception of the ECT-marked RTP packets. Upon reception of this + feedback from each receiver it knows of, the sender can consider + ECN functional for its traffic. Each sender does this + verification independently. When a new receiver joins an existing + RTP session, it will send RTCP reports in the usual manner. If + those RTCP reports include ECN information, verification will have + succeeded, and sources can continue to send ECT packets. If not, + verification fails, and each sender MUST stop using ECN (see + Section 7.2.1 for details). + + o Alternatively, ECN support can be verified during an initial end- + to-end STUN exchange (for example, as part of ICE connection + establishment). After having verified connectivity without ECN + capability, an extra STUN exchange, this time with the ECN field + set to ECT(0) or ECT(1), is performed on the candidate path that + is about to be used. If successful, the path's capability to + convey ECN-marked packets is verified. A new STUN attribute is + defined to convey feedback that the ECT-marked STUN request was + received (see Section 7.2.2), along with an ICE signalling option + (Section 6.4) to indicate that the check is to be performed. + + o Thirdly, the sender may make a leap of faith that ECN will work. + This is only recommended for applications that know they are + running in controlled environments where ECN functionality has + been verified through other means. In this mode, it is assumed + that ECN works, and the system reacts to failure indicators if the + assumption proved wrong. The use of this method relies on a high + confidence that ECN operation will be successful or an application + where failure is not serious. The impact on the network and other + users must be considered when making a leap of faith, so there are + limitations on when this method is allowed (see Section 7.2.3). + + The first mechanism, using RTP with RTCP feedback, has the advantage + of working for all RTP sessions, but the disadvantages of potential + clipping if ECN-marked RTP packets are discarded by middleboxes and + slow verification of ECN support. The STUN-based mechanism is faster + to verify ECN support but only works in those scenarios supported by + end-to-end STUN, such as within an ICE exchange. The third one, leap + of faith, has the advantage of avoiding additional tests or + complexities and enabling ECN usage from the first media packet. The + downside is that if the end-to-end path contains middleboxes that do + + + +Westerlund, et al. Standards Track [Page 14] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + not pass ECN, the impact on the application can be severe: in the + worst case, all media could be lost if a middlebox that discards ECN- + marked packets is present. A less severe effect, but still requiring + reaction, is the presence of a middlebox that re-marks ECT-marked + packets to not-ECT, possibly marking packets with an ECN-CE mark as + not-ECT. This could result in increased levels of congestion due to + non-responsiveness and impact media quality as applications end up + relying on packet loss as an indication of congestion. + + Once ECN support has been verified (or assumed) to work for all + receivers, a sender marks all its RTP packets as ECT packets, while + receivers rapidly feed back reports on any ECN-CE marks to the sender + using RTCP in RTP/AVPF immediate or early feedback mode, unless no + timely feedback is required. Each feedback report indicates the + receipt of new ECN-CE marks since the last ECN feedback packet and + also counts the total number of ECN-CE-marked packets as a cumulative + sum. This is the mechanism to provide the fastest possible feedback + to senders about ECN-CE marks. On receipt of an ECN-CE-marked + packet, the system must react to congestion as if packet loss has + been reported. Section 7.3 describes the ongoing use of ECN within + an RTP session. + + This rapid feedback is not optimised for reliability, so another + mechanism, RTCP XR ECN Summary Reports, is used to ensure more + reliable, but less timely, reporting of the ECN information. The ECN + Summary Report contains the same information as the ECN feedback + format, only packed differently for better efficiency with reports + for many sources. It is sent in a compound RTCP packet, along with + regular RTCP reception reports. By using cumulative counters for + observed ECN-CE, ECT, not-ECT, packet duplication, and packet loss, + the sender can determine what events have happened since the last + report, independently of any RTCP packets having been lost. + + RTCP reports MUST NOT be ECT marked, since ECT-marked traffic may be + dropped if the path is not ECN compliant. RTCP is used to provide + feedback about what has been transmitted and what ECN markings that + are received, so it is important that it is received in cases when + ECT-marked traffic is not getting through. + + There are numerous reasons why the path the RTP packets take from the + sender to the receiver may change, e.g., mobility and link failure + followed by re-routing around it. Such an event may result in the + packet being sent through a node that is ECN non-compliant, thus + re-marking or dropping packets with ECT set. To prevent this from + impacting the application for longer than necessary, the operation of + ECN is constantly monitored by all senders (Section 7.4). Both the + RTCP XR ECN Summary Reports and the ECN feedback packets allow the + sender to compare the number of ECT(0), ECT(1), and not-ECT-marked + + + +Westerlund, et al. Standards Track [Page 15] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + packets received with the number that were sent, while also reporting + ECN-CE-marked and lost packets. If these numbers do not agree, it + can be inferred that the path does not reliably pass ECN-marked + packets. A sender detecting a possible ECN non-compliance issue + should then stop sending ECT-marked packets to determine if that + allows the packets to be correctly delivered. If the issues can be + connected to ECN, then ECN usage is suspended. + +5. RTCP Extensions for ECN Feedback + + This memo defines two new RTCP extensions: one RTP/AVPF [RFC4585] + transport-layer feedback format for reporting urgent ECN information + and one RTCP XR [RFC3611] ECN Summary Report block type for regular + reporting of the ECN marking information. + +5.1. RTP/AVPF Transport-Layer ECN Feedback Packet + + This RTP/AVPF transport-layer feedback format is intended for use in + RTP/AVPF early or immediate feedback modes when information needs to + urgently reach the sender. Thus, its main use is to report reception + of an ECN-CE-marked RTP packet so that the sender may perform + congestion control or to speed up the initiation procedures by + rapidly reporting that the path can support ECN-marked traffic. The + feedback format is also defined with reduced-size RTCP [RFC5506] in + mind, where RTCP feedback packets may be sent without accompanying + Sender or Receiver Reports that would contain the extended highest + sequence number and the accumulated number of packet losses. Both + are important for ECN to verify functionality and keep track of when + CE marking does occur. + + The RTP/AVPF transport-layer feedback packet starts with the common + header defined by the RTP/AVPF profile [RFC4585], which is reproduced + in Figure 1. The FMT field takes the value 8 to indicate that the + Feedback Control Information (FCI) contains an ECN Feedback Report, + as defined in Figure 2. + + + + + + + + + + + + + + + + +Westerlund, et al. Standards Track [Page 16] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + |V=2|P| FMT=8 | PT=RTPFB=205 | length | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | SSRC of packet sender | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | SSRC of media source | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + : Feedback Control Information (FCI) : + : : + + Figure 1: RTP/AVPF Common Packet Format for Feedback Messages + + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Extended Highest Sequence Number | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | ECT (0) Counter | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | ECT (1) Counter | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | ECN-CE Counter | not-ECT Counter | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Lost Packets Counter | Duplication Counter | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 2: ECN Feedback Report Format + + The ECN Feedback Report contains the following fields: + + Extended Highest Sequence Number: The 32-bit extended highest + sequence number received, as defined by [RFC3550]. Indicates the + highest RTP sequence number to which this report relates. + + ECT(0) Counter: The 32-bit cumulative number of RTP packets with + ECT(0) received from this SSRC. + + ECT(1) Counter: The 32-bit cumulative number of RTP packets with + ECT(1) received from this SSRC. + + ECN-CE Counter: The cumulative number of RTP packets received from + this SSRC since the receiver joined the RTP session that were + ECN-CE marked, including ECN-CE marks in any duplicate packets. + The receiver should keep track of this value using a local + representation that is at least 32 bits and only include the 16 + + + +Westerlund, et al. Standards Track [Page 17] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + bits with least significance. In other words, the field will wrap + if more than 65535 ECN-CE-marked packets have been received. + + not-ECT Counter: The cumulative number of RTP packets received from + this SSRC since the receiver joined the RTP session that had an + ECN field value of not-ECT. The receiver should keep track of + this value using a local representation that is at least 32 bits + and only include the 16 bits with least significance. In other + words, the field will wrap if more than 65535 not-ECT packets have + been received. + + Lost Packets Counter: The cumulative number of RTP packets that the + receiver expected to receive minus the number of packets it + actually received that are not a duplicate of an already received + packet, from this SSRC since the receiver joined the RTP session. + Note that packets that arrive late are not counted as lost. The + receiver should keep track of this value using a local + representation that is at least 32 bits and only include the 16 + bits with least significance. In other words, the field will wrap + if more than 65535 packets are lost. + + Duplication Counter: The cumulative number of RTP packets received + that are a duplicate of an already received packet from this SSRC + since the receiver joined the RTP session. The receiver should + keep track of this value using a local representation that is at + least 32 bits and only include the 16 bits with least + significance. In other words, the field will wrap if more than + 65535 duplicate packets have been received. + + All fields in the ECN Feedback Report are unsigned integers in + network byte order. Each ECN Feedback Report corresponds to a single + RTP source (SSRC). Multiple sources can be reported by including + multiple ECN Feedback Report packets in an compound RTCP packet. + + The counters SHALL be initiated to 0 for each new SSRC received. + This enables detection of ECN-CE marks or packet loss on the initial + report from a specific participant. + + The use of at least 32-bit counters allows even extremely high packet + volume applications to not have wrapping of counters within any + timescale close to the RTCP reporting intervals. However, 32 bits + are not sufficiently large to disregard the fact that wrappings may + happen during the lifetime of a long-lived RTP session, and + implementations need to be written to handle wrapping of the + counters. It is recommended that implementations use local + representation of these counters that are longer than 32 bits to + enable easy handling of wraps. + + + + +Westerlund, et al. Standards Track [Page 18] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + There is a difference in packet duplication reports between the + packet loss counter that is defined in the Receiver Report Block + [RFC3550] and that defined here. To avoid holding state for what RTP + sequence numbers have been received, [RFC3550] specifies that one can + count packet loss by counting the number of received packets and + comparing that to the number of packets expected. As a result, a + packet duplication can hide a packet loss. However, when populating + the ECN Feedback Report, a receiver needs to track the sequence + numbers actually received and count duplicates and packet loss + separately to provide a more reliable indication. Reordering may, + however, still result in packet loss being reported in one report and + then removed in the next. + + The ECN-CE counter is robust for packet duplication. Adding each + received ECN-CE-marked packet to the counter is not an issue; in + fact, it is required to ensure complete tracking of the ECN state. + If one of the clones was ECN-CE marked, that is still an indication + of congestion. Packet duplication has a potential impact on the ECN + verification, and there is thus a need to count the duplicates. + +5.2. RTCP XR Report Block for ECN Summary Information + + This unilateral XR report block combined with RTCP SR or RR report + blocks carries the same information as the ECN Feedback Report and is + based on the same underlying information. However, the ECN Feedback + Report is intended to report an ECN-CE mark as soon as possible, + while this extended report is for the regular RTCP reporting and + continuous verification of the ECN functionality end-to-end. + + The ECN Summary Report block consists of one RTCP XR report block + header, shown in Figure 3 followed by one or more ECN Summary Report + data blocks, as defined in Figure 4. + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | BT=13 | Reserved | Block Length | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 3: RTCP XR Report Header + + + + + + + + + + + +Westerlund, et al. Standards Track [Page 19] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | SSRC of Media Sender | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | ECT (0) Counter | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | ECT (1) Counter | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | ECN-CE Counter | not-ECT Counter | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Lost Packets Counter | Duplication Counter | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 4: RTCP XR ECN Summary Report + + The RTCP XR ECN Summary Report contains the following fields: + + BT: Block Type identifying the ECN Summary Report block. Value is + 13. + + Reserved: All bits SHALL be set to 0 on transmission and ignored on + reception. + + Block Length: The length of this XR report block, including the + header, in 32-bit words minus one. Used to indicate the number of + ECN Summary Report data blocks present in the ECN Summary Report. + This length will be 5*n, where n is the number of ECN Summary + Report blocks, since blocks are a fixed size. The block length + MAY be zero if there is nothing to report. Receivers MUST discard + reports where the block length is not a multiple of five, since + these cannot be valid. + + SSRC of Media Sender: The SSRC identifying the media sender this + report is for. + + ECT(0) Counter: as in Section 5.1. + + ECT(1) Counter: as in Section 5.1. + + ECN-CE Counter: as in Section 5.1. + + not-ECT Counter: as in Section 5.1. + + Lost Packets Counter: as in Section 5.1. + + Duplication Counter: as in Section 5.1. + + + + +Westerlund, et al. Standards Track [Page 20] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + The extended highest sequence number counter for each SSRC is not + present in an RTCP XR report, in contrast to the feedback version. + The reason is that this summary report will rely on the information + sent in the Sender Report (SR) or Receiver Report (RR) blocks part of + the same RTCP compound packet. The extended highest sequence number + is available from the SR or RR. + + All the SSRCs that are present in the SR or RR SHOULD also be + included in the RTCP XR ECN Summary Report. In cases where the + number of senders are so large that the combination of SR/RR and the + ECN summary for all the senders exceed the MTU, then only a subset of + the senders SHOULD be included so that the reports for the subset + fits within the MTU. The subsets SHOULD be selected round-robin + across multiple intervals so that all sources are periodically + reported. In case there are no SSRCs that currently are counted as + senders in the session, the report block SHALL still be sent with no + report block entry and a zero report block length to continuously + indicate to the other participants the receiver capability to report + ECN information. + +6. SDP Signalling Extensions for ECN + + This section defines a number of SDP signalling extensions used in + the negotiation of the ECN for RTP support when using SDP. This + includes one SDP attribute "a=ecn-capable-rtp:" that negotiates the + actual operation of ECN for RTP. Two SDP signalling parameters are + defined to indicate the use of the RTCP XR ECN summary block and the + RTP/AVPF feedback format for ECN. One ICE option SDP representation + is also defined. + +6.1. Signalling ECN Capability Using SDP + + One new SDP attribute, "a=ecn-capable-rtp:", is defined. This is a + media-level attribute and MUST NOT be used at the session level. It + is not subject to the character set chosen. The aim of this + signalling is to indicate the capability of the sender and receivers + to support ECN, and to negotiate the method of ECN initiation to be + used in the session. The attribute takes a list of initiation + methods, ordered in decreasing preference. The defined values for + the initiation method are: + + rtp: Using RTP and RTCP as defined in Section 7.2.1. + + ice: Using STUN within ICE as defined in Section 7.2.2. + + leap: Using the leap-of-faith method as defined in Section 7.2.3. + + + + + +Westerlund, et al. Standards Track [Page 21] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + Further methods may be specified in the future, so unknown methods + MUST be ignored upon reception. + + In addition, a number of OPTIONAL parameters may be included in the + "a=ecn-capable-rtp:" attribute as follows: + + mode: This parameter signals the endpoint's capability to set and + read ECN marks in UDP packets. An examination of various + operating systems has shown that end-system support for ECN + marking of UDP packets may be symmetric or asymmetric. By this, + we mean that some systems may allow endpoints to set the ECN bits + in an outgoing UDP packet but not read them, while others may + allow applications to read the ECN bits but not set them. This + either/or case may produce an asymmetric support for ECN and thus + should be conveyed in the SDP signalling. The "mode=setread" + state is the ideal condition where an endpoint can both set and + read ECN bits in UDP packets. The "mode=setonly" state indicates + that an endpoint can set the ECT bit but cannot read the ECN bits + from received UDP packets to determine if upstream congestion + occurred. The "mode=readonly" state indicates that the endpoint + can read the ECN bits to determine if congestion has occurred for + incoming packets, but it cannot set the ECT bits in outgoing UDP + packets. When the "mode=" parameter is omitted, it is assumed + that the node has "setread" capabilities. This option can provide + for an early indication that ECN cannot be used in a session. + This would be the case when both the offerer and answerer set the + "mode=" parameter to "setonly" or both set it to "readonly". + + ect: This parameter makes it possible to express the preferred ECT + marking. This is either "random", "0", or "1", with "0" being + implied if not specified. The "ect" parameter describes a + receiver preference and is useful in the case where the receiver + knows it is behind a link using IP header compression, the + efficiency of which would be seriously disrupted if it were to + receive packets with randomly chosen ECT marks. It is RECOMMENDED + that ECT(0) marking be used. + + + + + + + + + + + + + + + +Westerlund, et al. Standards Track [Page 22] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + The ABNF [RFC5234] grammar for the "a=ecn-capable-rtp:" attribute is + shown in Figure 5. + + ecn-attribute = "a=ecn-capable-rtp:" SP init-list [SP parm-list] + init-list = init-value *("," init-value) + init-value = "rtp" / "ice" / "leap" / init-ext + init-ext = token + parm-list = parm-value *(";" SP parm-value) + parm-value = mode / ect / parm-ext + mode = "mode=" ("setonly" / "setread" / "readonly") + ect = "ect=" ("0" / "1" / "random") + parm-ext = parm-name "=" parm-value-ext + parm-name = token + parm-value-ext = token / quoted-string + quoted-string = ( DQUOTE *qdtext DQUOTE ) + qdtext = %x20-21 / %x23-5B / %x5D-7E / quoted-pair / UTF8-NONASCII + ; No DQUOTE and no "\" + quoted-pair = "\\" / ( "\" DQUOTE ) + UTF8-NONASCII = UTF8-1 / UTF8-2 / UTF8-3 / UTF8-4 + + ; external references: + ; token from RFC 4566 + ; SP and DQUOTE from RFC 5234 + ; UTF8-1, UTF8-2, UTF8-3, and UTF8-4 from RFC 3629 + + Figure 5: ABNF Grammar for the "a=ecn-capable-rtp:" Attribute + + Note the above quoted string construct has an escaping mechanism for + strings containing ". This uses \ (backslash) as an escaping + mechanism, i.e., a " is replaced by \" (backslash double quote) and + any \ (backslash) is replaced by \\ (backslash backslash) when put + into the double quotes as defined by the above syntax. The string in + a quoted string is UTF-8 [RFC3629]. + +6.1.1. Use of "a=ecn-capable-rtp:" with the Offer/Answer Model + + When SDP is used with the offer/answer model [RFC3264], the party + generating the SDP offer MUST insert an "a=ecn-capable-rtp:" + attribute into the media section of the SDP offer of each RTP session + for which it wishes to use ECN. The attribute includes one or more + ECN initiation methods in a comma-separated list in decreasing order + of preference, with any number of optional parameters following. The + answering party compares the list of initiation methods in the offer + with those it supports in order of preference. If there is a match + and if the receiver wishes to attempt to use ECN in the session, it + includes an "a=ecn-capable-rtp:" attribute containing its single + preferred choice of initiation method, and any optional parameters, + in the media sections of the answer. If there is no matching + + + +Westerlund, et al. Standards Track [Page 23] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + initiation method capability, or if the receiver does not wish to + attempt to use ECN in the session, it does not include an "a=ecn-- + capable-rtp:" attribute in its answer. If the attribute is removed + in the answer, then ECN MUST NOT be used in any direction for that + media flow. If there are initialisation methods that are unknown, + they MUST be ignored on reception and MUST NOT be included in an + answer. + + The endpoints' capability to set and read ECN marks, as expressed by + the optional "mode=" parameter, determines whether ECN support can be + negotiated for flows in one or both directions: + + o If the "mode=setonly" parameter is present in the "a=ecn-capable- + rtp:" attribute of the offer and the answering party is also + "mode=setonly", then there is no common ECN capability, and the + answer MUST NOT include the "a=ecn-capable-rtp:" attribute. + Otherwise, if the offer is "mode=setonly", then ECN may only be + initiated in the direction from the offering party to the + answering party. + + o If the "mode=readonly" parameter is present in the "a=ecn-capable- + rtp:" attribute of the offer and the answering party is + "mode=readonly", then there is no common ECN capability, and the + answer MUST NOT include the "a=ecn-capable-rtp:" attribute. + Otherwise, if the offer is "mode=readonly", then ECN may only be + initiated in the direction from the answering party to the + offering party. + + o If the "mode=setread" parameter is present in the "a=ecn-capable- + rtp:" attribute of the offer and the answering party is "setonly", + then ECN may only be initiated in the direction from the answering + party to the offering party. If the offering party is + "mode=setread" but the answering party is "mode=readonly", then + ECN may only be initiated in the direction from the offering party + to the answering party. If both offer and answer are + "mode=setread", then ECN may be initiated in both directions. + Note that "mode=setread" is implied by the absence of a "mode=" + parameter in the offer or the answer. + + o An offer that does not include a "mode=" parameter MUST be treated + as if a "mode=setread" parameter had been included. + + In an RTP session using multicast and ECN, participants that intend + to send RTP packets SHOULD support setting ECT marks in RTP packets + (i.e., should be "mode=setonly" or "mode=setread"). Participants + receiving data need the capability to read ECN marks on incoming + packets. It is important that receivers can read ECN marks + ("mode=readonly" or "mode=setread"), since otherwise no sender in the + + + +Westerlund, et al. Standards Track [Page 24] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + multicast session would be able to enable ECN. Accordingly, + receivers that are "mode=setonly" SHOULD NOT join multicast RTP + sessions that use ECN. If session participants that are not aware of + the ECN for RTP signalling are invited to a multicast session and + simply ignore the signalling attribute, the other party in the offer/ + answer exchange SHOULD terminate the SDP dialogue so that the + participant leaves the session. + + The "ect=" parameter in the "a=ecn-capable-rtp:" attribute is set + independently in the offer and the answer. Its value in the offer + indicates a preference for the sending behaviour of the answering + party, and its value in the answer indicates a sending preference for + the behaviour of the offering party. It will be the sender's choice + to honour the receiver's preference for what to receive or not. In + multicast sessions, all senders SHOULD set the ECT marks using the + value declared in the "ect=" parameter. + + Unknown optional parameters MUST be ignored on reception and MUST NOT + be included in the answer. That way, a new parameter may be + introduced and verified as supported by the other endpoint by having + the endpoint include it in any answer. + +6.1.2. Use of "a=ecn-capable-rtp:" with Declarative SDP + + When SDP is used in a declarative manner, for example, in a multicast + session using the Session Announcement Protocol (SAP) [RFC2974], + negotiation of session description parameters is not possible. The + "a=ecn-capable-rtp:" attribute MAY be added to the session + description to indicate that the sender will use ECN in the RTP + session. The attribute MUST include a single method of initiation. + Participants MUST NOT join such a session unless they have the + capability to receive ECN-marked UDP packets, implement the method of + initiation, and generate RTCP ECN feedback. The mode parameter MAY + also be included in declarative usage, to indicate the minimal + capability is required by the consumer of the SDP. So, for example, + in an SSM session, the participants configured with a particular SDP + will all be in a media receive-only mode; thus, "mode=readonly" may + be used as the receiver only needs to be able to report on the ECN + markings. In ASM sessions, using "mode=readonly" is also reasonable, + unless all senders are required to attempt to use ECN for their + outgoing RTP data traffic, in which case the mode needs to be set to + "setread". + +6.1.3. General Use of the "a=ecn-capable-rtp:" Attribute + + The "a=ecn-capable-rtp:" attribute MAY be used with RTP media + sessions using UDP/IP transport. It MUST NOT be used for RTP + sessions using TCP, SCTP, or DCCP transport or for non-RTP sessions. + + + +Westerlund, et al. Standards Track [Page 25] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + As described in Section 7.3.3, RTP sessions using ECN require rapid + RTCP ECN feedback, unless timely feedback is not required due to a + receiver-driven congestion control. To ensure that the sender can + react to ECN-CE-marked packets, timely feedback is usually required. + Thus, the use of the Extended RTP Profile for RTCP-Based Feedback + (RTP/AVPF) [RFC4585] or another profile that inherits RTP/AVPF's + signalling rules MUST be signalled unless timely feedback is not + required. If timely feedback is not required, it is still + RECOMMENDED to use RTP/AVPF. The signalling of an RTP/AVPF-based + profile is likely to be required even if the preferred method of + initialisation and the congestion control do not require timely + feedback, as the common interoperable method is likely to be + signalled or the improved fault reaction is desired. + +6.2. RTCP ECN Feedback SDP Parameter + + A new "nack" feedback parameter "ecn" is defined to indicate the + usage of the RTCP ECN feedback packet format (Section 5.1). The ABNF + [RFC5234] definition of the SDP parameter extension is: + + rtcp-fb-nack-param = + rtcp-fb-nack-param =/ ecn-fb-par + ecn-fb-par = SP "ecn" + + The offer/answer rules for these SDP feedback parameters are + specified in the RTP/AVPF profile [RFC4585]. + +6.3. XR Block ECN SDP Parameter + + A new unilateral RTCP XR block for ECN summary information is + specified; thus, the XR block SDP signalling also needs to be + extended with a parameter. This is done in the same way as for the + other XR blocks. The XR block SDP attribute as defined in Section + 5.1 of the RTCP XR specification [RFC3611] is defined to be + extensible. As no parameter values are needed for this ECN summary + block, this parameter extension consists of a simple parameter name + used to indicate support and intent to use the XR block. + + xr-format = + xr-format =/ ecn-summary-par + ecn-summary-par = "ecn-sum" + + For SDP declarative and offer/answer usage, see the RTCP XR + specification [RFC3611] and its description of how to handle + unilateral parameters. + + + + + + +Westerlund, et al. Standards Track [Page 26] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +6.4. ICE Parameter to Signal ECN Capability + + One new ICE [RFC5245] option, "rtp+ecn", is defined. This is used + with the SDP session level "a=ice-options" attribute in an SDP offer + to indicate that the initiator of the ICE exchange has the capability + to support ECN for RTP-over-UDP flows (via "a=ice-options: rtp+ecn"). + The answering party includes this same attribute at the session level + in the SDP answer if it also has the capability and removes the + attribute if it does not wish to use ECN or doesn't have the + capability to use ECN. If the ICE initiation method (Section 7.2.2) + is actually going to be used, it is also needs to be explicitly + negotiated using the "a=ecn-capable-rtp:" attribute. This ICE option + SHALL be included when the ICE initiation method is offered or + declared in the SDP. + + Note: This signalling mechanism is not strictly needed as long as + the STUN ECN testing capability is used within the context of this + document. It may, however, be useful if the ECN verification + capability is used in additional contexts. + +7. Use of ECN with RTP/UDP/IP + + In the detailed specification of the behaviour below, the different + functions in the general case will first be discussed. In case + special considerations are needed for middleboxes, multicast usage, + etc., those will be specially discussed in related subsections. + +7.1. Negotiation of ECN Capability + + The first stage of ECN negotiation for RTP over UDP is to signal the + capability to use ECN. An RTP system that supports ECN and uses SDP + for its signalling MUST implement the SDP extension to signal ECN + capability as described in Section 6.1, the RTCP ECN feedback SDP + parameter defined in Section 6.2, and the XR Block ECN SDP parameter + defined in Section 6.3. It MAY also implement alternative ECN + capability negotiation schemes, such as the ICE extension described + in Section 6.4. Other signalling systems will need to define + signalling parameters corresponding to those defined for SDP. + + The "ecn-capable-rtp:" SDP attribute MUST be used when employing ECN + for RTP according to this specification in systems using SDP. As the + RTCP XR ECN Summary Report is required independently of the + initialisation method or congestion control scheme, the "rtcp-xr" + attribute with the "ecn-sum" parameter MUST also be used. The + "rtcp-fb" attribute with the "nack" parameter "ecn" MUST be used + whenever the initialisation method or a congestion control algorithm + + + + + +Westerlund, et al. Standards Track [Page 27] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + requires timely sender-side knowledge of received CE markings. If + the congestion control scheme requires additional signalling, this + should be indicated as appropriate. + +7.2. Initiation of ECN Use in an RTP Session + + Once the sender and the receiver(s) have agreed that they have the + capability to use ECN within a session, they may attempt to initiate + ECN use. All session participants connected over the same transport + MUST use the same initiation method. RTP mixers or translators can + use different initiation methods to different participants that are + connected over different underlying transports. The mixer or + translator will need to do individual signalling with each + participant to ensure it is consistent with the ECN support in those + cases where it does not function as one endpoint for the ECN control + loop. + + At the start of the RTP session, when the first few packets with ECT + are sent, it is important to verify that IP packets with ECN field + values of ECT or ECN-CE will reach their destination(s). There is + some risk that the use of ECN will result in either reset of the ECN + field or loss of all packets with ECT or ECN-CE markings. If the + path between the sender and the receivers exhibits either of these + behaviours, the sender needs to stop using ECN immediately to protect + both the network and the application. + + The RTP senders and receivers SHALL NOT ECT mark their RTCP traffic + at any time. This is to ensure that packet loss due to ECN marking + will not effect the RTCP traffic and the necessary feedback + information it carries. + + An RTP system that supports ECN MUST implement the initiation of ECN + using in-band RTP and RTCP described in Section 7.2.1. It MAY also + implement other mechanisms to initiate ECN support, for example, the + STUN-based mechanism described in Section 7.2.2, or use the leap-of- + faith option if the session supports the limitations provided in + Section 7.2.3. If support for both in-band and out-of-band + mechanisms is signalled, the sender when negotiating SHOULD offer + detection of ECT using STUN with ICE with higher priority than + detection of ECT using RTP and RTCP. + + No matter how ECN usage is initiated, the sender MUST continually + monitor the ability of the network, and all its receivers, to support + ECN, following the mechanisms described in Section 7.4. This is + necessary because path changes or changes in the receiver population + may invalidate the ability of the system to use ECN. + + + + + +Westerlund, et al. Standards Track [Page 28] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +7.2.1. Detection of ECT Using RTP and RTCP + + The ECN initiation phase using RTP and RTCP to detect if the network + path supports ECN comprises three stages. First, the RTP sender + generates some small fraction of its traffic with ECT marks to act as + a probe for ECN support. Then, on receipt of these ECT-marked + packets, the receivers send RTCP ECN feedback packets and RTCP ECN + Summary Reports to inform the sender that their path supports ECN. + Finally, the RTP sender makes the decision to use ECN or not, based + on whether the paths to all RTP receivers have been verified to + support ECN. + + Generating ECN Probe Packets: During the ECN initiation phase, an + RTP sender SHALL mark a small fraction of its RTP traffic as ECT, + while leaving the reminder of the packets unmarked. The main + reason for only marking some packets is to maintain usable media + delivery during the ECN initiation phase in those cases where ECN + is not supported by the network path. A secondary reason to send + some not-ECT packets is to ensure that the receivers will send + RTCP reports on this sender, even if all ECT-marked packets are + lost in transit. The not-ECT packets also provide a baseline to + compare performance parameters against. Another reason for only + probing with a small number of packets is to reduce the risk that + significant numbers of congestion markings might be lost if ECT is + cleared to not-ECT by an ECN-reverting Middlebox. Then, any + resulting lack of congestion response is likely to have little + damaging effect on others. An RTP sender is RECOMMENDED to send a + minimum of two packets with ECT markings per RTCP reporting + interval. In case a random ECT pattern is intended to be used, at + least one packet with ECT(0) and one with ECT(1) should be sent + per reporting interval; in case a single ECT marking is to be + used, only that ECT value SHOULD be sent. The RTP sender SHALL + continue to send some ECT-marked traffic as long as the ECN + initiation phase continues. The sender SHOULD NOT mark all RTP + packets as ECT during the ECN initiation phase. + + This memo does not mandate which RTP packets are marked with ECT + during the ECN initiation phase. An implementation should insert + ECT marks in RTP packets in a way that minimises the impact on + media quality if those packets are lost. The choice of packets to + mark is very media dependent. For audio formats, it would make + sense for the sender to mark comfort noise packets or similar. + For video formats, packets containing P- or B-frames (rather than + I-frames) would be an appropriate choice. No matter which RTP + packets are marked, those packets MUST NOT be sent in duplicate, + with and without ECT, since the RTP sequence number is used to + identify packets that are received with ECN markings. + + + + +Westerlund, et al. Standards Track [Page 29] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + Generating RTCP ECN Feedback: If ECN capability has been negotiated + in an RTP session, the receivers in the session MUST listen for + ECT or ECN-CE-marked RTP packets and generate RTCP ECN feedback + packets (Section 5.1) to mark their receipt. An immediate or + early (depending on the RTP/AVPF mode) ECN feedback packet SHOULD + be generated on receipt of the first ECT- or ECN-CE-marked packet + from a sender that has not previously sent any ECT traffic. Each + regular RTCP report MUST also contain an ECN Summary Report + (Section 5.2). Reception of subsequent ECN-CE-marked packets MUST + result in additional early or immediate ECN feedback packets being + sent unless no timely feedback is required. + + Determination of ECN Support: RTP is a group communication protocol, + where members can join and leave the group at any time. This + complicates the ECN initiation phase, since the sender must wait + until it believes the group membership has stabilised before it + can determine if the paths to all receivers support ECN (group + membership changes after the ECN initiation phase has completed + are discussed in Section 7.3). + + An RTP sender shall consider the group membership to be stable + after it has been in the session and sending ECT-marked probe + packets for at least three RTCP reporting intervals (i.e., after + sending its third regularly scheduled RTCP packet) and when a + complete RTCP reporting interval has passed without changes to the + group membership. ECN initiation is considered successful when + the group membership is stable and all known participants have + sent one or more RTCP ECN feedback packets or RTCP XR ECN Summary + Reports indicating correct receipt of the ECT-marked RTP packets + generated by the sender. + + As an optimisation, if an RTP sender is initiating ECN usage + towards a unicast address, then it MAY treat the ECN initiation as + provisionally successful if it receives an RTCP ECN Feedback + Report or an RTCP XR ECN Summary Report indicating successful + receipt of the ECT-marked packets, with no negative indications, + from a single RTP receiver (where a single RTP receiver is + considered as all SSRCs used by a single RTCP CNAME). After + declaring provisional success, the sender MAY generate ECT-marked + packets as described in Section 7.3, provided it continues to + monitor the RTCP reports for a period of three RTCP reporting + intervals from the time the ECN initiation started, to check if + there are any other participants in the session. Thus, as long as + any additional SSRC that report on the ECN usage are using the + same RTCP CNAME as the previous reports and they are all + indicating functional ECN, the sender may continue. If other + participants are detected, i.e., other RTCP CNAMEs, the sender + MUST fallback to only ECT-marking a small fraction of its RTP + + + +Westerlund, et al. Standards Track [Page 30] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + packets, while it determines if ECN can be supported following the + full procedure described above. Different RTCP CNAMEs received + over a unicast transport may occur when using translators in a + multi-party RTP session (e.g., when using a centralised conference + bridge). + + Note: The above optimisation supports peer-to-peer unicast + transport with several SSRCs multiplexed onto the same flow + (e.g., a single participant with two video cameras or SSRC + multiplexed RTP retransmission [RFC4588]). It is desirable to + be able to rapidly negotiate ECN support for such a session, + but the optimisation above can fail if there are + implementations that use the same CNAME for different parts of + a distributed implementation that have different transport + characteristics (e.g., if a single logical endpoint is split + across multiple hosts). + + ECN initiation is considered to have failed at the instant the + initiating RTP sender received an RTCP packet that doesn't contain + an RTCP ECN Feedback Report or ECN Summary Report from any RTP + session participant that has an RTCP RR with an extended RTP + sequence number field that indicates that it should have received + multiple (>3) ECT-marked RTP packets. This can be due to failure + to support the ECN feedback format by the receiver or some + middlebox or the loss of all ECT-marked packets. Both indicate a + lack of ECN support. + + If the ECN negotiation succeeds, this indicates that the path can + pass some ECN-marked traffic and that the receivers support ECN + feedback. This does not necessarily imply that the path can robustly + convey ECN feedback; Section 7.3 describes the ongoing monitoring + that must be performed to ensure the path continues to robustly + support ECN. + + When a sender or receiver detects ECN failures on paths, they should + log these to enable follow up and statistics gathering regarding + broken paths. The logging mechanism used is implementation + dependent. + +7.2.2. Detection of ECT Using STUN with ICE + + This section describes an OPTIONAL method that can be used to avoid + media impact and also ensure an ECN-capable path prior to media + transmission. This method is considered in the context where the + session participants are using ICE [RFC5245] to find working + connectivity. We need to use ICE rather than STUN only, as the + verification needs to happen from the media sender to the address and + port on which the receiver is listening. + + + +Westerlund, et al. Standards Track [Page 31] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + Note that this method is only applicable to sessions when the remote + destinations are unicast addresses. In addition, transport + translators that do not terminate the ECN control loop and may + distribute received packets to more than one other receiver must + either disallow this method (and use the RTP/RTCP method instead) or + implement additional handling as discussed below. This is because + the ICE initialisation method verifies the underlying transport to + one particular address and port. If the receiver at that address and + port intends to use the received packets in a multi-point session, + then the tested capabilities and the actual session behaviour are not + matched. + + To minimise the impact of setup delay, and to prioritise the fact + that one has working connectivity rather than necessarily finding the + best ECN-capable network path, this procedure is applied after having + performed a successful connectivity check for a candidate, which is + nominated for usage. At that point, an additional connectivity check + is performed, sending the "ECN-CHECK" attribute in a STUN packet that + is ECT marked. On reception of the packet, a STUN server supporting + this extension will note the received ECN field value and send a + STUN/UDP/IP packet in reply with the ECN field set to not-ECT and an + ECN-CHECK attribute included. A STUN server that doesn't understand + the extension, or is incapable of reading the ECN values on incoming + STUN packets, should follow the rule in the STUN specification for + unknown comprehension-optional attributes and ignore the attribute, + resulting in the sender receiving a STUN response without the ECN- + CHECK STUN attribute. + + The ECN STUN checks can be lost on the path, for example, due to the + ECT marking but also due to various other non ECN-related reasons + causing packet loss. The goal is to detect when the ECT markings are + rewritten or if it is the ECT marking that causes packet loss so that + the path can be determined as not-ECT. Other reasons for packet loss + should not result in a failure to verify the path as ECT. Therefore, + a number of retransmissions should be attempted. But, the sender of + ECN STUN checks will also have to set a criteria for when it gives up + testing for ECN capability on the path. Since the ICE agent has + successfully verified the path, an RTT measurement for this path can + be performed. To have a high probability of successfully verifying + the path, it is RECOMMENDED that the client retransmit the ECN STUN + check at least 4 times. The transmission for that flow is stopped + when an ECN-CHECK STUN response has been received, which doesn't + indicate a retransmission of the request due to a temporary error, or + the maximum number of retransmissions has been sent. The ICE agent + is recommended to give up on the ECN verification MAX(1.5*RTT, 20 ms) + after the last ECN STUN check was sent. + + + + + +Westerlund, et al. Standards Track [Page 32] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + The transmission of the ECT-marked STUN connectivity checks + containing the ECN-CHECK attribute can be done prior as well in + parallel to actual media transmission. Both cases are supported, + where the main difference is how aggressively the transmission of the + STUN checks are done. The reason for this is to avoid adding + additional startup delay until media can flow. If media is required + immediately after nomination has occurred, the STUN checks SHALL be + done in parallel. If the application does not require media + transmission immediately, the verification of ECT SHOULD start using + the aggressive mode. At any point in the process until ECT has been + verified or found to not work, media transmission MAY be started, and + the ICE agent SHALL transition from the aggressive mode to the + parallel mode. + + The aggressive mode uses an interval between the retransmissions + based on the Ta timer as defined in Section 16.1 for RTP Media + Streams in ICE [RFC5245]. The number of ECN STUN checks needing to + be sent will depend on the number of ECN-capable flows (N) that is to + be established. The interval between each transmission of an ECN- + CHECK packet MUST be Ta. In other words, for a given flow being + verified for ECT, the retransmission timeout (RTO) is set to Ta*N. + + The parallel mode uses transmission intervals in order to prevent the + ECT verification checks from increasing the total bitrate more than + 10%. As ICE's regular transmission schedule is mimicking a common + voice call in amount, to meet that goal for most media flows, setting + the retransmission interval to Ta*N*k where k=10 fulfills that goal. + Thus, the default behaviour SHALL be to use k=10 when in parallel + mode. In cases where the bitrate of the STUN connectivity checks can + be determined, they MAY be sent with smaller values of k, but k MUST + NOT be smaller than 1, as long as the total bitrate for the + connectivity checks are less than 10% of the used media bitrate. The + RTP media packets being sent in parallel mode SHALL NOT be ECT marked + prior to verification of the path as ECT. + + The STUN ECN-CHECK attribute contains one field and a flag, as shown + in Figure 6. The flag indicates whether the echo field contains a + valid value or not. The field is the ECN echo field and, when valid, + contains the two ECN bits from the packet it echoes back. The ECN- + CHECK attribute is a comprehension optional attribute. + + + + + + + + + + + +Westerlund, et al. Standards Track [Page 33] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + 0 1 2 3 + 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Type | Length | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Reserved |ECF|V| + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 6: ECN-CHECK STUN Attribute + + V: Valid (1 bit) ECN Echo value field is valid when set to 1 and + invalid when set 0. + + ECF: ECN Echo value field (2 bits) contains the ECN field value of + the STUN packet it echoes back when the field is valid. If + invalid, the content is arbitrary. + + Reserved: Reserved bits (29 bits) SHALL be set to 0 on transmission + and SHALL be ignored on reception. + + This attribute MAY be included in any STUN request to request the ECN + field to be echoed back. In STUN requests, the V bit SHALL be set to + 0. A compliant STUN server receiving a request with the ECN-CHECK + attribute SHALL read the ECN field value of the IP/UDP packet in + which the request was received. Upon forming the response, the + server SHALL include the ECN-CHECK attribute setting the V bit to + valid and include the read value of the ECN field into the ECF field. + If the STUN responder was unable to ascertain, due to temporary + errors, the ECN value of the STUN request, it SHALL set the V bit in + the response to 0. The STUN client may retry immediately. + + The ICE-based initialisation method does require some special + consideration when used by a translator. This is especially for + transport translators and translators that fragment or reassemble + packets, since they do not separate the ECN control loops between the + endpoints and the translator. When using ICE-based initiation, such + a translator must ensure that any participants joining an RTP session + for which ECN has been negotiated are successfully verified in the + direction from the translator to the joining participant. + Alternatively, it must correctly handle remarking of ECT RTP packets + towards that participant. When a new participant joins the session, + the translator will perform a check towards the new participant. If + that is successfully completed, the ECT properties of the session are + maintained for the other senders in the session. If the check fails, + then the existing senders will now see a participant that fails to + receive ECT. Thus, the failure detection in those senders will + eventually detect this. However, to avoid misusing the network on + the path from the translator to the new participant, the translator + + + +Westerlund, et al. Standards Track [Page 34] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + SHALL remark the traffic intended to be forwarded from ECT to not- + ECT. Any packets intended to be forwarded that are ECN-CE marked + SHALL be discarded and not sent. In cases where the path from a new + participant to the translator fails the ECT check, then only that + sender will not contribute any ECT-marked traffic towards the + translator. + +7.2.3. Leap-of-Faith ECT Initiation Method + + This method for initiating ECN usage is a leap of faith that assumes + that ECN will work on the used path(s). The method is to go directly + to "ongoing use of ECN" as defined in Section 7.3. Thus, all RTP + packets MAY be marked as ECT, and the failure detection MUST be used + to detect any case when the assumption that the path is ECT capable + is wrong. This method is only recommended for controlled + environments where the whole path(s) between sender and receiver(s) + has been built and verified to be ECT. + + If the sender marks all packets as ECT while transmitting on a path + that contains an ECN-blocking middlebox, then receivers downstream of + that middlebox will not receive any RTP data packets from the sender + and hence will not consider it to be an active RTP SSRC. The sender + can detect this and revert to sending packets without ECT marks, + since RTCP SR/RR packets from such receivers will either not include + a report for the sender's SSRC or will report that no packets have + been received, but this takes at least one RTCP reporting interval. + It should be noted that a receiver might generate its first RTCP + packet immediately on joining a unicast session, or very shortly + after joining an RTP/AVPF session, before it has had chance to + receive any data packets. A sender that receives an RTCP SR/RR + packet indicating lack of reception by a receiver SHOULD therefore + wait for a second RTCP report from that receiver to be sure that the + lack of reception is due to ECT-marking. Since this recovery process + can take several tens of seconds, during which time the RTP session + is unusable for media, it is NOT RECOMMENDED that the leap-of-faith + ECT initiation method be used in environments where ECN-blocking + middleboxes are likely to be present. + +7.3. Ongoing Use of ECN within an RTP Session + + Once ECN has been successfully initiated for an RTP sender, that + sender begins sending all RTP data packets as ECT-marked, and its + receivers send ECN feedback information via RTCP packets. This + section describes procedures for sending ECT-marked data, providing + ECN feedback information via RTCP, and responding to ECN feedback + information. + + + + + +Westerlund, et al. Standards Track [Page 35] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +7.3.1. Transmission of ECT-Marked RTP Packets + + After a sender has successfully initiated ECN use, it SHOULD mark all + the RTP data packets it sends as ECT. The sender SHOULD mark packets + as ECT(0) unless the receiver expresses a preference for ECT(1) or + for a random ECT value using the "ect" parameter in the "a=ecn-- + capable-rtp:" attribute. + + The sender SHALL NOT include ECT marks on outgoing RTCP packets and + SHOULD NOT include ECT marks on any other outgoing control messages + (e.g., STUN [RFC5389] packets, Datagram Transport Layer Security + (DTLS) [RFC6347] handshake packets, or ZRTP [RFC6189] control + packets) that are multiplexed on the same UDP port. For control + packets there might be exceptions, like the STUN-based ECN-CHECK + defined in Section 7.2.2. + +7.3.2. Reporting ECN Feedback via RTCP + + An RTP receiver that receives a packet with an ECN-CE mark, or that + detects a packet loss, MUST schedule the transmission of an RTCP ECN + feedback packet as soon as possible (subject to the constraints of + [RFC4585] and [RFC3550]) to report this back to the sender unless no + timely feedback is required. The feedback RTCP packet SHALL consist + of at least one ECN feedback packet (Section 5.1) reporting on the + packets received since the last ECN feedback packet and will contain + (at least) an RTCP SR/RR packet and an SDES packet, unless reduced- + size RTCP [RFC5506] is used. The RTP/AVPF profile in early or + immediate feedback mode SHOULD be used where possible, to reduce the + interval before feedback can be sent. To reduce the size of the + feedback message, reduced-size RTCP [RFC5506] MAY be used if + supported by the endpoints. Both RTP/AVPF and reduced-size RTCP MUST + be negotiated in the session setup signalling before they can be + used. + + Every time a regular compound RTCP packet is to be transmitted, an + ECN-capable RTP receiver MUST include an RTCP XR ECN Summary Report + as described in Section 5.2 as part of the compound packet. + + The multicast feedback implosion problem, which occurs when many + receivers simultaneously send feedback to a single sender, must be + considered. The RTP/AVPF transmission rules will limit the amount of + feedback that can be sent, avoiding the implosion problem but also + delaying feedback by varying degrees from nothing up to a full RTCP + reporting interval. As a result, the full extent of a congestion + situation may take some time to reach the sender, although some + feedback should arrive in a reasonably timely manner, allowing the + sender to react on a single or a few reports. + + + + +Westerlund, et al. Standards Track [Page 36] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +7.3.3. Response to Congestion Notifications + + The reception of RTP packets with ECN-CE marks in the IP header is a + notification that congestion is being experienced. The default + reaction on the reception of these ECN-CE-marked packets MUST be to + provide the congestion control algorithm with a congestion + notification that triggers the algorithm to react as if packet loss + had occurred. There should be no difference in congestion response + if ECN-CE marks or packet drops are detected. + + Other reactions to ECN-CE may be specified in the future, following + IETF Review. Detailed designs of such alternative reactions MUST be + specified in a Standards Track RFC and be reviewed to ensure they are + safe for deployment under any restrictions specified. A potential + example for an alternative reaction could be emergency communications + (such as that generated by first responders, as opposed to the + general public) in networks where the user has been authorised. A + more detailed description of these other reactions, as well as the + types of congestion control algorithms used by end-nodes, is outside + the scope of this document. + + Depending on the media format, type of session, and RTP topology + used, there are several different types of congestion control that + can be used: + + Sender-Driven Congestion Control: The sender is responsible for + adapting the transmitted bitrate in response to RTCP ECN feedback. + When the sender receives the ECN feedback data, it feeds this + information into its congestion control or bitrate adaptation + mechanism so that it can react as if packet loss was reported. + The congestion control algorithm to be used is not specified here, + although TFRC [RFC5348] is one example that might be used. + + Receiver-Driven Congestion Control: In a receiver-driven congestion + control mechanism, the receivers can react to the ECN-CE marks + themselves without providing ECN-CE feedback to the sender. This + may allow faster response than sender-driven congestion control in + some circumstances and also scale to large number of receivers and + multicast usage. One example of receiver-driven congestion + control is implemented by providing the content in a layered way, + with each layer providing improved media quality but also + increased bandwidth usage. The receiver locally monitors the + ECN-CE marks on received packets to check if it experiences + congestion with the current number of layers. If congestion is + experienced, the receiver drops one layer, thus reducing the + resource consumption on the path towards itself. For example, if + a layered media encoding scheme such as H.264 Scalable Video + Coding (SVC) is used, the receiver may change its layer + + + +Westerlund, et al. Standards Track [Page 37] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + subscription and so reduce the bitrate it receives. The receiver + MUST still send an RTCP XR ECN Summary to the sender, even if it + can adapt without contact with the sender, so that the sender can + determine if ECN is supported on the network path. The timeliness + of RTCP feedback is less of a concern with receiver-driven + congestion control, and regular RTCP reporting of ECN summary + information is sufficient (without using RTP/AVPF immediate or + early feedback). + + Hybrid: There might be mechanisms that utilise both some receiver + behaviours and some sender-side monitoring, thus requiring both + feedback of congestion events to the sender and taking receiver + decisions and possible signalling to the sender. In this case, + the congestion control algorithm needs to use the signalling to + indicate which features of ECN for RTP are required. + + Responding to congestion indication in the case of multicast traffic + is a more complex problem than for unicast traffic. The fundamental + problem is diverse paths, i.e., when different receivers don't see + the same path and thus have different bottlenecks, so the receivers + may get ECN-CE-marked packets due to congestion at different points + in the network. This is problematic for sender-driven congestion + control, since when receivers are heterogeneous in regards to + capacity, the sender is limited to transmitting at the rate the + slowest receiver can support. This often becomes a significant + limitation as group size grows. Also, as group size increases, the + frequency of reports from each receiver decreases, which further + reduces the responsiveness of the mechanism. Receiver-driven + congestion control has the advantage that each receiver can choose + the appropriate rate for its network path, rather than all receivers + having to settle for the lowest common rate. + + We note that ECN support is not a silver bullet to improving + performance. The use of ECN gives the chance to respond to + congestion before packets are dropped in the network, improving the + user experience by allowing the RTP application to control how the + quality is reduced. An application that ignores ECN Congestion + Experienced feedback is not immune to congestion: the network will + eventually begin to discard packets if traffic doesn't respond. To + avoid packet loss, it is in the best interest of an application to + respond to ECN congestion feedback promptly. + +7.4. Detecting Failures + + Senders and receivers can deliberately ignore ECN-CE and thus get a + benefit over behaving flows (cheating). The ECN nonce [RFC3540] is + an addition to TCP that attempts to solve this issue as long as the + sender acts on behalf of the network. The assumption that senders + + + +Westerlund, et al. Standards Track [Page 38] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + act on behalf of the network may be false due to the nature of peer- + to-peer use of RTP. Still, a significant portion of RTP senders are + infrastructure devices (for example, streaming media servers) that do + have an interest in protecting both service quality and the network. + Even though there may be cases where the nonce may be applicable for + RTP, it is not included in this specification. This is because a + receiver interested in cheating would simply claim to not support the + nonce, or even ECN itself. It is, however, worth mentioning that, as + real-time media is commonly sensitive to increased delay and packet + loss, it will be in the interest of both the media sender and + receivers to minimise the number and duration of any congestion + events as they will adversely affect media quality. + + RTP sessions can also suffer from path changes resulting in a non- + ECN-compliant node becoming part of the path. That node may perform + either of two actions that has an effect on the ECN and application + functionality. The gravest is if the node drops packets with the ECN + field set to ECT(0), ECT(1), or ECN-CE. This can be detected by the + receiver when it receives an RTCP SR packet indicating that a sender + has sent a number of packets that it has not received. The sender + may also detect such a middlebox based on the receiver's RTCP RR + packet, when the extended sequence number is not advanced due to the + failure to receive packets. If the packet loss is less than 100%, + then packet loss reporting in either the ECN feedback information or + RTCP RR will indicate the situation. The other action is to re-mark + a packet from ECT or ECN-CE to not-ECT. That has less dire results; + however, it should be detected so that ECN usage can be suspended to + prevent misusing the network. + + The RTCP XR ECN summary packet and the ECN feedback packet allow the + sender to compare the number of ECT-marked packets of different types + received with the number it actually sent. The number of ECT packets + received, plus the number of ECN-CE-marked and lost packets, should + correspond to the number of sent ECT-marked packets plus the number + of received duplicates. If these numbers don't agree, there are two + likely reasons: a translator changing the stream or not carrying the + ECN markings forward or some node re-marking the packets. In both + cases, the usage of ECN is broken on the path. By tracking all the + different possible ECN field values, a sender can quickly detect if + some non-compliant behaviour is happening on the path. + + Thus, packet losses and non-matching ECN field value statistics are + possible indications of issues with using ECN over the path. The + next section defines both sender and receiver reactions to these + cases. + + + + + + +Westerlund, et al. Standards Track [Page 39] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +7.4.1. Fallback Mechanisms + + Upon the detection of a potential failure, both the sender and the + receiver can react to mitigate the situation. + + A receiver that detects a packet loss burst MAY schedule an early + feedback packet that includes at least the RTCP RR and the ECN + feedback message to report this to the sender. This will speed up + the detection of the loss at the sender, thus triggering sender-side + mitigation. + + A sender that detects high packet loss rates for ECT-marked packets + SHOULD immediately switch to sending packets as not-ECT to determine + if the losses are potentially due to the ECT markings. If the losses + disappear when the ECT-marking is discontinued, the RTP sender should + go back to initiation procedures to attempt to verify the apparent + loss of ECN capability of the used path. If a re-initiation fails, + then two possible actions exist: + + 1. Periodically retry the ECN initiation to detect if a path change + occurs to a path that is ECN capable. + + 2. Renegotiate the session to disable ECN support. This is a choice + that is suitable if the impact of ECT probing on the media + quality is noticeable. If multiple initiations have been + successful, but the following full usage of ECN has resulted in + the fallback procedures, then disabling of the ECN support is + RECOMMENDED. + + We foresee the possibility of flapping ECN capability due to several + reasons: video-switching MCU or similar middleboxes that select to + deliver media from the sender only intermittently; load-balancing + devices that may in worst case result in some packets taking a + different network path than the others; mobility solutions that + switch the underlying network path in a transparent way for the + sender or receiver; and membership changes in a multicast group. It + is, however, appropriate to mention that there are also issues such + as re-routing of traffic due to a flappy route table or excessive + reordering and other issues that are not directly ECN related but + nevertheless may cause problems for ECN. + +7.4.2. Interpretation of ECN Summary Information + + This section contains discussion on how the ECN Summary Report + information can be used to detect various types of ECN path issues. + We first review the information the RTCP reports provide on a per- + source (SSRC) basis: + + + + +Westerlund, et al. Standards Track [Page 40] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + ECN-CE Counter: The number of RTP packets received so far in the + session with an ECN field set to CE. + + ECT (0/1) Counters: The number of RTP packets received so far in the + session with an ECN field set to ECT (0) and ECT (1) respectively. + + not-ECT Counter: The number of RTP packets received so far in the + session with an ECN field set to not-ECT. + + Lost Packets Counter: The number of RTP packets that where expected + based on sequence numbers but never received. + + Duplication Counter: The number of received RTP packets that are + duplicates of already received ones. + + Extended Highest Sequence number: The highest sequence number seen + when sending this report, but with additional bits, to handle + disambiguation when wrapping the RTP sequence number field. + + The counters will be initialised to zero to provide values for the + RTP stream sender from the first report. After the first report, the + changes between the last received report and the previous report are + determined by simply taking the values of the latest minus the + previous, taking wrapping into account. This definition is also + robust to packet losses, since if one report is missing, the + reporting interval becomes longer, but is otherwise equally valid. + + In a perfect world, the number of not-ECT packets received should be + equal to the number sent minus the Lost Packets Counter, and the sum + of the ECT(0), ECT(1), and ECN-CE counters should be equal to the + number of ECT-marked packet sent. Two issues may cause a mismatch in + these statistics: severe network congestion or unresponsive + congestion control might cause some ECT-marked packets to be lost, + and packet duplication might result in some packets being received + and counted in the statistics multiple times (potentially with a + different ECN-mark on each copy of the duplicate). + + The rate of packet duplication is tracked, allowing one to take the + duplication into account. The value of the ECN field for duplicates + will also be counted, and when comparing the figures, one needs to + take into account in the calculation that some fraction of packet + duplicates are not-ECT and some are ECT. Thus, when only sending + not-ECT, the number of sent packets plus reported duplicates equals + the number of received not-ECT. When sending only ECT, the number of + sent ECT packets plus duplicates will equal ECT(0), ECT(1), ECN-CE, + and packet loss. When sending a mix of not-ECT and ECT, there is an + uncertainty if any duplicate or packet loss was an not-ECT or ECT. + If the packet duplication is completely independent of the usage of + + + +Westerlund, et al. Standards Track [Page 41] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + ECN, then the fraction of packet duplicates should be in relation to + the number of not-ECT vs. ECT packets sent during the period of + comparison. This relation does not hold for packet loss, where + higher rates of packet loss for not-ECT is expected than for ECT + traffic. + + Detecting clearing of ECN field: If the ratio between ECT and not-ECT + transmitted in the reports has become all not-ECT, or has + substantially changed towards not-ECT, then this is clearly an + indication that the path results in clearing of the ECT field. + + Dropping of ECT packets: To determine if the packet-drop ratio is + different between not-ECT and ECT-marked transmission requires a mix + of transmitted traffic. The sender should compare if the delivery + percentage (delivered/transmitted) between ECT and not-ECT is + significantly different. Care must be taken if the number of packets + is low in either of the categories. One must also take into account + the level of CE marking. A CE-marked packet would have been dropped + unless it was ECT marked. Thus, the packet loss level for not-ECT + should be approximately equal to the loss rate for ECT when counting + the CE-marked packets as lost ones. A sender performing this + calculation needs to ensure that the difference is statistically + significant. + + If erroneous behaviour is detected, it should be logged to enable + follow up and statistics gathering. + +8. Processing ECN in RTP Translators and Mixers + + RTP translators and mixers that support ECN for RTP are required to + process and potentially modify or generate ECN marking in RTP + packets. They also need to process and potentially modify or + generate RTCP ECN feedback packets for the translated and/or mixed + streams. This includes both downstream RTCP reports generated by the + media sender and also reports generated by the receivers, flowing + upstream back towards the sender. + +8.1. Transport Translators + + Some translators only perform transport-level translations, such as + copying packets from one address domain, like from unicast to + multicast. They may also perform relaying like copying an incoming + packet to a number of unicast receivers. This section details the + ECN-related actions for RTP and RTCP. + + + + + + + +Westerlund, et al. Standards Track [Page 42] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + For RTP data packets, the translator, which does not modify the media + stream, SHOULD copy the ECN bits unchanged from the incoming to the + outgoing datagrams, unless the translator itself is overloaded and + experiencing congestion, in which case it may mark the outgoing + datagrams with an ECN-CE mark. + + A transport translator does not modify RTCP packets. However, it + MUST perform the corresponding transport translation of the RTCP + packets as it does with RTP packets being sent from the same source/ + endpoint. + +8.2. Fragmentation and Reassembly in Translators + + An RTP translator may fragment or reassemble RTP data packets without + changing the media encoding and without reference to the congestion + state of the networks it bridges. An example of this might be to + combine packets of a voice-over-IP stream coded with one 20 ms frame + per RTP packet into new RTP packets with two 20 ms frames per packet, + thereby reducing the header overhead and thus stream bandwidth, at + the expense of an increase in latency. If multiple data packets are + re-encoded into one, or vice versa, the RTP translator MUST assign + new sequence numbers to the outgoing packets. Losses in the incoming + RTP packet stream may also induce corresponding gaps in the outgoing + RTP sequence numbers. An RTP translator MUST rewrite RTCP packets to + make the corresponding changes to their sequence numbers and to + reflect the impact of the fragmentation or reassembly. This section + describes how that rewriting is to be done for RTCP ECN feedback + packets. Section 7.2 of [RFC3550] describes general procedures for + other RTCP packet types. + + The processing of arriving RTP packets for this case is as follows. + If an ECN-marked packet is split into two, then both the outgoing + packets MUST be ECN marked identically to the original; if several + ECN-marked packets are combined into one, the outgoing packet MUST be + either ECN-CE marked or dropped if any of the incoming packets are + ECN-CE marked. If the outgoing combined packet is not ECN-CE marked, + then it MUST be ECT marked if any of the incoming packets were ECT + marked. + + RTCP ECN feedback packets (Section 5.1) contain seven fields that are + rewritten in an RTP translator that fragments or reassembles packets: + the extended highest sequence number, the duplication counter, the + Lost Packets Counter, the ECN-CE counter, and not-ECT counter, the + ECT(0) counter, and the ECT(1) counter. The RTCP XR report block for + ECN summary information (Section 5.2) includes all of these fields + except the extended highest sequence number, which is present in the + + + + + +Westerlund, et al. Standards Track [Page 43] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + report block in an SR or RR packet. The procedures for rewriting + these fields are the same for both the RTCP ECN feedback packet and + the RTCP XR ECN summary packet. + + When receiving an RTCP ECN feedback packet for the translated stream, + an RTP translator first determines the range of packets to which the + report corresponds. The extended highest sequence number in the RTCP + ECN feedback packet (or in the RTCP SR/RR packet contained within the + compound packet, in the case of RTCP XR ECN Summary Reports) + specifies the end sequence number of the range. For the first RTCP + ECN feedback packet received, the initial extended sequence number of + the range may be determined by subtracting the sum of the Lost + Packets Counter, the ECN-CE counter, the not-ECT counter, the ECT(0) + counter and the ECT(1) counter minus the duplication counter, from + the extended highest sequence number. For subsequent RTCP ECN + feedback packets, the starting sequence number may be determined as + being one after the extended highest sequence number of the previous + RTCP ECN feedback packet received from the same SSRC. These values + are in the sequence number space of the translated packets. + + Based on its knowledge of the translation process, the translator + determines the sequence number range for the corresponding original, + pre-translation, packets. The extended highest sequence number in + the RTCP ECN feedback packet is rewritten to match the final sequence + number in the pre-translation sequence number range. + + The translator then determines the ratio, R, of the number of packets + in the translated sequence number space (numTrans) to the number of + packets in the pre-translation sequence number space (numOrig) such + that R = numTrans / numOrig. The counter values in the RTCP ECN + Feedback Report are then scaled by dividing each of them by R. For + example, if the translation process combines two RTP packets into + one, then numOrig will be twice numTrans, giving R=0.5, and the + counters in the translated RTCP ECN feedback packet will be twice + those in the original. + + The ratio, R, may have a value that leads to non-integer multiples of + the counters when translating the RTCP packet. For example, a Voice + over IP (VoIP) translator that combines two adjacent RTP packets into + one if they contain active speech data, but passes comfort noise + packets unchanged, would have an R value of between 0.5 and 1.0 + depending on the amount of active speech. Since the counter values + in the translated RTCP report are integer values, rounding will be + necessary in this case. + + When rounding counter values in the translated RTCP packet, the + translator should try to ensure that they sum to the number of RTP + packets in the pre-translation sequence number space (numOrig). The + + + +Westerlund, et al. Standards Track [Page 44] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + translator should also try to ensure that no non-zero counter is + rounded to a zero value, unless the pre-translated values are zero, + since that will lose information that a particular type of event has + occurred. It is recognised that it may be impossible to satisfy both + of these constraints; in such cases, it is better to ensure that no + non-zero counter is mapped to a zero value, since this preserves + congestion adaptation and helps the RTCP-based ECN initiation + process. + + One should be aware of the impact this type of translator has on the + measurement of packet duplication. A translator performing + aggregation and most likely also an fragmenting translator will + suppress any duplication happening prior to itself. Thus, the + reports and what is being scaled will only represent packet + duplication happening from the translator to the receiver reporting + on the flow. + + It should be noted that scaling the RTCP counter values in this way + is meaningful only on the assumption that the level of congestion in + the network is related to the number of packets being sent. This is + likely to be a reasonable assumption in the type of environment where + RTP translators that fragment or reassemble packets are deployed, as + their entire purpose is to change the number of packets being sent to + adapt to known limitations of the network, but is not necessarily + valid in general. + + The rewritten RTCP ECN Feedback Report is sent from the other side of + the translator to that from which it arrived (as part of a compound + RTCP packet containing other translated RTCP packets, where + appropriate). + +8.3. Generating RTCP ECN Feedback in Media Transcoders + + An RTP translator that acts as a media transcoder cannot directly + forward RTCP packets corresponding to the transcoded stream, since + those packets will relate to the non-transcoded stream and will not + be useful in relation to the transcoded RTP flow. Such a transcoder + will need to interpose itself into the RTCP flow, acting as a proxy + for the receiver to generate RTCP feedback in the direction of the + sender relating to the pre-transcoded stream and acting in place of + the sender to generate RTCP relating to the transcoded stream to be + sent towards the receiver. This section describes how this proxying + is to be done for RTCP ECN feedback packets. Section 7.2 of + [RFC3550] describes general procedures for other RTCP packet types. + + An RTP translator acting as a media transcoder in this manner does + not have its own SSRC and hence is not visible to other entities at + the RTP layer. RTCP ECN feedback packets and RTCP XR report blocks + + + +Westerlund, et al. Standards Track [Page 45] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + for ECN summary information that are received from downstream relate + to the translated stream and so must be processed by the translator + as if they were the original media source. These reports drive the + congestion control loop and media adaptation between the translator + and the downstream receiver. If there are multiple downstream + receivers, a logically separate transcoder instance must be used for + each receiver and must process RTCP ECN Feedback and Summary Reports + independently of the other transcoder instances. An RTP translator + acting as a media transcoder in this manner MUST NOT forward RTCP ECN + feedback packets or RTCP XR ECN Summary Reports from downstream + receivers in the upstream direction. + + An RTP translator acting as a media transcoder will generate RTCP + reports upstream towards the original media sender, based on the + reception quality of the original media stream at the translator. + The translator will run a separate congestion control loop and media + adaptation between itself and the media sender for each of its + downstream receivers and must generate RTCP ECN feedback packets and + RTCP XR ECN Summary Reports for that congestion control loop using + the SSRC of that downstream receiver. + +8.4. Generating RTCP ECN Feedback in Mixers + + An RTP mixer terminates one-or-more RTP flows, combines them into a + single outgoing media stream, and transmits that new stream as a + separate RTP flow. A mixer has its own SSRC and is visible to other + participants in the session at the RTP layer. + + An ECN-aware RTP mixer must generate RTCP ECN feedback packets and + RTCP XR report blocks for ECN summary information relating to the RTP + flows it terminates, in exactly the same way it would if it were an + RTP receiver. These reports form part of the congestion control loop + between the mixer and the media senders generating the streams it is + mixing. A separate control loop runs between each sender and the + mixer. + + An ECN-aware RTP mixer will negotiate and initiate the use of ECN on + the mixed RTP flows it generates and will accept and process RTCP ECN + Feedback Reports and RTCP XR report blocks for ECN relating to those + mixed flows as if it were a standard media sender. A congestion + control loop runs between the mixer and its receivers, driven in part + by the ECN reports received. + + An RTP mixer MUST NOT forward RTCP ECN feedback packets or RTCP XR + ECN Summary Reports from downstream receivers in the upstream + direction. + + + + + +Westerlund, et al. Standards Track [Page 46] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +9. Implementation Considerations + + To allow the use of ECN with RTP over UDP, an RTP implementation + desiring to support receiving ECN-controlled media streams must + support reading the value of the ECT bits on received UDP datagrams, + and an RTP implementation desiring to support sending ECN-controlled + media streams must support setting the ECT bits in outgoing UDP + datagrams. The standard Berkeley sockets API pre-dates the + specification of ECN and does not provide the functionality that is + required for this mechanism to be used with UDP flows, making this + specification difficult to implement portably. + +10. IANA Considerations + +10.1. SDP Attribute Registration + + Following the guidelines in [RFC4566], the IANA has registered one + new media-level SDP attribute: + + o Contact name, email address and telephone number: Authors of RFC + 6679 + + o Attribute-name: ecn-capable-rtp + + o Type of attribute: media-level + + o Subject to charset: no + + This attribute defines the ability to negotiate the use of ECT (ECN- + capable transport) for RTP flows running over UDP/IP. This attribute + is put in the SDP offer if the offering party wishes to receive an + ECT flow. The answering party then includes the attribute in the + answer if it wishes to receive an ECT flow. If the answerer does not + include the attribute, then ECT MUST be disabled in both directions. + +10.2. RTP/AVPF Transport-Layer Feedback Message + + The IANA has registered one new RTP/AVPF Transport-Layer Feedback + Message in the table of FMT values for RTPFB Payload Types [RFC4585] + as defined in Section 5.1: + + Name: RTCP-ECN-FB + Long name: RTCP ECN Feedback + Value: 8 + Reference: RFC 6679 + + + + + + +Westerlund, et al. Standards Track [Page 47] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +10.3. RTCP Feedback SDP Parameter + + The IANA has registered one new SDP "rtcp-fb" attribute "nack" + parameter "ecn" in the SDP ("ack" and "nack" Attribute Values) + registry. + + Value name: ecn + Long name: Explicit Congestion Notification + Usable with: nack + Reference: RFC 6679 + +10.4. RTCP XR Report Blocks + + The IANA has registered one new RTCP XR Block Type as defined in + Section 5.2: + + Block Type: 13 + Name: ECN Summary Report + Reference: RFC 6679 + +10.5. RTCP XR SDP Parameter + + The IANA has registered one new RTCP XR SDP Parameter "ecn-sum" in + the "RTCP XR SDP Parameters" registry. + + Parameter name XR block (block type and name) + -------------- ------------------------------------ + ecn-sum 13 ECN Summary Report + +10.6. STUN Attribute + + A new STUN [RFC5389] attribute in the comprehension-optional range + under IETF Review (0x8000-0xFFFF) has been assigned to the ECN-CHECK + STUN attribute (0x802D) defined in Section 7.2.2. The STUN attribute + registry can currently be found at: + http://www.iana.org/assignments/stun-parameters. + +10.7. ICE Option + + A new ICE option "rtp+ecn" has been registered in the "ICE Options" + registry created by [RFC6336]. + +11. Security Considerations + + The use of ECN with RTP over UDP as specified in this document has + the following known security issues that need to be considered. + + + + + +Westerlund, et al. Standards Track [Page 48] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + External threats to the RTP and RTCP traffic: + + Denial of Service affecting RTCP: An attacker that can modify the + traffic between the media sender and a receiver can achieve either + of two things: 1) report a lot of packets as being congestion + experience marked, thus forcing the sender into a congestion + response; or 2) ensure that the sender disables the usage of ECN + by reporting failures to receive ECN by changing the counter + fields. This can also be accomplished by injecting false RTCP + packets to the media sender. Reporting a lot of ECN-CE-marked + traffic is likely the more efficient denial-of-service tool as + that may likely force the application to use the lowest possible + bitrates. The prevention against an external threat is to + integrity protect the RTCP feedback information and authenticate + the sender. + + Information leakage: The ECN feedback mechanism exposes the + receiver's perceived packet loss and the packets it considers to + be ECN-CE marked. This is mostly not considered sensitive + information. If it is considered sensitive, the RTCP feedback + should be encrypted. + + Changing the ECN bits: An on-path attacker that sees the RTP packet + flow from sender to receiver and who has the capability to change + the packets can rewrite ECT into ECN-CE, thus leading to erroneous + congestion response in the sender or receiver. This denial of + service against the media quality in the RTP session is impossible + for an endpoint to protect itself against. Only network + infrastructure nodes can detect this illicit re-marking. It will + be mitigated by turning off ECN; however, if the attacker can + modify its response to drop packets, the same vulnerability exist. + + Denial of Service affecting the session setup signalling: If an + attacker can modify the session signalling, it can prevent the + usage of ECN by removing the signalling attributes used to + indicate that the initiator is capable and willing to use ECN with + RTP/UDP. This attack can be prevented by authentication and + integrity protection of the signalling. We do note that any + attacker that can modify the signalling has more interesting + attacks they can perform than prevent the usage of ECN, like + inserting itself as a middleman in the media flows enabling wire- + tapping also for an off-path attacker. + + Threats that exist from misbehaving senders or receivers: + + Receivers cheating: A receiver may attempt to cheat and fail to + report reception of ECN-CE-marked packets. The benefit for a + receiver cheating in its reporting would be to get an unfair + + + +Westerlund, et al. Standards Track [Page 49] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + bitrate share across the resource bottleneck. It is far from + certain that a receiver would be able to get a significant larger + share of the resources. That assumes a high enough level of + aggregation that there are flows to acquire shares from. The risk + of cheating is that failure to react to congestion results in + packet loss and increased path delay. + + Receivers misbehaving: A receiver may prevent the usage of ECN in an + RTP session by reporting itself as non-ECN capable, forcing the + sender to turn off usage of ECN. In a point-to-point scenario, + there is little incentive to do this as it will only affect the + receiver, thus failing to utilise an optimisation. For multi- + party sessions, some motivation exists for why a receiver would + misbehave as it can prevent the other receivers from using ECN. + As an insider into the session, it is difficult to determine if a + receiver is misbehaving or simply incapable, making it basically + impossible in the incremental deployment phase of ECN for RTP + usage to determine this. If additional information about the + receivers and the network is known, it might be possible to deduce + that a receiver is misbehaving. If it can be determined that a + receiver is misbehaving, the only response is to exclude it from + the RTP session and ensure that it no longer has any valid + security context to affect the session. + + Misbehaving senders: The enabling of ECN gives the media packets a + higher degree of probability to reach the receiver compared to + not-ECT-marked ones on an ECN-capable path. However, this is no + magic bullet, and failure to react to congestion will most likely + only slightly delay a network buffer over-run, in which its + session also will experience packet loss and increased delay. + There is some possibility that the media sender's traffic will + push other traffic out of the way without being affected too + negatively. However, we do note that a media sender still needs + to implement congestion control functions to prevent the media + from being badly affected by congestion events. Thus, the + misbehaving sender is getting an unfair share. This can only be + detected and potentially prevented by network monitoring and + administrative entities. See Section 7 of [RFC3168] for more + discussion of this issue. + + We note that the endpoint security functions needed to prevent an + external attacker from interfering with the signalling are source + authentication and integrity protection. To prevent information + leakage from the feedback packets, encryption of the RTCP is also + needed. For RTP, multiple possible solutions exist depending on the + application context. Secure RTP (SRTP) [RFC3711] does satisfy the + requirement to protect this mechanism. Note, however, that when + using SRTP in group communication scenarios, different parties might + + + +Westerlund, et al. Standards Track [Page 50] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + share the same security context; in this case, the authentication + mechanism only shows that one of those parties is involved, not + necessarily which one. IPsec [RFC4301] and DTLS [RFC6347] can also + provide the necessary security functions. + + The signalling protocols used to initiate an RTP session also need to + be source authenticated and integrity protected to prevent an + external attacker from modifying any signalling. An appropriate + mechanism to protect the used signalling needs to be used. For SIP/ + SDP, ideally Secure MIME (S/MIME) [RFC5751] would be used. However, + with the limited deployment, a minimal mitigation strategy is to + require use of SIPS (SIP over TLS) [RFC3261] [RFC5630] to at least + accomplish hop-by-hop protection. + + We do note that certain mitigation methods will require network + functions. + +12. Examples of SDP Signalling + + This section contains a few different examples of the signalling + mechanism defined in this specification in an SDP context. If there + are discrepancies between these examples and the specification text, + the specification text is definitive. + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Westerlund, et al. Standards Track [Page 51] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +12.1. Basic SDP Offer/Answer + + This example is a basic offer/answer SDP exchange, assumed done by + SIP (not shown). The intention is to establish a basic audio session + point-to-point between two users. + + The Offer: + + v=0 + o=jdoe 3502844782 3502844782 IN IP4 10.0.1.4 + s=VoIP call + i=SDP offer for VoIP call with ICE and ECN for RTP + b=AS:128 + b=RR:2000 + b=RS:2500 + a=ice-pwd:YH75Fviy6338Vbrhrlp8Yh + a=ice-ufrag:9uB6 + a=ice-options:rtp+ecn + t=0 0 + m=audio 45664 RTP/AVPF 97 98 99 + c=IN IP4 192.0.2.3 + a=rtpmap:97 G719/48000/1 + a=fmtp:97 maxred=160 + a=rtpmap:98 AMR-WB/16000/1 + a=fmtp:98 octet-align=1; mode-change-capability=2 + a=rtpmap:99 PCMA/8000/1 + a=maxptime:160 + a=ptime:20 + a=ecn-capable-rtp: ice rtp ect=0 mode=setread + a=rtcp-fb:* nack ecn + a=rtcp-fb:* trr-int 1000 + a=rtcp-xr:ecn-sum + a=rtcp-rsize + a=candidate:1 1 UDP 2130706431 10.0.1.4 8998 typ host + a=candidate:2 1 UDP 1694498815 192.0.2.3 45664 typ srflx raddr + 10.0.1.4 rport 8998 + + This SDP offer presents a single media stream with 3 media payload + types. It proposes to use ECN with RTP, with the ICE-based + initialisation being preferred over the RTP/RTCP one. Leap of faith + is not suggested to be used. The offerer is capable of both setting + and reading the ECN bits. In addition, the use of both the RTCP ECN + feedback packet and the RTCP XR ECN Summary Report are supported. + ICE is also proposed with two candidates. It also supports reduced- + size RTCP and can use it. + + + + + + +Westerlund, et al. Standards Track [Page 52] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + The Answer: + + v=0 + o=jdoe 3502844783 3502844783 IN IP4 198.51.100.235 + s=VoIP call + i=SDP offer for VoIP call with ICE and ECN for RTP + b=AS:128 + b=RR:2000 + b=RS:2500 + a=ice-pwd:asd88fgpdd777uzjYhagZg + a=ice-ufrag:8hhY + a=ice-options:rtp+ecn + t=0 0 + m=audio 53879 RTP/AVPF 97 99 + c=IN IP4 198.51.100.235 + a=rtpmap:97 G719/48000/1 + a=fmtp:97 maxred=160 + a=rtpmap:99 PCMA/8000/1 + a=maxptime:160 + a=ptime:20 + a=ecn-capable-rtp: ice ect=0 mode=readonly + a=rtcp-fb:* nack ecn + a=rtcp-fb:* trr-int 1000 + a=rtcp-xr:ecn-sum + a=candidate:1 1 UDP 2130706431 198.51.100.235 53879 typ host + + The answer confirms that only one media stream will be used. One RTP + payload type was removed. ECN capability was confirmed, and the + initialisation method will be ICE. However, the answerer is only + capable of reading the ECN bits, which means that ECN can only be + used for RTP flowing from the offerer to the answerer. ECT always + set to 0 will be used in both directions. Both the RTCP ECN feedback + packet and the RTCP XR ECN Summary Report will be used. Reduced-size + RTCP will not be used as the answerer has not indicated support for + it in the answer. + + + + + + + + + + + + + + + + +Westerlund, et al. Standards Track [Page 53] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +12.2. Declarative Multicast SDP + + The session below describes an Any-Source Multicast using a session + with a single media stream. + + v=0 + o=jdoe 3502844782 3502844782 IN IP4 198.51.100.235 + s=Multicast SDP session using ECN for RTP + i=Multicasted audio chat using ECN for RTP + b=AS:128 + t=3502892703 3502910700 + m=audio 56144 RTP/AVPF 97 + c=IN IP4 233.252.0.212/127 + a=rtpmap:97 g719/48000/1 + a=fmtp:97 maxred=160 + a=maxptime:160 + a=ptime:20 + a=ecn-capable-rtp: rtp mode=readonly; ect=0 + a=rtcp-fb:* nack ecn + a=rtcp-fb:* trr-int 1500 + a=rtcp-xr:ecn-sum + + This is a declarative SDP example and indicates required + functionality in the consumer of the SDP. The initialisation method + required is the RTP/RTCP-based one, indicated by the "a=ecn-capable- + rtp: rtp ..." line. Receivers are required to be able to read ECN + marks ("mode=readonly"), and the ECT value is recommended to be set + to 0 always ("ect=0"). The ECN usage in this session requires both + ECN feedback and RTCP XR ECN Summary Reports, and their use is + indicated through the "a=rtcp-fb:" and "a=rtcp-xr:ecn-sum" lines. + +13. Acknowledgments + + The authors wish to thank the following individuals for their reviews + and comments: Thomas Belling, Bob Briscoe, Roni Even, Kevin P. + Flemming, Tomas Frankkila, Christian Groves, Christer Holmgren, + Cullen Jennings, Tom Van Caenegem, Simo Veikkolainen, Bill Ver Steeg, + Dan Wing, Qin Wu, and Lei Zhu. + + + + + + + + + + + + + +Westerlund, et al. Standards Track [Page 54] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +14. References + +14.1. Normative References + + [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate + Requirement Levels", BCP 14, RFC 2119, March 1997. + + [RFC3168] Ramakrishnan, K., Floyd, S., and D. Black, "The Addition + of Explicit Congestion Notification (ECN) to IP", + RFC 3168, September 2001. + + [RFC3550] Schulzrinne, H., Casner, S., Frederick, R., and V. + Jacobson, "RTP: A Transport Protocol for Real-Time + Applications", STD 64, RFC 3550, July 2003. + + [RFC3611] Friedman, T., Caceres, R., and A. Clark, "RTP Control + Protocol Extended Reports (RTCP XR)", RFC 3611, + November 2003. + + [RFC3629] Yergeau, F., "UTF-8, a transformation format of ISO + 10646", STD 63, RFC 3629, November 2003. + + [RFC4566] Handley, M., Jacobson, V., and C. Perkins, "SDP: Session + Description Protocol", RFC 4566, July 2006. + + [RFC5234] Crocker, D. and P. Overell, "Augmented BNF for Syntax + Specifications: ABNF", STD 68, RFC 5234, January 2008. + + [RFC5245] Rosenberg, J., "Interactive Connectivity Establishment + (ICE): A Protocol for Network Address Translator (NAT) + Traversal for Offer/Answer Protocols", RFC 5245, + April 2010. + + [RFC5348] Floyd, S., Handley, M., Padhye, J., and J. Widmer, "TCP + Friendly Rate Control (TFRC): Protocol Specification", + RFC 5348, September 2008. + + [RFC5389] Rosenberg, J., Mahy, R., Matthews, P., and D. Wing, + "Session Traversal Utilities for NAT (STUN)", RFC 5389, + October 2008. + + [RFC6336] Westerlund, M. and C. Perkins, "IANA Registry for + Interactive Connectivity Establishment (ICE) Options", + RFC 6336, July 2011. + + + + + + + +Westerlund, et al. Standards Track [Page 55] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +14.2. Informative References + + [RFC1112] Deering, S., "Host extensions for IP multicasting", STD 5, + RFC 1112, August 1989. + + [RFC2762] Rosenberg, J. and H. Schulzrinne, "Sampling of the Group + Membership in RTP", RFC 2762, February 2000. + + [RFC2974] Handley, M., Perkins, C., and E. Whelan, "Session + Announcement Protocol", RFC 2974, October 2000. + + [RFC3261] Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston, + A., Peterson, J., Sparks, R., Handley, M., and E. + Schooler, "SIP: Session Initiation Protocol", RFC 3261, + June 2002. + + [RFC3264] Rosenberg, J. and H. Schulzrinne, "An Offer/Answer Model + with Session Description Protocol (SDP)", RFC 3264, + June 2002. + + [RFC3540] Spring, N., Wetherall, D., and D. Ely, "Robust Explicit + Congestion Notification (ECN) Signaling with Nonces", + RFC 3540, June 2003. + + [RFC3551] Schulzrinne, H. and S. Casner, "RTP Profile for Audio and + Video Conferences with Minimal Control", STD 65, RFC 3551, + July 2003. + + [RFC3569] Bhattacharyya, S., "An Overview of Source-Specific + Multicast (SSM)", RFC 3569, July 2003. + + [RFC3711] Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. + Norrman, "The Secure Real-time Transport Protocol (SRTP)", + RFC 3711, March 2004. + + [RFC4301] Kent, S. and K. Seo, "Security Architecture for the + Internet Protocol", RFC 4301, December 2005. + + [RFC4340] Kohler, E., Handley, M., and S. Floyd, "Datagram + Congestion Control Protocol (DCCP)", RFC 4340, March 2006. + + [RFC4585] Ott, J., Wenger, S., Sato, N., Burmeister, C., and J. Rey, + "Extended RTP Profile for Real-time Transport Control + Protocol (RTCP)-Based Feedback (RTP/AVPF)", RFC 4585, + July 2006. + + + + + + +Westerlund, et al. Standards Track [Page 56] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + + [RFC4588] Rey, J., Leon, D., Miyazaki, A., Varsa, V., and R. + Hakenberg, "RTP Retransmission Payload Format", RFC 4588, + July 2006. + + [RFC4607] Holbrook, H. and B. Cain, "Source-Specific Multicast for + IP", RFC 4607, August 2006. + + [RFC4960] Stewart, R., "Stream Control Transmission Protocol", + RFC 4960, September 2007. + + [RFC5117] Westerlund, M. and S. Wenger, "RTP Topologies", RFC 5117, + January 2008. + + [RFC5124] Ott, J. and E. Carrara, "Extended Secure RTP Profile for + Real-time Transport Control Protocol (RTCP)-Based Feedback + (RTP/SAVPF)", RFC 5124, February 2008. + + [RFC5506] Johansson, I. and M. Westerlund, "Support for Reduced-Size + Real-Time Transport Control Protocol (RTCP): Opportunities + and Consequences", RFC 5506, April 2009. + + [RFC5630] Audet, F., "The Use of the SIPS URI Scheme in the Session + Initiation Protocol (SIP)", RFC 5630, October 2009. + + [RFC5751] Ramsdell, B. and S. Turner, "Secure/Multipurpose Internet + Mail Extensions (S/MIME) Version 3.2 Message + Specification", RFC 5751, January 2010. + + [RFC5760] Ott, J., Chesterfield, J., and E. Schooler, "RTP Control + Protocol (RTCP) Extensions for Single-Source Multicast + Sessions with Unicast Feedback", RFC 5760, February 2010. + + [RFC6189] Zimmermann, P., Johnston, A., and J. Callas, "ZRTP: Media + Path Key Agreement for Unicast Secure RTP", RFC 6189, + April 2011. + + [RFC6347] Rescorla, E. and N. Modadugu, "Datagram Transport Layer + Security Version 1.2", RFC 6347, January 2012. + + + + + + + + + + + + + +Westerlund, et al. Standards Track [Page 57] + +RFC 6679 ECN for RTP over UDP/IP August 2012 + + +Authors' Addresses + + Magnus Westerlund + Ericsson + Farogatan 6 + SE-164 80 Kista + Sweden + Phone: +46 10 714 82 87 + EMail: magnus.westerlund@ericsson.com + + + Ingemar Johansson + Ericsson + Laboratoriegrand 11 + SE-971 28 Lulea + Sweden + Phone: +46 73 0783289 + EMail: ingemar.s.johansson@ericsson.com + + + Colin Perkins + University of Glasgow + School of Computing Science + Glasgow G12 8QQ + United Kingdom + EMail: csp@csperkins.org + + + Piers O'Hanlon + University of Oxford + Oxford Internet Institute + 1 St Giles + Oxford OX1 3JS + United Kingdom + EMail: piers.ohanlon@oii.ox.ac.uk + + + Ken Carlberg + G11 + 1600 Clarendon Blvd + Arlington, VA + USA + EMail: carlberg@g11.org.uk + + + + + + + + +Westerlund, et al. Standards Track [Page 58] + -- cgit v1.2.3