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/rfc9265.txt | 1058 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1058 insertions(+) create mode 100644 doc/rfc/rfc9265.txt (limited to 'doc/rfc/rfc9265.txt') diff --git a/doc/rfc/rfc9265.txt b/doc/rfc/rfc9265.txt new file mode 100644 index 0000000..1e24846 --- /dev/null +++ b/doc/rfc/rfc9265.txt @@ -0,0 +1,1058 @@ + + + + +Internet Research Task Force (IRTF) N. Kuhn +Request for Comments: 9265 CNES +Category: Informational E. Lochin +ISSN: 2070-1721 ENAC + F. Michel + UCLouvain + M. Welzl + University of Oslo + July 2022 + + + Forward Erasure Correction (FEC) Coding and Congestion Control in + Transport + +Abstract + + Forward Erasure Correction (FEC) is a reliability mechanism that is + distinct and separate from the retransmission logic in reliable + transfer protocols such as TCP. FEC coding can help deal with losses + at the end of transfers or with networks having non-congestion + losses. However, FEC coding mechanisms should not hide congestion + signals. This memo offers a discussion of how FEC coding and + congestion control can coexist. Another objective is to encourage + the research community to also consider congestion control aspects + when proposing and comparing FEC coding solutions in communication + systems. + + This document is the product of the Coding for Efficient Network + Communications Research Group (NWCRG). The scope of the document is + end-to-end communications; FEC coding for tunnels is out of the scope + of the document. + +Status of This Memo + + This document is not an Internet Standards Track specification; it is + published for informational purposes. + + This document is a product of the Internet Research Task Force + (IRTF). The IRTF publishes the results of Internet-related research + and development activities. These results might not be suitable for + deployment. This RFC represents the consensus of the Network Coding + for Efficient Network Communications Research Group of the Internet + Research Task Force (IRTF). Documents approved for publication by + the IRSG are not candidates for any level of Internet Standard; see + Section 2 of RFC 7841. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + https://www.rfc-editor.org/info/rfc9265. + +Copyright Notice + + Copyright (c) 2022 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 + (https://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. + +Table of Contents + + 1. Introduction + 2. Context + 2.1. Fairness, Quantifying and Limiting Harm, and Policy + Concerns + 2.2. Separate Channels, Separate Entities + 2.3. Relation between Transport Layer and Application + Requirements + 2.4. Scope of the Document Concerning Transport Multipath and + Multistream Applications + 2.5. Types of Coding + 3. FEC above the Transport + 3.1. Fairness and Impact on Non-coded Flows + 3.2. Congestion Control and Recovered Symbols + 3.3. Interactions between Congestion Control and Coding Rates + 3.4. On Useless Repair Symbols + 3.5. On Partial Ordering at FEC Level + 3.6. On Partial Reliability at FEC Level + 3.7. On Multipath Transport and FEC Mechanism + 4. FEC within the Transport + 4.1. Fairness and Impact on Non-coded Flows + 4.2. Interactions between Congestion Control and Coding Rates + 4.3. On Useless Repair Symbols + 4.4. On Partial Ordering at FEC and/or Transport Level + 4.5. On Partial Reliability at FEC Level + 4.6. On Transport Multipath and Subpath FEC Coding Rate + 5. FEC below the Transport + 5.1. Fairness and Impact on Non-coded Flows + 5.2. Congestion Control and Recovered Symbols + 5.3. Interactions between Congestion Control and Coding Rates + 5.4. On Useless Repair Symbols + 5.5. On Partial Ordering at FEC Level with In-Order Delivery + Transport + 5.6. On Partial Reliability at FEC Level + 5.7. FEC Not Aware of Transport Multipath + 6. Research Recommendations and Questions + 6.1. Activities Related to Congestion Control and Coding + 6.2. Open Research Questions + 6.2.1. Parameter Derivation + 6.2.2. New Signaling Methods and Fairness + 6.3. Recommendations and Advice for Evaluating Coding Mechanisms + 7. IANA Considerations + 8. Security Considerations + 9. Informative References + Acknowledgements + Authors' Addresses + +1. Introduction + + There are cases where deploying FEC coding improves the performance + of a transmission. As an example, it may take time for a sender to + detect transfer tail losses (losses that occur at the end of a + transfer where, e.g., TCP obtains no more ACKs that would enable it + to quickly repair the loss via retransmission). Allowing the + receiver to recover such losses instead of having to rely on a + retransmission could improve the experience of applications using + short flows. Another example is a network where non-congestion + losses are persistent and prevent a sender from exploiting the link + capacity. + + Coding and the loss detection of congestion controls are two distinct + and separate reliability mechanisms. Since FEC coding repairs + losses, blindly applying FEC may easily lead to an implementation + that also hides a congestion signal from the sender. It is important + to ensure that such hiding of information does not occur, because + loss may be the only congestion signal available to the sender (e.g., + TCP [RFC5681]). + + FEC coding and congestion control can be seen as two separate + channels. In practice, implementations may mix the signals that are + exchanged on these channels. This memo offers a discussion of how + FEC coding and congestion control coexist. Another objective is to + encourage the research community to also consider congestion control + aspects when proposing and comparing FEC coding solutions in + communication systems. This document does not aim to propose + guidelines for characterizing FEC coding solutions. + + We consider three architectures for end-to-end unicast data transfer: + + * with FEC coding in the application (above the transport) + (Section 3), + + * within the transport (Section 4), or + + * directly below the transport (Section 5). + + A typical scenario for the considerations in this document is a + client browsing the Web or watching a live video. + + This document represents the collaborative work and consensus of the + Coding for Efficient Network Communications Research Group (NWCRG); + it is not an IETF product nor a standard. The document follows the + terminology proposed in the taxonomy document [RFC8406]. + +2. Context + +2.1. Fairness, Quantifying and Limiting Harm, and Policy Concerns + + Traffic from or to different end users may share various types of + bottlenecks. When such a shared bottleneck does not implement some + form of flow protection, the share of the available capacity between + single flows can help assess when one flow starves the other. + + As one example, for residential accesses, the data rate can be + guaranteed for the customer premises equipment but not necessarily + for the end user. The quality of service that guarantees fairness + between the different clients can be seen as a policy concern + [FLOW-RATE-FAIRNESS]. + + While past efforts have focused on achieving fairness, quantifying + and limiting harm caused by new algorithms (or algorithms with + coding) is more practical [BEYONDJAIN]. This document considers + fairness as the impact of the addition of coded flows on non-coded + flows when they share the same bottleneck. It is assumed that the + non-coded flows respond to congestion signals from the network. This + document does not contribute to the definition of fairness at a wider + scale. + +2.2. Separate Channels, Separate Entities + + Figures 1 and 2 present the notations that will be used in this + document and introduce the Forward Erasure Correction (FEC) and + Congestion Control (CC) channels. The FEC channel carries repair + symbols (from the sender to the receiver) and information from the + receiver to the sender (e.g., signaling which symbols have been + recovered, loss rate prior and/or after decoding, etc.). The CC + channel carries network packets from a sender to a receiver and + packets signaling information about the network (number of packets + received vs. lost, Explicit Congestion Notification (ECN) marks + [RFC3168], etc.) from the receiver to the sender. The network + packets that are sent by the CC channel may be composed of source + packets and/or repair symbols. + + SENDER RECEIVER + + +------+ +------+ + | | ----- network packets ---->| | + | CC | | CC | + | | <--- network information ---| | + +------+ +------+ + + Figure 1: Congestion Control (CC) Channel + + SENDER RECEIVER + + +------+ +------+ + | | source and/or | | + | | ----- repair symbols ---->| | + | FEC | | FEC | + | | signaling | | + | | <--- recovered symbols ----| | + +------+ +------+ + + Figure 2: Forward Erasure Correction (FEC) Channel + + Inside a host, the CC and FEC entities can be regarded as + conceptually separate: + + | ^ | ^ + | source | coding |packets | sending + | packets | rate |requirements | rate (or + v | v | window) + +---------------+source +-----------------+ + | FEC |and/or | CC | + | |repair | |network + | |symbols | |packets + +---------------+==> +-----------------+==> + ^ ^ + | signaling | network + | recovered symbols | information + + Figure 3: Separate Entities (Sender-Side) + + | | + | source and/or | network + | repair symbols | packets + v v + +---------------+ +-----------------+ + | FEC |signaling | CC | + | |recovered | |network + | |symbols | |information + +---------------+==> +-----------------+==> + + Figure 4: Separate Entities (Receiver-Side) + + Figures 3 and 4 provide more details than Figures 1 and 2. Some + elements are introduced: + + 'network information' (input control plane for the transport + including CC): + refers not only to the network information that is explicitly + signaled from the receiver but all the information a congestion + control obtains from a network. + + 'requirements' (input control plane for the transport including + CC): + refers to application requirements such as upper/lower rate + bounds, periods of quiescence, or a priority. + + 'sending rate (or window)' (output control plane for the transport + including CC): + refers to the rate at which a congestion control decides to + transmit packets based on 'network information'. + + 'signaling recovered symbols' (input control plane for the FEC): + refers to the information a FEC sender can obtain from a FEC + receiver about the performance of the FEC solution as seen by the + receiver. + + 'coding rate' (output control plane for the FEC): + refers to the coding rate that is used by the FEC solution (i.e., + proportion of transmitted symbols that carry useful data). + + 'network packets' (output data plane for the CC): + refers to the data that is transmitted by a CC sender to a CC + receiver. The network packets may contain source and/or repair + symbols. + + 'source and/or repair symbols' (data plane for the FEC): + refers to the data that is transmitted by a FEC sender to a FEC + receiver. The sender can decide to send source symbols only + (meaning that the coding rate is 0), repair symbols only (if the + solution decides not to send the original source symbols), or a + mix of both. + + The inputs to FEC (incoming data packets without repair symbols and + signaling from the receiver about losses and/or recovered symbols) + are distinct from the inputs to CC. The latter calculates a sending + rate or window from network information, and it takes the packet to + send as input, sometimes along with application requirements such as + upper/lower rate bounds, periods of quiescence, or a priority. It is + not clear that the ACK signals feeding into a congestion control + algorithm are useful to FEC in their raw form, and vice versa; + information about recovered blocks may be quite irrelevant to a CC + algorithm. + +2.3. Relation between Transport Layer and Application Requirements + + The choice of the adequate transport layer may be related to + application requirements and the services offered by a transport + protocol [RFC8095]: + + The transport layer may implement a retransmission mechanism to + guarantee the reliability of a data transfer (e.g., TCP). + Depending on how the FEC and CC functions are scheduled (FEC above + CC (Section 3), FEC in CC (Section 4), and FEC below CC + (Section 5)), the impact of reliable transport on the FEC + reliability mechanisms is different. + + The transport layer may provide an unreliable transport service + (e.g., UDP or the Datagram Congestion Control Protocol (DCCP) + [RFC4340]) or a partially reliable transport service (e.g., the + Stream Control Transmission Protocol (SCTP) with the partial + reliability extension [RFC3758] or QUIC with the unreliable datagram + extension [RFC9221]). Depending on the amount of redundancy and + network conditions, there could be cases where it becomes impossible + to carry traffic. This is further discussed in Section 3 where a + "FEC above CC" case is assessed and in Sections 4 and 5 where "FEC in + CC" and "FEC below CC" are assessed, respectively. + +2.4. Scope of the Document Concerning Transport Multipath and + Multistream Applications + + The application layer can be composed of several streams above FEC + and transport-layer instances. The transport layer can exploit a + multipath mechanism. The different streams could exploit different + paths between the sender and the receiver. Moreover, a single-stream + application could also exploit a multipath transport mechanism. This + section describes what is in the scope of this document with regard + to multistream applications and multipath transport protocols. + + The different combinations between multistream applications and + multipath transport are the following: (1) one application-layer + stream as input packets above a combination of FEC and multipath + (Mpath) transport layers (Figure 5) and (2) multiple application- + layer streams as input packets above a combination of FEC and + multipath (Mpath) or single path (Spath) transport layers (Figure 6). + This document further details cases I (in Section 3.7), II (in + Section 4.6), and III (in Section 5.7) as illustrated in Figure 5. + Cases IV, V, and VI of Figure 6 are related to how multiple streams + are managed by a single transport or FEC layer; this does not + directly concern the interaction between FEC and the transport and is + out of the scope of this document. + + CASE I CASE II CASE III + +---------------+ +---------------+ +---------------+ + | Stream 1 | | Stream 2 | | Stream 3 | + +---------------+ +---------------+ +---------------+ + + +---------------+ +---------------+ +---------------+ + | FEC | | FEC | |Mpath Transport| + +---------------+ | in | +---------------+ + |Mpath Transport| + +---------------+ | | +-----+ +-----+ + |Mpath Transport| | | |Flow1|...|FlowM| + +---------------+ +---------------+ +-----+ +-----+ + + +-----+ +-----+ +-----+ +-----+ +-----+ +-----+ + |Flow1|...|FlowM| |Flow1|...|FlowM| | FEC |...| FEC | + +-----+ +-----+ +-----+ +-----+ +-----+ +-----+ + + Figure 5: Transport Multipath and Single-Stream Applications - in + the Scope of the Document + + CASE IV CASE V CASE VI + +-------+ +-------+ +-------+ +-------+ +-------+ +-------+ + |Stream1|...|StreamM| |Stream1|...|StreamM| |Stream1|...|StreamM| + +-------+ +-------+ +-------+ +-------+ +-------+ +-------+ + + +-------------------+ +-------------------+ +-------------------+ + | | | FEC | | Mpath Transport | + | FEC | +-------------------+ +-------------------+ + | above/in/below | + | Spath Transport | +-------------------+ +-------------------+ + | | | Mpath Transport | | FEC | + +-------------------+ +-------------------+ +-------------------+ + + +-------------------+ +-----+ +-----+ +-----+ +-----+ + | Flow | |Flow1| ... |FlowM| |Flow1| ... |FlowM| + +-------------------+ +-----+ +-----+ +-----+ +-----+ + + Figure 6: Transport Single Path, Transport Multipath, and Multistream + Applications - out of the Scope of the Document + +2.5. Types of Coding + + [RFC8406] summarizes recommended terminology for Network Coding + concepts and constructs. In particular, the document identifies the + following coding types (among many others): + + Block Coding: Coding technique where the input Flow must first be + segmented into a sequence of blocks; FEC encoding and decoding are + performed independently on a per-block basis. + + Sliding Window Coding: General class of coding techniques that rely + on a sliding encoding window. + + The decoding scheme may not be able to decode all the symbols. The + chance of decoding the erased packets depends on the size of the + encoding window, the coding rate, and the distribution of erasure in + the transmission channel. The FEC channel may let the client + transmit information related to the need of supplementary symbols to + adapt the level of reliability. Partial and full reliability could + be envisioned. + + Full reliability: The receiver may hold symbols until the decoding + of source symbols is possible. In particular, if the codec does + not enable a subset of the system to be inverted, the receiver + would have to wait for a certain minimum amount of repair packets + before it can recover all the source symbols. + + Partial reliability: The receiver cannot deliver source symbols that + could not have been decoded to the upper layer. For a fixed size + of encoding window (for Sliding Window Coding) or of blocks (for + Block Coding) containing the source symbols, increasing the amount + of repair symbols would increase the chances of recovering the + erased symbols. However, this would have an impact on memory + requirements, the cost of encoding and decoding processes, and the + network overhead. + +3. FEC above the Transport + + | source ^ source + | packets | packets + v | + +-------------+ +-------------+ + |FEC | signaling|FEC | + | | recovered| | + | | symbols| | + | | <==| | + +-------------+ +-------------+ + | source ^ ^ source + | and/or | sending | and/or + | repair | rate | repair + | symbols | (or window) | symbols + v | | + +-------------+ +-------------+ + |Transport | network|Transport | + |(incl. CC) | information| | + | |network <==| | + | |packets | | + +-------------+==> +-------------+ + + SENDER RECEIVER + + Figure 7: FEC above the Transport + + Figure 7 presents an architecture where FEC operates on top of the + transport. + + The advantage of this approach is that the FEC overhead does not + contribute to congestion in the network when congestion control is + implemented at the transport layer, because the repair symbols are + sent following the congestion window or rate determined by the CC + mechanism. This can result in an improved quality of experience for + latency-sensitive applications such as Voice over IP (VoIP) or any + not-fully reliable services. + + This approach requires that the transport protocol does not implement + a fully reliable in-order data transfer service (e.g., like TCP). + QUIC with the unreliable datagram extension [RFC9221] is an example + of a protocol for which this is relevant. In cases where the + partially reliable transport is blocked and a fallback to a reliable + transport is proposed, there is a risk for bad interactions between + reliability at the transport level and coding schemes. For reliable + transfers, coding usage does not guarantee better performance; + instead, it would mainly reduce goodput. + +3.1. Fairness and Impact on Non-coded Flows + + The addition of coding within the flow does not influence the + interaction between coded and non-coded flows. This interaction + would mainly depend on the congestion controls associated with each + flow. + +3.2. Congestion Control and Recovered Symbols + + The congestion control mechanism receives network packets and may not + be able to differentiate repair symbols from actual source ones. + This differentiation requires a transport protocol to provide more + than the services described in [RFC8095], such as specifically + indicating what information has been repaired. The relevance of + adding coding at the application layer is related to the needs of the + application. For real-time applications using an unreliable or + partially reliable transport, this approach may reduce the number of + losses perceived by the application. + +3.3. Interactions between Congestion Control and Coding Rates + + The coding rate applied at the application layer mainly depends on + the available rate or congestion window given by the congestion + control underneath. The coding rate could be adapted to avoid adding + overhead when the minimum required data rate of the application is + not provided by the congestion control underneath. When the + congestion control allows sending faster than the application needs, + adding coding can reduce packet losses and improve the quality of + experience (provided that an unreliable or partially reliable + transport is used). + +3.4. On Useless Repair Symbols + + The only case where adding useless repair symbols does not obviously + result in reduced goodput is when the application rate is limited + (e.g., VoIP traffic). In this case, useless repair symbols would + only impact the amount of data generated in the network. Extra data + in the network can, however, increase the likelihood of increasing + delay and/or packet loss, which could provoke a congestion control + reaction that would degrade goodput. + +3.5. On Partial Ordering at FEC Level + + Irrespective of the transport protocol, a FEC mechanism does not + require implementing a reordering mechanism if the application does + not need it. However, if the application needs in-order delivery of + packets, a reordering mechanism at the receiver is required. + +3.6. On Partial Reliability at FEC Level + + The application may require partial reliability. In this case, the + coding rate of a FEC mechanism could be adapted based on inputs from + the application and the trade-off between latency and packet loss. + Partial reliability impacts the type of FEC and type of codec that + can be used, such as discussed in Section 2.5. + +3.7. On Multipath Transport and FEC Mechanism + + Whether the transport protocol exploits multiple paths or not does + not have an impact on the FEC mechanism. + +4. FEC within the Transport + + | source ^ source + | packets | packets + v | + +------------+ +------------+ + | Transport | | Transport | + | | | | + | +---+ +--+ | signaling| +---+ +--+ | + | |FEC| |CC| | recovered| |FEC| |CC| | + | +---+ +--+ | symbols| +---+ +--+ | + | | <==| | + | |network network| | + | |packets information| | + +------------+ ==> <==+------------+ + + SENDER RECEIVER + + Figure 8: FEC in the Transport + + Figure 8 presents an architecture where FEC operates within the + transport. The repair symbols are sent within what the congestion + window or calculated rate allows, such as in [CTCP]. + + The advantage of this approach is that it allows a joint optimization + of CC and FEC. Moreover, the transmission of repair symbols does not + add congestion in potentially congested networks but helps repair + lost packets (such as tail losses). This joint optimization is the + key to prevent flows to consume the whole available capacity. The + amount of repair traffic injected should not lead to congestion. As + denoted in [FEC-CONGESTION-CONTROL], an increase of the repair ratio + should be done conjointly with a decrease of the source sending rate. + + The drawback of this approach is that it may require specific + signaling and transport services that may not be described in + [RFC8095]. Therefore, development and maintenance may require + specific efforts at both the transport and the coding levels, and the + design of the solution may end up being complex to suit different + deployment needs. + + For reliable transfers, including redundancy reduces goodput for long + transfers, but the amount of repair symbols can be adapted, e.g., + depending on the congestion window size. There is a trade-off + between 1) the capacity that could have been exploited by application + data instead of transmitting source packets and 2) the benefits + derived from transmitting repair symbols (e.g., unlocking the receive + buffer if it is limiting). The coding ratio needs to be carefully + designed. For small files, sending repair symbols when there is no + more data to transmit could help to reduce the transfer time. + Sending repair symbols can avoid the silence period between the + transmission of the last packet in the send buffer and 1) firing a + retransmission of lost packets or 2) the transmission of new packets. + + Examples of the solution could be to add a given percentage of the + congestion window or rate as supplementary symbols or to send a fixed + amount of repair symbols at a fixed rate. The redundancy flow can be + decorrelated from the congestion control that manages source packets; + a separate congestion control entity could be introduced to manage + the amount of recovered symbols to transmit on the FEC channel. The + separate congestion control instances could be made to work together + while adhering to priorities, as in coupled congestion control for + RTP media [RFC8699] in case all traffic can be assumed to take the + same path, or otherwise with a multipath congestion window coupling + mechanism as in Multipath TCP [RFC6356]. Another possibility would + be to exploit a lower-than-best-effort congestion control [RFC6297] + for repair symbols. + +4.1. Fairness and Impact on Non-coded Flows + + Specific interaction between congestion controls and coding schemes + can be proposed (see Sections 4.2 and 4.3). If no specific + interaction is introduced, the coding scheme may hide congestion + losses from the congestion controller, and the description of + Section 5 may apply. + +4.2. Interactions between Congestion Control and Coding Rates + + The receiver can differentiate between source packets and repair + symbols. The receiver may indicate both the number of source packets + received and the repair symbols that were actually useful in the + recovery process of packets. The congestion control at the sender + can then exploit this information to tune congestion control + behavior. + + There is an important flexibility in the trade-off, inherent to the + use of coding, between (1) reducing goodput when useless repair + symbols are transmitted and (2) helping to recover from losses + earlier than with retransmissions. The receiver may indicate to the + sender the number of packets that have been received or recovered. + The sender may use this information to tune the coding ratio. For + example, coupling an increased transmission rate with an increasing + or decreasing coding rate could be envisioned. A server may use a + decreasing coding rate as a probe of the channel capacity and adapt + the congestion control transmission rate. + +4.3. On Useless Repair Symbols + + The sender may exploit the information given by the receiver to + reduce the number of useless repair symbols and improve goodput. + +4.4. On Partial Ordering at FEC and/or Transport Level + + The application may require in-order delivery of packets. In this + case, both FEC and transport-layer mechanisms should guarantee that + packets are delivered in order. If partial ordering is requested by + the application, both the FEC and transport could relax the + constraints related to in-order delivery; partial ordering impacts + both the congestion control and the type of FEC and type of codec + that can be used. + +4.5. On Partial Reliability at FEC Level + + The application may require partial reliability. The reliability + offered by FEC may be sufficient with no retransmission required. + This depends on application needs and the trade-off between latency + and loss. Partial reliability impacts the type of FEC and type of + codec that can be used, such as discussed in Section 2.5. + +4.6. On Transport Multipath and Subpath FEC Coding Rate + + The sender may adapt the coding rate of each of the single subpaths + whether the congestion control is coupled or not. There is an + important flexibility on how the coding rate is tuned depending on + the characteristics of each subpath. + +5. FEC below the Transport + + | source ^ source + | packets | packets + v | + +--------------+ +--------------+ + |Transport | network|Transport | + |(including CC)| information| | + | | <==| | + +--------------+ +--------------+ + | network packets ^ network packets + v | + +--------------+ +--------------+ + | FEC |source | FEC | + | |and/or signaling| | + | |repair recovered| | + | |symbols symbols| | + | |==> <==| | + +--------------+ +--------------+ + + SENDER RECEIVER + + Figure 9: FEC below the Transport + + Figure 9 presents an architecture where FEC is applied end to end + below the transport layer but above the link layer. Note that it is + common to apply FEC at the link layer on one or more of the links + that make up the end-to-end path. The application of FEC at the link + layer contributes to the total capacity that a link exposes to upper + layers, but it may not be visible to either the end-to-end sender or + the receiver, if the end-to-end sender and receiver are separated by + more than one link; this is therefore out of scope for this document. + This includes the use of FEC on top of a link layer in scenarios + where the link is known by configuration. In the scenario considered + here, the repair symbols are not visible to the end-to-end congestion + controller and may be sent on top of what is allowed by the + congestion control. + + Including redundancy adds traffic without reducing goodput but incurs + potential fairness issues. The effective bit rate is higher than the + CC's computed fair share due to the transmission of repair symbols, + and losses are hidden from the transport. This may cause a problem + for loss-based congestion detection, but it is not a problem for + delay-based congestion detection. + + The advantage of this approach is that it can result in performance + gains when there are persistent transmission losses along the path. + + The drawback of this approach is that it can induce congestion in + already congested networks. The coding ratio needs to be carefully + designed. + + Examples of the solution could be to add a given percentage of the + congestion window or rate as supplementary symbols or to send a fixed + amount of repair symbols at a fixed rate. The redundancy flow can be + decorrelated from the congestion control that manages source packets; + a separate congestion control entity could be introduced to manage + the amount of recovered symbols to transmit on the FEC channel. The + separate congestion control instances could be made to work together + while adhering to priorities, as in coupled congestion control for + RTP media [RFC8699] in case all traffic can be assumed to take the + same path, or otherwise with a multipath congestion window coupling + mechanism as in Multipath TCP [RFC6356]. Another possibility would + be to exploit a lower-than-best-effort congestion control [RFC6297] + for repair symbols. + +5.1. Fairness and Impact on Non-coded Flows + + The coding scheme may hide congestion losses from the congestion + controller. There are cases where this can drastically reduce the + goodput of non-coded flows. Depending on the congestion control, it + may be possible to signal to the congestion control mechanism that + there was congestion (loss) even when a packet has been recovered, + e.g., using ECN, to reduce the impact on the non-coded flows (see + Section 5.2 and [TENTET]). + +5.2. Congestion Control and Recovered Symbols + + The congestion control may not be aware of the existence of a coding + scheme underneath it. The congestion control may behave as if no + coding scheme had been introduced. The only way for a coding channel + to indicate that symbols have been lost but recovered is to exploit + existing signaling that is understood by the congestion control + mechanism. An example would be to indicate to a TCP sender that a + packet has been received, yet congestion has occurred, by using ECN + signaling [TENTET]. + +5.3. Interactions between Congestion Control and Coding Rates + + The coding rate can be tuned depending on the number of recovered + symbols and the rate at which the sender transmits data. If the + coding scheme is not aware of the congestion control implementation, + it is hard for the coding scheme to apply the relevant coding rate. + +5.4. On Useless Repair Symbols + + Useless repair symbols only impact the load on the network without + actual gain for the coded flow. Using feedback signaling, FEC + mechanisms can measure the ratio between the number of symbols that + were actually used and the number of symbols that were useless, and + adjust the coding rate. + +5.5. On Partial Ordering at FEC Level with In-Order Delivery Transport + + The transport above the FEC channel may support out-of-order delivery + of packets; reordering mechanisms at the receiver may not be + necessary. In cases where the transport requires in-order delivery, + the FEC channel may need to implement a reordering mechanism. + Otherwise, spurious retransmissions may occur at the transport level. + +5.6. On Partial Reliability at FEC Level + + The transport or application layer above the FEC channel may require + partial reliability only. FEC may provide an unnecessary service + unless it is aware of the reliability requirements. Partial + reliability impacts the type of FEC and codec that can be used, such + as discussed in Section 2.5. + +5.7. FEC Not Aware of Transport Multipath + + The transport may exploit multiple paths without the FEC channel + being aware of it. If FEC is aware that multiple paths are in use, + FEC can be applied to all subflows as an aggregate, or to each of the + subflows individually. If FEC is not aware that multiple paths are + in use, FEC can only be applied to each subflow individually. When + FEC is applied to all the flows as an aggregate, the varying + characteristics of the individual paths may lead to a risk for the + coding rate to be inadequate for the characteristics of the + individual paths. + +6. Research Recommendations and Questions + + This section provides a short state-of-the art overview of activities + related to congestion control and coding. The objective is to + identify open research questions and contribute to advice when + evaluating coding mechanisms. + +6.1. Activities Related to Congestion Control and Coding + + We map activities related to congestion control and coding with the + organization presented in this document: + + For the FEC above transport case: [RFC8680] + + For the FEC within transport case: [CODING-FOR-QUIC], [QUIC-FEC], + and [RFC5109] + + For the FEC below transport case: [NCTCP] and [TETRYS] + +6.2. Open Research Questions + + There is a general trade-off, inherent to the use of coding, between + (1) reducing goodput when useless repair symbols are transmitted and + (2) helping to recover from transmission and congestion losses. + +6.2.1. Parameter Derivation + + There is a trade-off related to the amount of redundancy to add as a + function of the transport-layer protocol and application + requirements. + + [RFC8095] describes the mechanisms provided by existing IETF + protocols such as TCP, SCTP, or RTP. [RFC8406] describes the variety + of coding techniques. The number of combinations makes the + determination of an optimum parameters derivation very complex. This + depends on application requirements and deployment context. + + Appendix C of [RFC8681] describes how to tune the parameters for a + target use case. However, this discussion does not integrate + congestion-controlled end points. + + Research question 1: "Is there a way to dynamically adjust the codec + characteristics depending on the transmission channel, the + transport protocol, and application requirements?" + + Research question 2: "Should we apply specific per-stream FEC + mechanisms when multiple streams with different reliability needs + are carried out?" + +6.2.2. New Signaling Methods and Fairness + + Recovering lost symbols may hide congestion losses from the + congestion control. Disambiguating ACKed packets from rebuilt + packets would help the sender adapt its sending rate accordingly. + There are opportunities for introducing interaction between + congestion control and coding schemes to improve the quality of + experience while guaranteeing fairness with other flows. + + Some existing solutions already propose to disambiguate ACKed packets + from rebuilt packets [QUIC-FEC]. New signaling methods and FEC- + recovery-aware congestion controls could be proposed. This would + allow the design of adaptive coding rates. + + Research question 3: "Should we quantify the harm that a coded flow + would induce on a non-coded flow? How can this be reduced while + still benefiting from advantages brought by FEC?" + + Research question 4: "If transport and FEC senders are collocated + and close to the client, and FEC is applied only on the last mile, + e.g., to ignore losses on a noisy wireless link, would this raise + fairness issues?" + + Research question 5: "Should we propose a generic API to allow + dynamic interactions between a transport protocol and a coding + scheme? This should consider existing APIs between application + and transport layers." + +6.3. Recommendations and Advice for Evaluating Coding Mechanisms + + Research Recommendation 1: "From a congestion control point of view, + a recovered packet must be considered as a lost packet. This does + not apply to the usage of FEC on a path that is known to be + lossy." + + Research Recommendation 2: "New research contributions should be + mapped following the organization of this document (above, below, + and in the congestion control) and should consider congestion + control aspects when proposing and comparing FEC coding solutions + in communication systems." + + Research Recommendation 3: "When a research work aims at improving + throughput by hiding the packet loss signal from congestion + control (e.g., because the path between the sender and receiver is + known to consist of a noisy wireless link), the authors should 1) + discuss the advantages of using the proposed FEC solution compared + to replacing the congestion control by one that ignores a portion + of the encountered losses and 2) critically discuss the impact of + hiding packet loss from the congestion control mechanism." + +7. IANA Considerations + + This document has no IANA actions. + +8. Security Considerations + + FEC and CC schemes can contribute to DoS attacks. Moreover, the + transmission of signaling messages from the client to the server + should be protected and reliable; otherwise, an attacker may + compromise FEC rate adaptation. Indeed, an attacker could either + modify the values indicated by the client or drop signaling messages. + + In case of FEC below the transport, the aggregate rate of source and + repair packets may exceed the rate at which a congestion control + mechanism allows an application to send. This could result in an + application obtaining more than its fair share of the network + capacity. + +9. Informative References + + [BEYONDJAIN] + Ware, R., Mukerjee, M. K., Seshan, S., and J. Sherry, + "Beyond Jain's Fairness Index: Setting the Bar For The + Deployment of Congestion Control Algorithms", HotNets '19: + Proceedings of the 18th ACM Workshop on Hot Topics in + Networks, DOI 10.1145/3365609.3365855, November 2019, + . + + [CODING-FOR-QUIC] + Swett, I., Montpetit, M., Roca, V., and F. Michel, "Coding + for QUIC", Work in Progress, Internet-Draft, draft-swett- + nwcrg-coding-for-quic-04, 9 March 2020, + . + + [CTCP] Kim, M., Cloud, J., ParandehGheibi, A., Urbina, L., Fouli, + K., Leith, D., and M. Medard, "Network Coded TCP (CTCP)", + arXiv: 1212.2291v3, DOI 10.48550/arXiv.1212.2291, April + 2013, . + + [FEC-CONGESTION-CONTROL] + Singh, V., Nagy, M., Ott, J., and L. Eggert, "Congestion + Control Using FEC for Conversational Media", Work in + Progress, Internet-Draft, draft-singh-rmcat-adaptive-fec- + 03, 20 March 2016, . + + [FLOW-RATE-FAIRNESS] + Briscoe, B., "Flow Rate Fairness: Dismantling a Religion", + Work in Progress, Internet-Draft, draft-briscoe-tsvarea- + fair-02, 11 July 2007, + . + + [NCTCP] Sundararajan, J., Shah, D., Médard, M., Jakubczak, S., + Mitzenmacher, M., and J. Barros, "Network Coding Meets + TCP: Theory and Implementation", Proceedings of the IEEE + (Volume: 99, Issue: 3), DOI 10.1109/JPROC.2010.2093850, + March 2011, . + + [QUIC-FEC] Michel, F., De Coninck, Q., and O. Bonaventure, "QUIC-FEC: + Bringing the benefits of Forward Erasure Correction to + QUIC", DOI 10.23919/IFIPNetworking.2019.8816838, May 2019, + . + + [RFC3168] Ramakrishnan, K., Floyd, S., and D. Black, "The Addition + of Explicit Congestion Notification (ECN) to IP", + RFC 3168, DOI 10.17487/RFC3168, September 2001, + . + + [RFC3758] Stewart, R., Ramalho, M., Xie, Q., Tuexen, M., and P. + Conrad, "Stream Control Transmission Protocol (SCTP) + Partial Reliability Extension", RFC 3758, + DOI 10.17487/RFC3758, May 2004, + . + + [RFC4340] Kohler, E., Handley, M., and S. Floyd, "Datagram + Congestion Control Protocol (DCCP)", RFC 4340, + DOI 10.17487/RFC4340, March 2006, + . + + [RFC5109] Li, A., Ed., "RTP Payload Format for Generic Forward Error + Correction", RFC 5109, DOI 10.17487/RFC5109, December + 2007, . + + [RFC5681] Allman, M., Paxson, V., and E. Blanton, "TCP Congestion + Control", RFC 5681, DOI 10.17487/RFC5681, September 2009, + . + + [RFC6297] Welzl, M. and D. Ros, "A Survey of Lower-than-Best-Effort + Transport Protocols", RFC 6297, DOI 10.17487/RFC6297, June + 2011, . + + [RFC6356] Raiciu, C., Handley, M., and D. Wischik, "Coupled + Congestion Control for Multipath Transport Protocols", + RFC 6356, DOI 10.17487/RFC6356, October 2011, + . + + [RFC8095] Fairhurst, G., Ed., Trammell, B., Ed., and M. Kuehlewind, + Ed., "Services Provided by IETF Transport Protocols and + Congestion Control Mechanisms", RFC 8095, + DOI 10.17487/RFC8095, March 2017, + . + + [RFC8406] Adamson, B., Adjih, C., Bilbao, J., Firoiu, V., Fitzek, + F., Ghanem, S., Lochin, E., Masucci, A., Montpetit, M-J., + Pedersen, M., Peralta, G., Roca, V., Ed., Saxena, P., and + S. Sivakumar, "Taxonomy of Coding Techniques for Efficient + Network Communications", RFC 8406, DOI 10.17487/RFC8406, + June 2018, . + + [RFC8680] Roca, V. and A. Begen, "Forward Error Correction (FEC) + Framework Extension to Sliding Window Codes", RFC 8680, + DOI 10.17487/RFC8680, January 2020, + . + + [RFC8681] Roca, V. and B. Teibi, "Sliding Window Random Linear Code + (RLC) Forward Erasure Correction (FEC) Schemes for + FECFRAME", RFC 8681, DOI 10.17487/RFC8681, January 2020, + . + + [RFC8699] Islam, S., Welzl, M., and S. Gjessing, "Coupled Congestion + Control for RTP Media", RFC 8699, DOI 10.17487/RFC8699, + January 2020, . + + [RFC9221] Pauly, T., Kinnear, E., and D. Schinazi, "An Unreliable + Datagram Extension to QUIC", RFC 9221, + DOI 10.17487/RFC9221, March 2022, + . + + [TENTET] Lochin, E., "On the joint use of TCP and Network Coding", + NWCRG Session, IETF 100, November 2017, + . + + [TETRYS] Detchart, J., Lochin, E., Lacan, J., and V. Roca, "Tetrys, + an On-the-Fly Network Coding protocol", Work in Progress, + Internet-Draft, draft-detchart-nwcrg-tetrys-08, 17 October + 2021, . + +Acknowledgements + + Many thanks to Spencer Dawkins, Dave Oran, Carsten Bormann, Vincent + Roca, and Marie-Jose Montpetit for their useful comments that helped + improve the document. + +Authors' Addresses + + Nicolas Kuhn + CNES + Email: nicolas.kuhn.ietf@gmail.com + + + Emmanuel Lochin + ENAC + Email: emmanuel.lochin@enac.fr + + + François Michel + UCLouvain + Email: francois.michel@uclouvain.be + + + Michael Welzl + University of Oslo + Email: michawe@ifi.uio.no -- cgit v1.2.3