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/rfc8325.txt | 2075 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 2075 insertions(+) create mode 100644 doc/rfc/rfc8325.txt (limited to 'doc/rfc/rfc8325.txt') diff --git a/doc/rfc/rfc8325.txt b/doc/rfc/rfc8325.txt new file mode 100644 index 0000000..06eeb16 --- /dev/null +++ b/doc/rfc/rfc8325.txt @@ -0,0 +1,2075 @@ + + + + + + +Internet Engineering Task Force (IETF) T. Szigeti +Request for Comments: 8325 J. Henry +Category: Standards Track Cisco Systems +ISSN: 2070-1721 F. Baker + February 2018 + + + Mapping Diffserv to IEEE 802.11 + +Abstract + + As Internet traffic is increasingly sourced from and destined to + wireless endpoints, it is crucial that Quality of Service (QoS) be + aligned between wired and wireless networks; however, this is not + always the case by default. This document specifies a set of + mappings from Differentiated Services Code Point (DSCP) to IEEE + 802.11 User Priority (UP) to reconcile the marking recommendations + offered by the IETF and the IEEE so as to maintain consistent QoS + treatment between wired and IEEE 802.11 wireless networks. + +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 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/rfc8325. + +Copyright Notice + + Copyright (c) 2018 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. 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. + + + +Szigeti, et al. Standards Track [Page 1] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +Table of Contents + + 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3 + 1.1. Related Work . . . . . . . . . . . . . . . . . . . . . . 3 + 1.2. Interaction with RFC 7561 . . . . . . . . . . . . . . . . 4 + 1.3. Applicability Statement . . . . . . . . . . . . . . . . . 4 + 1.4. Document Organization . . . . . . . . . . . . . . . . . . 5 + 1.5. Requirements Language . . . . . . . . . . . . . . . . . . 5 + 1.6. Terminology Used in This Document . . . . . . . . . . . . 6 + 2. Service Comparison and Default Interoperation of Diffserv and + IEEE 802.11 . . . . . . . . . . . . . . . . . . . . . . . . . 9 + 2.1. Diffserv Domain Boundaries . . . . . . . . . . . . . . . 9 + 2.2. EDCF Queuing . . . . . . . . . . . . . . . . . . . . . . 10 + 2.3. Default DSCP-to-UP Mappings and Conflicts . . . . . . . . 10 + 2.4. Default UP-to-DSCP Mappings and Conflicts . . . . . . . . 11 + 3. Recommendations for Capabilities of Wireless Device Marking + and Mapping . . . . . . . . . . . . . . . . . . . . . . . . . 13 + 4. Recommendations for DSCP-to-UP Mapping . . . . . . . . . . . 13 + 4.1. Network Control Traffic . . . . . . . . . . . . . . . . . 14 + 4.1.1. Network Control Protocols . . . . . . . . . . . . . . 14 + 4.1.2. Operations, Administration, and Maintenance (OAM) . 15 + 4.2. User Traffic . . . . . . . . . . . . . . . . . . . . . . 15 + 4.2.1. Telephony . . . . . . . . . . . . . . . . . . . . . . 15 + 4.2.2. Signaling . . . . . . . . . . . . . . . . . . . . . . 16 + 4.2.3. Multimedia Conferencing . . . . . . . . . . . . . . . 17 + 4.2.4. Real-Time Interactive . . . . . . . . . . . . . . . . 17 + 4.2.5. Multimedia Streaming . . . . . . . . . . . . . . . . 17 + 4.2.6. Broadcast Video . . . . . . . . . . . . . . . . . . . 18 + 4.2.7. Low-Latency Data . . . . . . . . . . . . . . . . . . 18 + 4.2.8. High-Throughput Data . . . . . . . . . . . . . . . . 18 + 4.2.9. Standard . . . . . . . . . . . . . . . . . . . . . . 19 + 4.2.10. Low-Priority Data . . . . . . . . . . . . . . . . . . 20 + 4.3. Summary of Recommendations for DSCP-to-UP Mapping . . . . 20 + 5. Recommendations for Upstream Mapping and Marking . . . . . . 21 + 5.1. Upstream DSCP-to-UP Mapping within the Wireless Client + Operating System . . . . . . . . . . . . . . . . . . . . 22 + 5.2. Upstream UP-to-DSCP Mapping at the Wireless AP . . . . . 22 + 5.3. Upstream DSCP-Passthrough at the Wireless AP . . . . . . 23 + 5.4. Upstream DSCP Marking at the Wireless AP . . . . . . . . 24 + 6. Overview of IEEE 802.11 QoS . . . . . . . . . . . . . . . . . 24 + 6.1. Distributed Coordination Function (DCF) . . . . . . . . . 25 + 6.1.1. Slot Time . . . . . . . . . . . . . . . . . . . . . . 25 + 6.1.2. Interframe Space (IFS) . . . . . . . . . . . . . . . 26 + 6.1.3. Contention Window (CW) . . . . . . . . . . . . . . . 26 + 6.2. Hybrid Coordination Function (HCF) . . . . . . . . . . . 27 + 6.2.1. User Priority (UP) . . . . . . . . . . . . . . . . . 27 + 6.2.2. Access Category (AC) . . . . . . . . . . . . . . . . 28 + 6.2.3. Arbitration Interframe Space (AIFS) . . . . . . . . . 29 + + + +Szigeti, et al. Standards Track [Page 2] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + 6.2.4. Access Category CWs . . . . . . . . . . . . . . . . . 29 + 6.3. IEEE 802.11u QoS Map Set . . . . . . . . . . . . . . . . 30 + 7. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 31 + 8. Security Considerations . . . . . . . . . . . . . . . . . . . 31 + 8.1. Security Recommendations for General QoS . . . . . . . . 31 + 8.2. Security Recommendations for WLAN QoS . . . . . . . . . . 32 + 9. References . . . . . . . . . . . . . . . . . . . . . . . . . 34 + 9.1. Normative References . . . . . . . . . . . . . . . . . . 34 + 9.2. Informative References . . . . . . . . . . . . . . . . . 35 + Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . . 37 + Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 37 + +1. Introduction + + The wireless medium defined by IEEE 802.11 [IEEE.802.11-2016] has + become the preferred medium for endpoints connecting to business and + private networks. However, it presents several design challenges for + ensuring end-to-end QoS. Some of these challenges relate to the + nature of the IEEE 802.11 Radio Frequency (RF) medium itself, being a + half-duplex and shared medium, while other challenges relate to the + fact that the IEEE 802.11 standard is not administered by the same + standards body as IP networking standards. While the IEEE has + developed tools to enable QoS over wireless networks, little guidance + exists on how to maintain consistent QoS treatment between wired IP + networks and wireless IEEE 802.11 networks. The purpose of this + document is to provide such guidance. + +1.1. Related Work + + Several RFCs outline Diffserv QoS recommendations over IP networks, + including: + + RFC 2474 Specifies the Diffserv Codepoint Field. This RFC also + details Class Selectors, as well as the Default + Forwarding (DF) PHB for best effort traffic. The Default + Forwarding PHB is referred to as the Default PHB in RFC + 2474. + + RFC 2475 Defines a Diffserv architecture. + + RFC 3246 Specifies the Expedited Forwarding (EF) Per-Hop Behavior + (PHB). + + RFC 2597 Specifies the Assured Forwarding (AF) PHB. + + RFC 3662 Specifies a Lower-Effort Per-Domain Behavior (PDB). + + + + + +Szigeti, et al. Standards Track [Page 3] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + RFC 4594 Presents configuration guidelines for Diffserv service + classes. + + RFC 5127 Presents the aggregation of Diffserv service classes. + + RFC 5865 Specifies a DSCP for capacity-admitted traffic. + + Note: [RFC4594] is intended to be viewed as a framework for + supporting Diffserv in any network, including wireless networks; + thus, it describes different types of traffic expected in IP networks + and provides guidance as to what DSCP marking(s) should be associated + with each traffic type. As such, this document draws heavily on + [RFC4594], as well as [RFC5127], and [RFC8100]. + + In turn, the relevant standard for wireless QoS is IEEE 802.11, which + is being progressively updated; at the time of writing, the current + version of which is [IEEE.802.11-2016]. + +1.2. Interaction with RFC 7561 + + There is also a recommendation from the Global System for Mobile + Communications Association (GSMA) on DSCP-to-UP Mapping for IP Packet + eXchange (IPX), specifically their Guidelines for IPX Provider + networks [GSMA-IPX_Guidelines]. These GSMA Guidelines were developed + without reference to existing IETF specifications for various + services, referenced in Section 1.1. In turn, [RFC7561] was written + based on these GSMA Guidelines, as explicitly called out in + [RFC7561], Section 4.2. Thus, [RFC7561] conflicts with the overall + Diffserv traffic-conditioning service plan, both in the services + specified and the codepoints specified for them. As such, these two + plans cannot be normalized. Rather, as discussed in [RFC2474], + Section 2, the two domains (IEEE 802.11 and GSMA) are different + Differentiated Services Domains separated by a Differentiated + Services Boundary. At that boundary, codepoints from one domain are + translated to codepoints for the other, and maybe to Default (zero) + if there is no corresponding service to translate to. + +1.3. Applicability Statement + + This document is applicable to the use of Differentiated Services + that interconnect with IEEE 802.11 wireless LANs (referred to as + Wi-Fi, throughout this document, for simplicity). These guidelines + are applicable whether the wireless access points (APs) are deployed + in an autonomous manner, managed by (centralized or distributed) WLAN + controllers, or some hybrid deployment option. This is because, in + all these cases, the wireless AP is the bridge between wired and + wireless media. + + + + +Szigeti, et al. Standards Track [Page 4] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + This document applies to IP networks using Wi-Fi infrastructure at + the link layer. Such networks typically include wired LANs with + wireless APs at their edges; however, such networks can also include + Wi-Fi backhaul, wireless mesh solutions, or any other type of AP-to- + AP wireless network that extends the wired-network infrastructure. + +1.4. Document Organization + + This document is organized as follows: + + Section 1 introduces the wired-to-wireless QoS challenge, references + related work, outlines the organization of the document, and + specifies both the requirements language and the terminology used in + this document. + + Section 2 begins the discussion with a comparison of IETF Diffserv + QoS and Wi-Fi QoS standards and highlights discrepancies between + these that require reconciliation. + + Section 3 presents the marking and mapping capabilities that wireless + APs and wireless endpoint devices are recommended to support. + + Section 4 presents DSCP-to-UP mapping recommendations for each of the + [RFC4594] service classes, which are primarily applicable in the + downstream (wired-to-wireless) direction. + + Section 5, in turn, considers upstream (wireless-to-wired) QoS + options, their respective merits and recommendations. + + Section 6 (in the form of an Appendix) presents a brief overview of + how QoS is achieved over IEEE 802.11 wireless networks, given the + shared, half-duplex nature of the wireless medium. + + Section 7 contains IANA considerations. + + Section 8 presents security considerations relative to DSCP-to-UP + mapping, UP-to-DSCP mapping, and re-marking. + +1.5. Requirements Language + + 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 BCP + 14 [RFC2119] [RFC8174] when, and only when, they appear in all + capitals, as shown here. + + + + + + +Szigeti, et al. Standards Track [Page 5] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +1.6. Terminology Used in This Document + + Key terminology used in this document includes: + + AC: Access Category. A label for the common set of enhanced + distributed channel access (EDCA) parameters that are used by a + QoS station (STA) to contend for the channel in order to transmit + medium access control (MAC) service data units (MSDUs) with + certain priorities; see [IEEE.802.11-2016], Section 3.2. + + AIFS: Arbitration Interframe Space. Interframe space used by QoS + stations before transmission of data and other frame types defined + by [IEEE.802.11-2016], Section 10.3.2.3.6. + + AP: Access Point. An entity that contains one station (STA) and + provides access to the distribution services, via the wireless + medium (WM) for associated STAs. An AP comprises a STA and a + distribution system access function (DSAF); see + [IEEE.802.11-2016], Section 3.1. + + BSS: Basic Service Set. Informally, a wireless cell; formally, a set + of stations that have successfully synchronized using the JOIN + service primitives and one STA that has used the START primitive. + Alternatively, a set of STAs that have used the START primitive + specifying matching mesh profiles where the match of the mesh + profiles has been verified via the scanning procedure. Membership + in a BSS does not imply that wireless communication with all other + members of the BSS is possible. See the definition in + [IEEE.802.11-2016], Section 3.1. + + Contention Window: See CW. + + CSMA/CA: Carrier Sense Multiple Access with Collision Avoidance. A + MAC method in which carrier sensing is used, but nodes attempt to + avoid collisions by transmitting only when the channel is sensed + to be "idle". When these do transmit, nodes transmit their packet + data in its entirety. + + CSMA/CD: Carrier Sense Multiple Access with Collision Detection. A + MAC method (used most notably in early Ethernet technology) for + local area networking. It uses a carrier-sensing scheme in which + a transmitting station detects collisions by sensing transmissions + from other stations while transmitting a frame. When this + collision condition is detected, the station stops transmitting + that frame, transmits a jam signal, and then waits for a random + time interval before trying to resend the frame. + + + + + +Szigeti, et al. Standards Track [Page 6] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + CW: Contention Window. Limits a CWMin and CWMax, from which a + random backoff is computed. + + CWMax: Contention Window Maximum. The maximum value (in units of + Slot Time) that a CW can take. + + CWMin: Contention Window Minimum. The minimum value that a CW can + take. + + DCF: Distributed Coordinated Function. A class of coordination + function where the same coordination function logic is active in + every station (STA) in the BSS whenever the network is in + operation. + + DIFS: Distributed (Coordination Function) Interframe Space. A unit + of time during which the medium has to be detected as idle before + a station should attempt to send frames, as per + [IEEE.802.11-2016], Section 10.3.2.3.5. + + DSCP: Differentiated Service Code Point [RFC2474] and [RFC2475]. + The DSCP is carried in the first 6 bits of the IPv4 Type of + Service (TOS) field and the IPv6 Traffic Class field (the + remaining 2 bits are used for IP Explicit Congestion Notification + (ECN) [RFC3168]). + + EIFS: Extended Interframe Space. A unit of time that a station has + to defer before transmitting a frame if the previous frame + contained an error, as per [IEEE.802.11-2016], Section 10.3.2.3.7. + + HCF: Hybrid Coordination Function. A coordination function that + combines and enhances aspects of the contention-based and + contention-free access methods to provide QoS stations (STAs) with + prioritized and parameterized QoS access to the WM, while + continuing to support non-QoS STAs for best-effort transfer; see + [IEEE.802.11-2016], Section 3.1. + + IFS: Interframe Space. Period of silence between transmissions over + IEEE 802.11 networks. [IEEE.802.11-2016] describes several types + of Interframe Spaces. + + Random Backoff Timer: A pseudorandom integer period of time (in + units of Slot Time) over the interval (0,CW), where CWmin is less + than or equal to CW, which in turn is less than or equal to CWMax. + Stations desiring to initiate transfer of data frames and/or + management frames using the DCF shall invoke the carrier sense + mechanism to determine the busy-or-idle state of the medium. If + the medium is busy, the STA shall defer until the medium is + determined to be idle without interruption for a period of time + + + +Szigeti, et al. Standards Track [Page 7] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + equal to DIFS when the last frame detected on the medium was + received correctly or after the medium is determined to be idle + without interruption for a period of time equal to EIFS when the + last frame detected on the medium was not received correctly. + After this DIFS or EIFS medium idle time, the STA shall then + generate a random backoff period for an additional deferral time + before transmitting. See [IEEE.802.11-2016], Section 10.3.3. + + RF: Radio Frequency. + + SIFS: Short Interframe Space. An IFS used before transmission of + specific frames as defined in [IEEE.802.11-2016], + Section 10.3.2.3.3. + + Slot Time: A unit of time used to count time intervals in IEEE + 802.11 networks; it is defined in [IEEE.802.11-2016], + Section 10.3.2.13. + + Trust: From a QoS-perspective, "trust" refers to the accepting of + the QoS markings of a packet by a network device. Trust is + typically extended at Layer 3 (by accepting the DSCP), but may + also be extended at lower layers, such as at Layer 2 by accepting + UP markings. For example, if an AP is configured to trust DSCP + markings and it receives a packet marked EF, then it would treat + the packet with the Expedite Forwarding PHB and propagate the EF + marking value (DSCP 46) as it transmits the packet. + Alternatively, if a network device is configured to operate in an + untrusted manner, then it would re-mark packets as these entered + the device, typically to DF (or to a different marking value at + the network administrator's preference). Note: The terms + "trusted" and "untrusted" are used extensively in [RFC4594]. + + UP: User Priority. A value associated with an MSDU that indicates + how the MSDU is to be handled. The UP is assigned to an MSDU in + the layers above the MAC; see [IEEE.802.11-2016], Section 3.1. + The UP defines a level of priority for the associated frame, on a + scale of 0 to 7. + + Wi-Fi: An interoperability certification defined by the Wi-Fi + Alliance. However, this term is commonly used, including in the + present document, to be the equivalent of IEEE 802.11. + + Wireless: In the context of this document, "wireless" refers to the + media defined in IEEE 802.11 [IEEE.802.11-2016], and not 3G/4G LTE + or any other radio telecommunications specification. + + + + + + +Szigeti, et al. Standards Track [Page 8] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +2. Service Comparison and Default Interoperation of Diffserv and + IEEE 802.11 + + (Section 6 provides a brief overview of IEEE 802.11 QoS.) + + The following comparisons between IEEE 802.11 and Diffserv services + should be noted: + + [IEEE.802.11-2016] does not support an EF PHB service [RFC3246], + as it is not possible to assure that a given access category will + be serviced with strict priority over another (due to the random + element within the contention process) + + [IEEE.802.11-2016] does not support an AF PHB service [RFC2597], + again because it is not possible to assure that a given access + category will be serviced with a minimum amount of assured + bandwidth (due to the non-deterministic nature of the contention + process) + + [IEEE.802.11-2016] loosely supports a Default PHB ([RFC2474]) via + the Best Effort Access Category (AC_BE) + + [IEEE.802.11-2016] loosely supports a Lower Effort PDB service + ([RFC3662]) via the Background Access Category (AC_BK) + + As such, these high-level considerations should be kept in mind when + mapping from Diffserv to [IEEE.802.11-2016] (and vice versa); + however, APs may or may not always be positioned at Diffserv domain + boundaries, as will be discussed next. + +2.1. Diffserv Domain Boundaries + + It is important to recognize that the wired-to-wireless edge may or + may not function as an edge of a Diffserv domain or a domain + boundary. + + In most commonly deployed WLAN models, the wireless AP represents not + only the edge of the Diffserv domain, but also the edge of the + network infrastructure itself. As such, only client endpoint devices + (and no network infrastructure devices) are downstream from the + access points in these deployment models. Note: security + considerations and recommendations for hardening such Wi-Fi-at-the- + edge deployment models are detailed in Section 8; these + recommendations include mapping network control protocols (which are + not used downstream from the AP in this deployment model) to UP 0. + + + + + + +Szigeti, et al. Standards Track [Page 9] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + Alternatively, in other deployment models, such as Wi-Fi backhaul, + wireless mesh infrastructures, wireless AP-to-AP deployments, or in + cases where a Wi-Fi link connects to a device providing service via + another technology (e.g., Wi-Fi to Bluetooth or Zigbee router), the + wireless AP extends the network infrastructure and thus, typically, + the Diffserv domain. In such deployments, both client devices and + infrastructure devices may be expected downstream from the APs, and, + as such, network control protocols are RECOMMENDED to be mapped to UP + 7 in this deployment model, as is discussed in Section 4.1.1. + + Thus, as can be seen from these two examples, the QoS treatment of + packets at the AP will depend on the position of the AP in the + network infrastructure and on the WLAN deployment model. + + However, regardless of whether or not the AP is at the Diffserv + boundary, marking-specific incompatibilities exist from Diffserv to + 802.11 (and vice versa) that must be reconciled, as will be discussed + next. + +2.2. EDCF Queuing + + [IEEE.802.11-2016] displays a reference implementation queuing model + in Figure 10-24, which depicts four transmit queues, one per access + category. + + However, in practical implementations, it is common for WLAN network + equipment vendors to implement dedicated transmit queues on a per-UP + (versus a per-AC) basis, which are then dequeued into their + associated AC in a preferred (or even in a strict priority manner). + For example, it is common for vendors to dequeue UP 5 ahead of UP 4 + to the hardware performing the EDCA function (EDCAF) for the Video + Access Category (AC_VI). + + Some of the recommendations made in Section 4 make reference to this + common implementation model of queuing per UP. + +2.3. Default DSCP-to-UP Mappings and Conflicts + + While no explicit guidance is offered in mapping (6-Bit) Layer 3 DSCP + values to (3-Bit) Layer 2 markings (such as IEEE 802.1D, 802.1p or + 802.11e), a common practice in the networking industry is to map + these by what we will refer to as "default DSCP-to-UP mapping" (for + lack of a better term), wherein the three Most Significant Bits + (MSBs) of the DSCP are used as the corresponding L2 markings. + + + + + + + +Szigeti, et al. Standards Track [Page 10] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + Note: There are mappings provided in [IEEE.802.11-2016], Annex V + Tables V-1 and V2, but it bears mentioning that these mappings are + provided as examples (as opposed to explicit recommendations). + Furthermore, some of these mappings do not align with the intent and + recommendations expressed in [RFC4594], as will be discussed in this + and the following section (Section 2.4). + + However, when this default DSCP-to-UP mapping method is applied to + packets marked per recommendations in [RFC4594] and destined to + 802.11 WLAN clients, it will yield a number of inconsistent QoS + mappings, specifically: + + o Voice (EF-101110) will be mapped to UP 5 (101), and treated in the + Video Access Category (AC_VI) rather than the Voice Access + Category (AC_VO), for which it is intended + + o Multimedia Streaming (AF3-011xx0) will be mapped to UP 3 (011) and + treated in the Best Effort Access Category (AC_BE) rather than the + Video Access Category (AC_VI), for which it is intended + + o Broadcast Video (CS3-011000) will be mapped to UP 3 (011) and + treated in the Best Effort Access Category (AC_BE) rather than the + Video Access Category (AC_VI), for which it is intended + + o OAM traffic (CS2-010000) will be mapped to UP 2 (010) and treated + in the Background Access Category (AC_BK), which is not the intent + expressed in [RFC4594] for this service class + + It should also be noted that while [IEEE.802.11-2016] defines an + intended use for each access category through the AC naming + convention (for example, UP 6 and UP 7 belong to AC_VO, the Voice + Access Category), [IEEE.802.11-2016] does not: + + o define how upper-layer markings (such as DSCP) should map to UPs + (and, hence, to ACs) + + o define how UPs should translate to other mediums' Layer 2 QoS + markings + + o strictly restrict each access category to applications reflected + in the AC name + +2.4. Default UP-to-DSCP Mappings and Conflicts + + In the opposite direction of flow (the upstream direction, that is, + from wireless-to-wired), many APs use what we will refer to as + "default UP-to-DSCP mapping" (for lack of a better term), wherein + DSCP values are derived from UP values by multiplying the UP values + + + +Szigeti, et al. Standards Track [Page 11] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + by 8 (i.e., shifting the three UP bits to the left and adding three + additional zeros to generate a DSCP value). This derived DSCP value + is then used for QoS treatment between the wireless AP and the + nearest classification and marking policy enforcement point (which + may be the centralized wireless LAN controller, relatively deep + within the network). Alternatively, in the case where there is no + other classification and marking policy enforcement point, then this + derived DSCP value will be used on the remainder of the Internet + path. + + It goes without saying that when six bits of marking granularity are + derived from three, then information is lost in translation. + Servicing differentiation cannot be made for 12 classes of traffic + (as recommended in [RFC4594]), but for only eight (with one of these + classes being reserved for future use (i.e., UP 7, which maps to DSCP + CS7). + + Such default upstream mapping can also yield several inconsistencies + with [RFC4594], including: + + o Mapping UP 6 (which would include Voice or Telephony traffic, see + [RFC4594]) to CS6, which [RFC4594] recommends for Network Control + + o Mapping UP 4 (which would include Multimedia Conferencing and/or + Real-Time Interactive traffic, see [RFC4594]) to CS4, thus losing + the ability to differentiate between these two distinct service + classes, as recommended in [RFC4594], Sections 4.3 and 4.4 + + o Mapping UP 3 (which would include Multimedia Streaming and/or + Broadcast Video traffic, see [RFC4594]) to CS3, thus losing the + ability to differentiate between these two distinct service + classes, as recommended in [RFC4594], Sections 4.5 and 4.6 + + o Mapping UP 2 (which would include Low-Latency Data and/or OAM + traffic, see [RFC4594]) to CS2, thus losing the ability to + differentiate between these two distinct service classes, as + recommended in [RFC4594], Sections 4.7 and 3.3, and possibly + overwhelming the queues provisioned for OAM (which is typically + lower in capacity (being Network Control Traffic), as compared to + Low-Latency Data queues (being user traffic)) + + o Mapping UP 1 (which would include High-Throughput Data and/or Low- + Priority Data traffic, see [RFC4594]) to CS1, thus losing the + ability to differentiate between these two distinct service + classes, as recommended in [RFC4594], Sections 4.8 and 4.10, and + causing legitimate business-relevant High-Throughput Data to + receive a [RFC3662] Lower-Effort PDB, for which it is not intended + + + + +Szigeti, et al. Standards Track [Page 12] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + The following sections address these limitations and concerns in + order to reconcile [RFC4594] and [IEEE.802.11-2016]. First + downstream (wired-to-wireless) DSCP-to-UP mappings will be aligned + and then upstream (wireless-to-wired) models will be addressed. + +3. Recommendations for Capabilities of Wireless Device Marking and + Mapping + + This document assumes and RECOMMENDS that all wireless APs (as the + interconnects between wired-and-wireless networks) support the + ability to: + + o mark DSCP, per Diffserv standards + + o mark UP, per the [IEEE.802.11-2016] standard + + o support fully configurable mappings between DSCP and UP + + o process DSCP markings set by wireless endpoint devices + + This document further assumes and RECOMMENDS that all wireless + endpoint devices support the ability to: + + o mark DSCP, per Diffserv standards + + o mark UP, per the [IEEE.802.11-2016] standard + + o support fully configurable mappings between DSCP (set by + applications in software) and UP (set by the operating system and/ + or wireless network interface hardware drivers) + + Having made the assumptions and recommendations above, it bears + mentioning that, while the mappings presented in this document are + RECOMMENDED to replace the current common default practices (as + discussed in Sections 2.3 and 2.4), these mapping recommendations are + not expected to fit every last deployment model; as such, they MAY be + overridden by network administrators, as needed. + +4. Recommendations for DSCP-to-UP Mapping + + The following section specifies downstream (wired-to-wireless) + mappings between [RFC4594], "Configuration Guidelines for Diffserv + Service Classes" and [IEEE.802.11-2016]. As such, this section draws + heavily from [RFC4594], including service class definitions and + recommendations. + + + + + + +Szigeti, et al. Standards Track [Page 13] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + This section assumes [IEEE.802.11-2016] wireless APs and/or WLAN + controllers that support customizable, non-default DSCP-to-UP mapping + schemes. + + This section also assumes that [IEEE.802.11-2016] APs and endpoint + devices differentiate UP markings with corresponding queuing and + dequeuing treatments, as described in Section 2.2. + +4.1. Network Control Traffic + + Network Control Traffic is defined as packet flows that are essential + for stable operation of the administered network [RFC4594], + Section 3. Network Control Traffic is different from user + application control (signaling) that may be generated by some + applications or services. Network Control Traffic MAY be split into + two service classes: + + o Network Control, and + + o Operations, Administration, and Maintenance (OAM) + +4.1.1. Network Control Protocols + + The Network Control service class is used for transmitting packets + between network devices (e.g., routers) that require control + (routing) information to be exchanged between nodes within the + administrative domain, as well as across a peering point between + different administrative domains. + + [RFC4594], Section 3.2, recommends that Network Control Traffic be + marked CS6 DSCP. Additionally, as stated in [RFC4594], Section 3.1: + "CS7 DSCP value SHOULD be reserved for future use, potentially for + future routing or control protocols." + + By default (as described in Section 2.4), packets marked DSCP CS7 + will be mapped to UP 7 and serviced within the Voice Access Category + (AC_VO). This represents the RECOMMENDED mapping for CS7, that is, + packets marked to CS7 DSCP are RECOMMENDED to be mapped to UP 7. + + However, by default (as described in Section 2.4), packets marked + DSCP CS6 will be mapped to UP 6 and serviced within the Voice Access + Category (AC_VO); such mapping and servicing is a contradiction to + the intent expressed in [RFC4594], Section 3.2. As such, it is + RECOMMENDED to map Network Control Traffic marked CS6 to UP 7 (per + [IEEE.802.11-2016], Section 10.2.4.2, Table 10-1), thereby admitting + it to the Voice Access Category (AC_VO), albeit with a marking + distinguishing it from (data-plane) voice traffic. + + + + +Szigeti, et al. Standards Track [Page 14] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + It should be noted that encapsulated routing protocols for + encapsulated or overlay networks (e.g., VPN, Network Virtualization + Overlays, etc.) are not Network Control Traffic for any physical + network at the AP; hence, they SHOULD NOT be marked with CS6 in the + first place. + + Additionally, and as previously noted, the Security Considerations + section (Section 8) contains additional recommendations for hardening + Wi-Fi-at-the-edge deployment models, where, for example, network + control protocols are not expected to be sent nor received between + APs and client endpoint devices that are downstream. + +4.1.2. Operations, Administration, and Maintenance (OAM) + + The OAM (Operations, Administration, and Maintenance) service class + is recommended for OAM&P (Operations, Administration, and Maintenance + and Provisioning). The OAM service class can include network + management protocols, such as SNMP, Secure Shell (SSH), TFTP, Syslog, + etc., as well as network services, such as NTP, DNS, DHCP, etc. + [RFC4594], Section 3.3, recommends that OAM traffic be marked CS2 + DSCP. + + By default (as described in Section 2.3), packets marked DSCP CS2 + will be mapped to UP 2 and serviced with the Background Access + Category (AC_BK). Such servicing is a contradiction to the intent + expressed in [RFC4594], Section 3.3. As such, it is RECOMMENDED that + a non-default mapping be applied to OAM traffic, such that CS2 DSCP + is mapped to UP 0, thereby admitting it to the Best Effort Access + Category (AC_BE). + +4.2. User Traffic + + User traffic is defined as packet flows between different users or + subscribers. It is the traffic that is sent to or from end-terminals + and that supports a very wide variety of applications and services + [RFC4594], Section 4. + + Network administrators can categorize their applications according to + the type of behavior that they require and MAY choose to support all + or a subset of the defined service classes. + +4.2.1. Telephony + + The Telephony service class is recommended for applications that + require real-time, very low delay, very low jitter, and very low + packet loss for relatively constant-rate traffic sources (inelastic + traffic sources). This service class SHOULD be used for IP telephony + service. The fundamental service offered to traffic in the Telephony + + + +Szigeti, et al. Standards Track [Page 15] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + service class is minimum jitter, delay, and packet loss service up to + a specified upper bound. [RFC4594], Section 4.1, recommends that + Telephony traffic be marked EF DSCP. + + Traffic marked to DSCP EF will map by default (as described in + Section 2.3) to UP 5 and, thus, to the Video Access Category (AC_VI) + rather than to the Voice Access Category (AC_VO), for which it is + intended. Therefore, a non-default DSCP-to-UP mapping is + RECOMMENDED, such that EF DSCP is mapped to UP 6, thereby admitting + it into the Voice Access Category (AC_VO). + + Similarly, the VOICE-ADMIT DSCP (44 decimal / 101100 binary) + described in [RFC5865] is RECOMMENDED to be mapped to UP 6, thereby + admitting it also into the Voice Access Category (AC_VO). + +4.2.2. Signaling + + The Signaling service class is recommended for delay-sensitive + client-server (e.g., traditional telephony) and peer-to-peer + application signaling. Telephony signaling includes signaling + between 1) IP phone and soft-switch, 2) soft-client and soft-switch, + and 3) media gateway and soft-switch as well as peer-to-peer using + various protocols. This service class is intended to be used for + control of sessions and applications. [RFC4594], Section 4.2, + recommends that Signaling traffic be marked CS5 DSCP. + + While Signaling is recommended to receive a superior level of service + relative to the default class (i.e., AC_BE), it does not require the + highest level of service (i.e., AC_VO). This leaves only the Video + Access Category (AC_VI), which it will map to by default (as + described in Section 2.3). Therefore, it is RECOMMENDED to map + Signaling traffic marked CS5 DSCP to UP 5, thereby admitting it to + the Video Access Category (AC_VI). + + Note: Signaling traffic is not control-plane traffic from the + perspective of the network (but rather is data-plane traffic); as + such, it does not merit provisioning in the Network Control service + class (marked CS6 and mapped to UP 6). However, Signaling traffic is + control-plane traffic from the perspective of the voice/video + telephony overlay-infrastructure. As such, Signaling should be + treated with preferential servicing versus other data-plane flows. + This may be achieved in common WLAN deployments by mapping Signaling + traffic marked CS5 to UP 5. On APs supporting per-UP EDCAF queuing + logic (as described in Section 2.2), this will result in preferential + treatment for Signaling traffic versus other video flows in the same + access category (AC_VI), which are marked to UP 4, as well as + preferred treatment over flows in the Best Effort (AC_BE) and + Background (AC_BK) Access Categories. + + + +Szigeti, et al. Standards Track [Page 16] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +4.2.3. Multimedia Conferencing + + The Multimedia Conferencing service class is recommended for + applications that require real-time service for rate-adaptive + traffic. [RFC4594], Section 4.3, recommends Multimedia Conferencing + traffic be marked AF4x (that is, AF41, AF42, and AF43, according to + the rules defined in [RFC2475]). + + The primary media type typically carried within the Multimedia + Conferencing service class is video; as such, it is RECOMMENDED to + map this class into the Video Access Category (AC_VI), which it does + by default (as described in Section 2.3). Specifically, it is + RECOMMENDED to map AF41, AF42, and AF43 to UP 4, thereby admitting + Multimedia Conferencing into the Video Access Category (AC_VI). + +4.2.4. Real-Time Interactive + + The Real-Time Interactive service class is recommended for + applications that require low loss and jitter and very low delay for + variable-rate inelastic traffic sources. Such applications may + include inelastic video-conferencing applications, but may also + include gaming applications (as pointed out in [RFC4594], Sections + 2.1 through 2.3 and Section 4.4). [RFC4594], Section 4.4, recommends + Real-Time Interactive traffic be marked CS4 DSCP. + + The primary media type typically carried within the Real-Time + Interactive service class is video; as such, it is RECOMMENDED to map + this class into the Video Access Category (AC_VI), which it does by + default (as described in Section 2.3). Specifically, it is + RECOMMENDED to map CS4 to UP 4, thereby admitting Real-Time + Interactive traffic into the Video Access Category (AC_VI). + +4.2.5. Multimedia Streaming + + The Multimedia Streaming service class is recommended for + applications that require near-real-time packet forwarding of + variable-rate elastic traffic sources. Typically, these flows are + unidirectional. [RFC4594], Section 4.5, recommends Multimedia + Streaming traffic be marked AF3x (that is, AF31, AF32, and AF33, + according to the rules defined in [RFC2475]). + + The primary media type typically carried within the Multimedia + Streaming service class is video; as such, it is RECOMMENDED to map + this class into the Video Access Category (AC_VI), which it will by + default (as described in Section 2.3). Specifically, it is + RECOMMENDED to map AF31, AF32, and AF33 to UP 4, thereby admitting + Multimedia Streaming into the Video Access Category (AC_VI). + + + + +Szigeti, et al. Standards Track [Page 17] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +4.2.6. Broadcast Video + + The Broadcast Video service class is recommended for applications + that require near-real-time packet forwarding with very low packet + loss of constant rate and variable-rate inelastic traffic sources. + Typically these flows are unidirectional. [RFC4594] Section 4.6 + recommends Broadcast Video traffic be marked CS3 DSCP. + + As directly implied by the name, the primary media type typically + carried within the Broadcast Video service class is video; as such, + it is RECOMMENDED to map this class into the Video Access Category + (AC_VI); however, by default (as described in Section 2.3), this + service class will map to UP 3 and, thus, the Best Effort Access + Category (AC_BE). Therefore, a non-default mapping is RECOMMENDED, + such that CS4 maps to UP 4, thereby admitting Broadcast Video into + the Video Access Category (AC_VI). + +4.2.7. Low-Latency Data + + The Low-Latency Data service class is recommended for elastic and + time-sensitive data applications, often of a transactional nature, + where a user is waiting for a response via the network in order to + continue with a task at hand. As such, these flows are considered + foreground traffic, with delays or drops to such traffic directly + impacting user productivity. [RFC4594], Section 4.7, recommends + Low-Latency Data be marked AF2x (that is, AF21, AF22, and AF23, + according to the rules defined in [RFC2475]). + + By default (as described in Section 2.3), Low-Latency Data will map + to UP 2 and, thus, to the Background Access Category (AC_BK), which + is contrary to the intent expressed in [RFC4594]. + + Mapping Low-Latency Data to UP 3 may allow targeted traffic to + receive a superior level of service via per-UP transmit queues + servicing the EDCAF hardware for the Best Effort Access Category + (AC_BE), as described in Section 2.2. Therefore it is RECOMMENDED to + map Low-Latency Data traffic marked AF2x DSCP to UP 3, thereby + admitting it to the Best Effort Access Category (AC_BE). + +4.2.8. High-Throughput Data + + The High-Throughput Data service class is recommended for elastic + applications that require timely packet forwarding of variable-rate + traffic sources and, more specifically, is configured to provide + efficient, yet constrained (when necessary) throughput for TCP + longer-lived flows. These flows are typically not user interactive. + According to [RFC4594], Section 4.8, it can be assumed that this + class will consume any available bandwidth and that packets + + + +Szigeti, et al. Standards Track [Page 18] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + traversing congested links may experience higher queuing delays or + packet loss. It is also assumed that this traffic is elastic and + responds dynamically to packet loss. [RFC4594], Section 4.8, + recommends High-Throughput Data be marked AF1x (that is, AF11, AF12, + and AF13, according to the rules defined in [RFC2475]). + + By default (as described in Section 2.3), High-Throughput Data will + map to UP 1 and, thus, to the Background Access Category (AC_BK), + which is contrary to the intent expressed in [RFC4594]. + + Unfortunately, there really is no corresponding fit for the High- + Throughput Data service class within the constrained 4 Access + Category [IEEE.802.11-2016] model. If the High-Throughput Data + service class is assigned to the Best Effort Access Category (AC_BE), + then it would contend with Low-Latency Data (while [RFC4594] + recommends a distinction in servicing between these service classes) + as well as with the default service class; alternatively, if it is + assigned to the Background Access Category (AC_BK), then it would + receive a less-then-best-effort service and contend with Low-Priority + Data (as discussed in Section 4.2.10). + + As such, since there is no directly corresponding fit for the High- + Throughout Data service class within the [IEEE.802.11-2016] model, it + is generally RECOMMENDED to map High-Throughput Data to UP 0, thereby + admitting it to the Best Effort Access Category (AC_BE). + +4.2.9. Standard + + The Standard service class is recommended for traffic that has not + been classified into one of the other supported forwarding service + classes in the Diffserv network domain. This service class provides + the Internet's "best-effort" forwarding behavior. [RFC4594], + Section 4.9, states that the "Standard service class MUST use the + Default Forwarding (DF) PHB". + + The Standard service class loosely corresponds to the + [IEEE.802.11-2016] Best Effort Access Category (AC_BE); therefore, it + is RECOMMENDED to map Standard service class traffic marked DF DSCP + to UP 0, thereby admitting it to the Best Effort Access Category + (AC_BE). This happens to correspond to the default mapping (as + described in Section 2.3). + + + + + + + + + + +Szigeti, et al. Standards Track [Page 19] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +4.2.10. Low-Priority Data + + The Low-Priority Data service class serves applications that the user + is willing to accept without service assurances. This service class + is specified in [RFC3662] and [LE-PHB]. + + [RFC3662] and [RFC4594] both recommend Low-Priority Data be marked + CS1 DSCP. + + Note: This marking recommendation may change in the future, as + [LE-PHB] defines a Lower Effort (LE) PHB for Low-Priority Data + traffic and recommends an additional DSCP for this traffic. + + The Low-Priority Data service class loosely corresponds to the + [IEEE.802.11-2016] Background Access Category (AC_BK); therefore, it + is RECOMMENDED to map Low-Priority Data traffic marked CS1 DSCP to UP + 1, thereby admitting it to the Background Access Category (AC_BK). + This happens to correspond to the default mapping (as described in + Section 2.3). + +4.3. Summary of Recommendations for DSCP-to-UP Mapping + + Figure 1 summarizes the [RFC4594] DSCP marking recommendations mapped + to [IEEE.802.11-2016] UP and Access Categories applied in the + downstream direction (i.e., from wired-to-wireless networks). + + +-------------------------------------------------------------------+ + | IETF Diffserv | PHB |Reference | IEEE 802.11 | + | Service Class | | RFC |User Priority| Access Category | + |===============+======+==========+=============+====================| + | | | | 7 | AC_VO (Voice) | + |Network Control| CS7 | RFC 2474 | OR | + |(reserved for | | | 0 | AC_BE (Best Effort)| + | future use) | | |See Security Considerations-Sec.8 | + +---------------+------+----------+-------------+--------------------+ + | | | | 7 | AC_VO (Voice) | + |Network Control| CS6 | RFC 2474 | OR | + | | | | 0 | AC_BE (Best Effort)| + | | | | See Security Considerations | + +---------------+------+----------+-------------+--------------------+ + | Telephony | EF | RFC 3246 | 6 | AC_VO (Voice) | + +---------------+------+----------+-------------+--------------------+ + | VOICE-ADMIT | VA | RFC 5865 | 6 | AC_VO (Voice) | + | | | | | | + +---------------+------+----------+-------------+--------------------+ + | Signaling | CS5 | RFC 2474 | 5 | AC_VI (Video) | + + + + + +Szigeti, et al. Standards Track [Page 20] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + +---------------+------+----------+-------------+--------------------+ + | Multimedia | AF41 | | | | + | Conferencing | AF42 | RFC 2597 | 4 | AC_VI (Video) | + | | AF43 | | | | + +---------------+------+----------+-------------+--------------------+ + | Real-Time | CS4 | RFC 2474 | 4 | AC_VI (Video) | + | Interactive | | | | | + +---------------+------+----------+-------------+--------------------+ + | Multimedia | AF31 | | | | + | Streaming | AF32 | RFC 2597 | 4 | AC_VI (Video) | + | | AF33 | | | | + +---------------+------+----------+-------------+--------------------+ + |Broadcast Video| CS3 | RFC 2474 | 4 | AC_VI (Video) | + +---------------+------+----------+-------------+--------------------+ + | Low- | AF21 | | | | + | Latency | AF22 | RFC 2597 | 3 | AC_BE (Best Effort)| + | Data | AF23 | | | | + +---------------+------+----------+-------------+--------------------+ + | OAM | CS2 | RFC 2474 | 0 | AC_BE (Best Effort)| + +---------------+------+----------+-------------+--------------------+ + | High- | AF11 | | | | + | Throughput | AF12 | RFC 2597 | 0 | AC_BE (Best Effort)| + | Data | AF13 | | | | + +---------------+------+----------+-------------+--------------------+ + | Standard | DF | RFC 2474 | 0 | AC_BE (Best Effort)| + +---------------+------+----------+-------------+--------------------+ + | Low-Priority | CS1 | RFC 3662 | 1 | AC_BK (Background) | + | Data | | | | | + +--------------------------------------------------------------------+ + + Note: All unused codepoints are RECOMMENDED to be mapped to UP 0 + (See Security Considerations below) + + Figure 1: Summary of Mapping Recommendations from Downstream + DSCP to IEEE 802.11 UP and AC + +5. Recommendations for Upstream Mapping and Marking + + In the upstream direction (i.e., wireless-to-wired), there are three + types of mapping that may be implemented: + + o DSCP-to-UP mapping within the wireless client operating system, + and + + o UP-to-DSCP mapping at the wireless AP, or + + o DSCP-Passthrough at the wireless AP (effectively a 1:1 DSCP-to- + DSCP mapping) + + + +Szigeti, et al. Standards Track [Page 21] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + As an alternative to the latter two options, the network + administrator MAY choose to use the wireless-to-wired edge as a + Diffserv boundary and explicitly set (or reset) DSCP markings + according to administrative policy, thus making the wireless edge a + Diffserv policy enforcement point; this approach is RECOMMENDED + whenever the APs support the required classification and marking + capabilities. + + Each of these options will now be considered. + +5.1. Upstream DSCP-to-UP Mapping within the Wireless Client Operating + System + + Some operating systems on wireless client devices utilize a similar + default DSCP-to-UP mapping scheme as that described in Section 2.3. + As such, this can lead to the same conflicts as described in that + section, but in the upstream direction. + + Therefore, to improve on these default mappings, and to achieve + parity and consistency with downstream QoS, it is RECOMMENDED that + wireless client operating systems instead utilize the same DSCP-to-UP + mapping recommendations presented in Section 4. Note that it is + explicitly stated that packets requesting a marking of CS6 or CS7 + DSCP SHOULD be mapped to UP 0 (and not to UP 7). Furthermore, in + such cases, the wireless client operating system SHOULD re-mark such + packets to DSCP 0. This is because CS6 and CS7 DSCP, as well as UP 7 + markings, are intended for network control protocols, and these + SHOULD NOT be sourced from wireless client endpoint devices. This + recommendation is detailed in the Security Considerations section + (Section 8). + +5.2. Upstream UP-to-DSCP Mapping at the Wireless AP + + UP-to-DSCP mapping generates a DSCP value for the IP packet (either + an unencapsulated IP packet or an IP packet encapsulated within a + tunneling protocol such as Control and Provisioning of Wireless + Access Points (CAPWAP) -- and destined towards a wireless LAN + controller for decapsulation and forwarding) from the Layer 2 + [IEEE.802.11-2016] UP marking. This is typically done in the manner + described in Section 2.4. + + It should be noted that any explicit re-marking policy to be + performed on such a packet generally takes place at the nearest + classification and marking policy enforcement point, which may be: + + o At the wireless AP, and/or + + + + + +Szigeti, et al. Standards Track [Page 22] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + o At the wired network switch port, and/or + + o At the wireless LAN controller + + Note: Multiple classification and marking policy enforcement points + may exist, as some devices have the capability to re-mark at only + Layer 2 or Layer 3, while other devices can re-mark at either/both + layers. + + As such, UP-to-DSCP mapping allows for wireless L2 markings to affect + the QoS treatment of a packet over the wired IP network (that is, + until the packet reaches the nearest classification and marking + policy enforcement point). + + It should be further noted that nowhere in the [IEEE.802.11-2016] + specification is there an intent expressed for UP markings to be used + to influence QoS treatment over wired IP networks. Furthermore, + [RFC2474], [RFC2475], and [RFC8100] all allow for the host to set + DSCP markings for end-to-end QoS treatment over IP networks. + Therefore, wireless APs MUST NOT leverage Layer 2 [IEEE.802.11-2016] + UP markings as set by wireless hosts and subsequently perform a + UP-to-DSCP mapping in the upstream direction. But rather, if + wireless host markings are to be leveraged (as per business + requirements, technical constraints, and administrative policies), + then it is RECOMMENDED to pass through the Layer 3 DSCP markings set + by these wireless hosts instead, as is discussed in the next section. + +5.3. Upstream DSCP-Passthrough at the Wireless AP + + It is generally NOT RECOMMENDED to pass through DSCP markings from + unauthenticated and unauthorized devices, as these are typically + considered untrusted sources. + + When business requirements and/or technical constraints and/or + administrative policies require QoS markings to be passed through at + the wireless edge, then it is RECOMMENDED to pass through Layer 3 + DSCP markings (over Layer 2 [IEEE.802.11-2016] UP markings) in the + upstream direction, with the exception of CS6 and CS7 (as will be + discussed further), for the following reasons: + + o [RFC2474], [RFC2475], and [RFC8100] all allow for hosts to set + DSCP markings to achieve an end-to-end differentiated service + + o [IEEE.802.11-2016] does not specify that UP markings are to be + used to affect QoS treatment over wired IP networks + + + + + + +Szigeti, et al. Standards Track [Page 23] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + o Most present wireless device operating systems generate UP values + by the same method as described in Section 2.3 (i.e., by using the + 3 MSBs of the encapsulated 6-bit DSCP); then, at the AP, these + 3-bit markings are converted back into DSCP values, typically in + the default manner described in Section 2.4; as such, information + is lost in the translation from a 6-bit marking to a 3-bit marking + (which is then subsequently translated back to a 6-bit marking); + passing through the original (encapsulated) DSCP marking prevents + such loss of information + + o A practical implementation benefit is also realized by passing + through the DSCP set by wireless client devices, as enabling + applications to mark DSCP is much more prevalent and accessible to + programmers of applications running on wireless device platforms, + vis-a-vis trying to explicitly set UP values, which requires + special hooks into the wireless device operating system and/or + hardware device drivers, many of which do not support such + functionality + + CS6 and CS7 are exceptions to this passthrough recommendation because + wireless hosts SHOULD NOT use them (see Section 5.1) and traffic with + those two markings poses a threat to operation of the wired network + (see Section 8.2). CS6 and CS7 SHOULD NOT be passed through to the + wired network in the upstream direction unless the AP has been + specifically configured to do that by a network administrator or + operator. + +5.4. Upstream DSCP Marking at the Wireless AP + + An alternative option to mapping is for the administrator to treat + the wireless edge as the edge of the Diffserv domain and explicitly + set (or reset) DSCP markings in the upstream direction according to + administrative policy. This option is RECOMMENDED over mapping, as + this typically is the most secure solution because the network + administrator directly enforces the Diffserv policy across the IP + network (versus an application developer and/or the developer of the + operating system of the wireless endpoint device, who may be + functioning completely independently of the network administrator). + +6. Overview of IEEE 802.11 QoS + + QoS is enabled on wireless networks by means of the Hybrid + Coordination Function (HCF). To give better context to the + enhancements in HCF that enable QoS, it may be helpful to begin with + a review of the original Distributed Coordination Function (DCF). + + + + + + +Szigeti, et al. Standards Track [Page 24] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +6.1. Distributed Coordination Function (DCF) + + As has been noted, the Wi-Fi medium is a shared medium, with each + station -- including the wireless AP -- contending for the medium on + equal terms. As such, it shares the same challenge as any other + shared medium in requiring a mechanism to prevent (or avoid) + collisions, which can occur when two (or more) stations attempt + simultaneous transmission. + + The IEEE Ethernet Working Group solved this challenge by implementing + a Carrier Sense Multiple Access/Collision Detection (CSMA/CD) + mechanism that could detect collisions over the shared physical cable + (as collisions could be detected as reflected energy pulses over the + physical wire). Once a collision was detected, then a predefined set + of rules was invoked that required stations to back off and wait + random periods of time before reattempting transmission. While CSMA/ + CD improved the usage of Ethernet as a shared medium, it should be + noted the ultimate solution to solving Ethernet collisions was the + advance of switching technologies, which treated each Ethernet cable + as a dedicated collision domain. + + However, unlike Ethernet (which uses physical cables), collisions + cannot be directly detected over the wireless medium, as RF energy is + radiated over the air and colliding bursts are not necessarily + reflected back to the transmitting stations. Therefore, a different + mechanism is required for this medium. + + As such, the IEEE modified the CSMA/CD mechanism to adapt it to + wireless networks to provide Carrier Sense Multiple Access/Collision + Avoidance (CSMA/CA). The original CSMA/CA mechanism used in IEEE + 802.11 was the Distributed Coordination Function. DCF is a timer- + based system that leverages three key sets of timers, the slot time, + interframe spaces and CWs. + +6.1.1. Slot Time + + The slot time is the basic unit of time measure for both DCF and HCF, + on which all other timers are based. The slot-time duration varies + with the different generations of data rates and performances + described by [IEEE.802.11-2016]. For example, [IEEE.802.11-2016] + specifies the slot time to be 20 microseconds ([IEEE.802.11-2016], + Table 15-5) for legacy implementations (such as IEEE 802.11b, + supporting 1, 2, 5.5, and 11 Mbps data rates), while newer + implementations (including IEEE 802.11g, 802.11a, 802.11n, and + 802.11ac, supporting data rates from 6.5 Mbps to over 2 Gbps per + spatial stream) define a shorter slot time of 9 microseconds + ([IEEE.802.11-2016], Section 17.4.4, Table 17-21). + + + + +Szigeti, et al. Standards Track [Page 25] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +6.1.2. Interframe Space (IFS) + + The time interval between frames that are transmitted over the air is + called the Interframe Space (IFS). Several IFSs are defined in + [IEEE.802.11-2016], with the most relevant to DCF being the Short + Interframe Space (SIFS), the DCF Interframe Space (DIFS), and the + Extended Interframe Space (EIFS). + + The SIFS is the amount of time in microseconds required for a + wireless interface to process a received RF signal and its associated + frame (as specified in [IEEE.802.11-2016]) and to generate a response + frame. Like slot times, the SIFS can vary according to the + performance implementation of [IEEE.802.11-2016]. The SIFS for IEEE + 802.11a, 802.11n, and 802.11ac (in 5 GHz) is 16 microseconds + ([IEEE.802.11-2016], Section 17.4.4, Table 17-21). + + Additionally, a station must sense the status of the wireless medium + before transmitting. If it finds that the medium is continuously + idle for the duration of a DIFS, then it is permitted to attempt + transmission of a frame (after waiting an additional random backoff + period, as will be discussed in the next section). If the channel is + found busy during the DIFS interval, the station must defer its + transmission until the medium is found to be idle for the duration of + a DIFS interval. The DIFS is calculated as: + + DIFS = SIFS + (2 * Slot time) + + However, if all stations waited only a fixed amount of time before + attempting transmission, then collisions would be frequent. To + offset this, each station must wait, not only a fixed amount of time + (the DIFS), but also a random amount of time (the random backoff) + prior to transmission. The range of the generated random backoff + timer is bounded by the CW. + +6.1.3. Contention Window (CW) + + Contention windows bound the range of the generated random backoff + timer that each station must wait (in addition to the DIFS) before + attempting transmission. The initial range is set between 0 and the + CW minimum value (CWmin), inclusive. The CWmin for DCF (in 5 GHz) is + specified as 15 slot times ([IEEE.802.11-2016], Section 17.4.4, + Table 17-21). + + However, it is possible that two (or more) stations happen to pick + the exact same random value within this range. If this happens, then + a collision may occur. At this point, the stations effectively begin + the process again, waiting a DIFS and generate a new random backoff + value. However, a key difference is that for this subsequent + + + +Szigeti, et al. Standards Track [Page 26] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + attempt, the CW approximately doubles in size (thus, exponentially + increasing the range of the random value). This process repeats as + often as necessary if collisions continue to occur, until the maximum + CW size (CWmax) is reached. The CWmax for DCF is specified as 1023 + slot times ([IEEE.802.11-2016], Section 17.4.4, Table 17-21). + + At this point, transmission attempts may still continue (until some + other predefined limit is reached), but the CW sizes are fixed at the + CWmax value. + + Incidentally it may be observed that a significant amount of jitter + can be introduced by this contention process for wireless + transmission access. For example, the incremental transmission delay + of 1023 slot times (CWmax) using 9-microsecond slot times may be as + high as 9 ms of jitter per attempt. And, as previously noted, + multiple attempts can be made at CWmax. + +6.2. Hybrid Coordination Function (HCF) + + Therefore, as can be seen from the preceding description of DCF, + there is no preferential treatment of one station over another when + contending for the shared wireless media; nor is there any + preferential treatment of one type of traffic over another during the + same contention process. To support the latter requirement, the IEEE + enhanced DCF in 2005 to support QoS, specifying HCF in IEEE 802.11, + which was integrated into the main IEEE 802.11 standard in 2007. + +6.2.1. User Priority (UP) + + One of the key changes to the frame format in [IEEE.802.11-2016] is + the inclusion of a QoS Control field, with 3 bits dedicated for QoS + markings. These bits are referred to the User Priority (UP) bits and + these support eight distinct marking values: 0-7, inclusive. + + While such markings allow for frame differentiation, these alone do + not directly affect over-the-air treatment. Rather, it is the + non-configurable and standard-specified mapping of UP markings to the + Access Categories (ACs) from [IEEE.802.11-2016] that generate + differentiated treatment over wireless media. + + + + + + + + + + + + +Szigeti, et al. Standards Track [Page 27] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +6.2.2. Access Category (AC) + + Pairs of UP values are mapped to four defined access categories that + correspondingly specify different treatments of frames over the air. + These access categories (in order of relative priority from the top + down) and their corresponding UP mappings are shown in Figure 2 + (adapted from [IEEE.802.11-2016], Section 10.2.4.2, Table 10-1). + + +-----------------------------------------+ + | User | Access | Designative | + | Priority | Category | (informative) | + |===========+============+================| + | 7 | AC_VO | Voice | + +-----------+------------+----------------+ + | 6 | AC_VO | Voice | + +-----------+------------+----------------+ + | 5 | AC_VI | Video | + +-----------+------------+----------------+ + | 4 | AC_VI | Video | + +-----------+------------+----------------+ + | 3 | AC_BE | Best Effort | + +-----------+------------+----------------+ + | 0 | AC_BE | Best Effort | + +-----------+------------+----------------+ + | 2 | AC_BK | Background | + +-----------+------------+----------------+ + | 1 | AC_BK | Background | + +-----------------------------------------+ + + Figure 2: Mappings between IEEE 802.11 + Access Categories and User Priority + + The manner in which these four access categories achieve + differentiated service over-the-air is primarily by tuning the fixed + and random timers that stations have to wait before sending their + respective types of traffic, as will be discussed next. + + + + + + + + + + + + + + + +Szigeti, et al. Standards Track [Page 28] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +6.2.3. Arbitration Interframe Space (AIFS) + + As previously mentioned, each station must wait a fixed amount of + time to ensure the medium is idle before attempting transmission. + With DCF, the DIFS is constant for all types of traffic. However, + with [IEEE.802.11-2016], the fixed amount of time that a station has + to wait will depend on the access category and is referred to as an + Arbitration Interframe Space (AIFS). AIFSs are defined in slot times + and the AIFSs per access category are shown in Figure 3 (adapted from + [IEEE.802.11-2016], Section 9.4.2.29, Table 9-137). + + +-------------------------------------------+ + | Access | Designative | AIFS | + | Category | (informative) |(slot times)| + |============+=================+============| + | AC_VO | Voice | 2 | + +------------+-----------------+------------+ + | AC_VI | Video | 2 | + +------------+-----------------+------------+ + | AC_BE | Best Effort | 3 | + +------------+-----------------+------------+ + | AC_BK | Background | 7 | + +------------+-----------------+------------+ + + Figure 3: Arbitration Interframe Spaces by Access Category + +6.2.4. Access Category CWs + + Not only is the fixed amount of time that a station has to wait + skewed according to its [IEEE.802.11-2016] access category, but so + are the relative sizes of the CWs that bound the random backoff + timers, as shown in Figure 4 (adapted from [IEEE.802.11-2016], + Section 9.4.2.29, Table 9-137). + + +-------------------------------------------------------+ + | Access | Designative | CWmin | CWmax | + | Category | (informative) |(slot times)|(slot times)| + |===========+=================+============|============| + | AC_VO | Voice | 3 | 7 | + +-----------+-----------------+------------+------------+ + | AC_VI | Video | 7 | 15 | + +-----------+-----------------+------------+------------+ + | AC_BE | Best Effort | 15 | 1023 | + +-----------+-----------------+------------+------------+ + | AC_BK | Background | 15 | 1023 | + +-----------+-----------------+------------+------------+ + + Figure 4: CW Sizes by Access Category + + + +Szigeti, et al. Standards Track [Page 29] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + When the fixed and randomly generated timers are added together on a + per-access-category basis, then traffic assigned to the Voice Access + Category (i.e., traffic marked to UP 6 or 7) will receive a + statistically superior service relative to traffic assigned to the + Video Access Category (i.e., traffic marked UP 5 and 4), which, in + turn, will receive a statistically superior service relative to + traffic assigned to the Best Effort Access Category traffic (i.e., + traffic marked UP 3 and 0), which finally will receive a + statistically superior service relative to traffic assigned to the + Background Access Category traffic (i.e., traffic marked to UP 2 and + 1). + +6.3. IEEE 802.11u QoS Map Set + + IEEE 802.11u [IEEE.802-11u-2011] is an addendum that has now been + included within the main standard ([IEEE.802.11-2016]), and which + includes, among other enhancements, a mechanism by which wireless APs + can communicate DSCP to/from UP mappings that have been configured on + the wired IP network. Specifically, a QoS Map Set information + element (described in [IEEE.802.11-2016], Section 9.4.2.95, and + commonly referred to as the "QoS Map element") is transmitted from an + AP to a wireless endpoint device in an association / re-association + Response frame (or within a special QoS Map Configure frame). + + The purpose of the QoS Map element is to provide the mapping of + higher-layer QoS constructs (i.e., DSCP) to User Priorities. One + intended effect of receiving such a map is for the wireless endpoint + device (that supports this function and is administratively + configured to enable it) to perform corresponding DSCP-to-UP mapping + within the device (i.e., between applications and the operating + system / wireless network interface hardware drivers) to align with + what the APs are mapping in the downstream direction, so as to + achieve consistent end-to-end QoS in both directions. + + The QoS Map element includes two key components: + + 1) each of the eight UP values (0-7) is associated with a range of + DSCP values, and + + 2) (up to 21) exceptions from these range-based DSCP to/from UP + mapping associations may be optionally and explicitly specified. + + + + + + + + + + +Szigeti, et al. Standards Track [Page 30] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + In line with the recommendations put forward in this document, the + following recommendations apply when the QoS Map element is enabled: + + 1) each of the eight UP values (0-7) are RECOMMENDED to be mapped to + DSCP 0 (as a baseline, so as to meet the recommendation made in + Section 8.2, and + + 2) (up to 21) exceptions from this baseline mapping are RECOMMENDED + to be made in line with Section 4.3, to correspond to the + Diffserv Codepoints that are in use over the IP network. + + It is important to note that the QoS Map element is intended to be + transmitted from a wireless AP to a non-AP station. As such, the + model where this element is used is that of a network where the AP is + the edge of the Diffserv domain. Networks where the AP extends the + Diffserv domain by connecting other APs and infrastructure devices + through the IEEE 802.11 medium are not included in the cases covered + by the presence of the QoS Map element, and therefore are not + included in the present recommendation. + +7. IANA Considerations + + This document has no IANA actions. + +8. Security Considerations + + The recommendations in this document concern widely deployed wired + and wireless network functionality, and, for that reason, do not + present additional security concerns that do not already exist in + these networks. In fact, several of the recommendations made in this + document serve to protect wired and wireless networks from potential + abuse, as is discussed further in this section. + +8.1. Security Recommendations for General QoS + + It may be possible for a wired or wireless device (which could be + either a host or a network device) to mark packets (or map packet + markings) in a manner that interferes with or degrades existing QoS + policies. Such marking or mapping may be done intentionally or + unintentionally by developers and/or users and/or administrators of + such devices. + + To illustrate: A gaming application designed to run on a smartphone + or tablet may request that all its packets be marked DSCP EF and/or + UP 6. However, if the traffic from such an application is forwarded + without change over a business network, then this could interfere + with QoS policies intended to provide priority services for business + voice applications. + + + +Szigeti, et al. Standards Track [Page 31] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + To mitigate such scenarios, it is RECOMMENDED to implement general + QoS security measures, including: + + o Setting a traffic conditioning policy reflective of business + objectives and policy, such that traffic from authorized users + and/or applications and/or endpoints will be accepted by the + network; otherwise, packet markings will be "bleached" (i.e., + re-marked to DSCP DF and/or UP 0). Additionally, Section 5.3 made + it clear that it is generally NOT RECOMMENDED to pass through DSCP + markings from unauthorized and/or unauthenticated devices, as + these are typically considered untrusted sources. This is + especially relevant for Internet of Things (IoT) deployments, + where tens of billions of devices are being connected to IP + networks with little or no security capabilities, leaving them + vulnerable to be utilized as agents for DDoS attacks. These + attacks can be amplified with preferential QoS treatments, should + the packet markings of such devices be trusted. + + o Policing EF marked packet flows, as detailed in [RFC2474], + Section 7, and [RFC3246], Section 3. + + In addition to these general QoS security recommendations, WLAN- + specific QoS security recommendations can serve to further mitigate + attacks and potential network abuse. + +8.2. Security Recommendations for WLAN QoS + + The wireless LAN presents a unique DoS attack vector, as endpoint + devices contend for the shared media on a completely egalitarian + basis with the network (as represented by the AP). This means that + any wireless client could potentially monopolize the air by sending + packets marked to preferred UP values (i.e., UP values 4-7) in the + upstream direction. Similarly, airtime could be monopolized if + excessive amounts of downstream traffic were marked/mapped to these + same preferred UP values. As such, the ability to mark/map to these + preferred UP values (of UP 4-7) should be controlled. + + If such marking/mapping were not controlled, then, for example, a + malicious user could cause WLAN DoS by flooding traffic marked CS7 + DSCP downstream. This codepoint would map by default (as described + in Section 2.3) to UP 7 and would be assigned to the Voice Access + Category (AC_VO). Such a flood could cause Denial-of-Service to not + only wireless voice applications, but also to all other traffic + classes. Similarly, an uninformed application developer may request + all traffic from his/her application be marked CS7 or CS6, thinking + this would achieve the best overall servicing of their application + traffic, while not realizing that such a marking (if honored by the + client operating system) could cause not only WLAN DoS, but also IP + + + +Szigeti, et al. Standards Track [Page 32] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + network instability, as the traffic marked CS7 or CS6 finds its way + into queues intended for servicing (relatively low-bandwidth) network + control protocols, potentially starving legitimate network control + protocols in the process. + + Therefore, to mitigate such an attack, it is RECOMMENDED that all + packets marked to Diffserv Codepoints not authorized or explicitly + provisioned for use over the wireless network by the network + administrator be mapped to UP 0; this recommendation applies both at + the AP (in the downstream direction) and within the operating system + of the wireless endpoint device (in the upstream direction). + + Such a policy of mapping unused codepoints to UP 0 would also prevent + an attack where non-standard codepoints were used to cause WLAN DoS. + Consider the case where codepoints are mapped to UP values using a + range function (e.g., DSCP values 48-55 all map to UP 6), then an + attacker could flood packets marked, for example, to DSCP 49, in + either the upstream or downstream direction over the WLAN, causing + DoS to all other traffic classes in the process. + + In the majority of WLAN deployments, the AP represents not only the + edge of the Diffserv domain, but also the edge of the network + infrastructure itself; that is, only wireless client endpoint devices + are downstream from the AP. In such a deployment model, CS6 and CS7 + also fall into the category of codepoints that are not in use over + the wireless LAN (since only wireless client endpoint devices are + downstream from the AP in this model and these devices do not + (legitimately) participate in network control protocol exchanges). + As such, it is RECOMMENDED that CS6 and CS7 DSCP be mapped to UP 0 in + these Wi-Fi-at-the-edge deployment models. Otherwise, it would be + easy for a malicious application developer, or even an inadvertently + poorly programmed IoT device, to cause WLAN DoS and even wired IP + network instability by flooding traffic marked CS6 DSCP, which would, + by default (as described in Section 2.3), be mapped to UP 6, causing + all other traffic classes on the WLAN to be starved, as well as + hijacking queues on the wired IP network that are intended for the + servicing of routing protocols. To this point, it was also + recommended in Section 5.1 that packets requesting a marking of CS6 + or CS7 DSCP SHOULD be re-marked to DSCP 0 and mapped to UP 0 by the + wireless client operating system. + + Finally, it should be noted that the recommendations put forward in + this document are not intended to address all attack vectors + leveraging QoS marking abuse. Mechanisms that may further help + mitigate security risks of both wired and wireless networks deploying + QoS include strong device- and/or user-authentication, access- + control, rate-limiting, control-plane policing, encryption, and other + techniques; however, the implementation recommendations for such + + + +Szigeti, et al. Standards Track [Page 33] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + mechanisms are beyond the scope of this document to address in + detail. Suffice it to say that the security of the devices and + networks implementing QoS, including QoS mapping between wired and + wireless networks, merits consideration in actual deployments. + +9. References + +9.1. Normative References + + [IEEE.802.11-2016] + IEEE, "IEEE Standard for Information technology - + Telecommunications and information exchange between + systems - Local and metropolitan area networks - Specific + requirements - Part 11: Wireless LAN Medium Access Control + (MAC) and Physical Layer (PHY) Specifications", + IEEE 802.11, DOI 10.1109/IEEESTD.2016.7786995, December + 2016, . + + [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate + Requirement Levels", BCP 14, RFC 2119, + DOI 10.17487/RFC2119, March 1997, + . + + [RFC2474] Nichols, K., Blake, S., Baker, F., and D. Black, + "Definition of the Differentiated Services Field (DS + Field) in the IPv4 and IPv6 Headers", RFC 2474, + DOI 10.17487/RFC2474, December 1998, + . + + [RFC2597] Heinanen, J., Baker, F., Weiss, W., and J. Wroclawski, + "Assured Forwarding PHB Group", RFC 2597, + DOI 10.17487/RFC2597, June 1999, + . + + [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, + . + + [RFC3246] Davie, B., Charny, A., Bennet, J., Benson, K., Le Boudec, + J., Courtney, W., Davari, S., Firoiu, V., and D. + Stiliadis, "An Expedited Forwarding PHB (Per-Hop + Behavior)", RFC 3246, DOI 10.17487/RFC3246, March 2002, + . + + + + + + +Szigeti, et al. Standards Track [Page 34] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + [RFC3662] Bless, R., Nichols, K., and K. Wehrle, "A Lower Effort + Per-Domain Behavior (PDB) for Differentiated Services", + RFC 3662, DOI 10.17487/RFC3662, December 2003, + . + + [RFC4594] Babiarz, J., Chan, K., and F. Baker, "Configuration + Guidelines for DiffServ Service Classes", RFC 4594, + DOI 10.17487/RFC4594, August 2006, + . + + [RFC5865] Baker, F., Polk, J., and M. Dolly, "A Differentiated + Services Code Point (DSCP) for Capacity-Admitted Traffic", + RFC 5865, DOI 10.17487/RFC5865, May 2010, + . + + [RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC + 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, + May 2017, . + +9.2. Informative References + + [GSMA-IPX_Guidelines] + GSM Association, "Guidelines for IPX Provider networks + (Previously Inter-Service Provider IP Backbone Guidelines) + Version 11.0", Official Document IR.34, November 2014, + . + + [IEEE.802-11u-2011] + IEEE, "IEEE Standard for Information technology - + Telecommunications and information exchange between + systems - Local and metropolitan area networks - Specific + requirements - Part 11: Wireless LAN Medium Access Control + (MAC) and Physical Layer (PHY) specifications: Amendment + 9: Interworking with External Networks", IEEE 802.11, + DO 10.1109/IEEESTD.2011.5721908, February 2011, + . + + [LE-PHB] Bless, R., "A Lower Effort Per-Hop Behavior (LE PHB)", + Work in Progress, draft-ietf-tsvwg-le-phb-02, June 2017. + + [RFC2475] Blake, S., Black, D., Carlson, M., Davies, E., Wang, Z., + and W. Weiss, "An Architecture for Differentiated + Services", RFC 2475, DOI 10.17487/RFC2475, December 1998, + . + + + + + +Szigeti, et al. Standards Track [Page 35] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + + [RFC5127] Chan, K., Babiarz, J., and F. Baker, "Aggregation of + Diffserv Service Classes", RFC 5127, DOI 10.17487/RFC5127, + February 2008, . + + [RFC7561] Kaippallimalil, J., Pazhyannur, R., and P. Yegani, + "Mapping Quality of Service (QoS) Procedures of Proxy + Mobile IPv6 (PMIPv6) and WLAN", RFC 7561, + DOI 10.17487/RFC7561, June 2015, + . + + [RFC8100] Geib, R., Ed. and D. Black, "Diffserv-Interconnection + Classes and Practice", RFC 8100, DOI 10.17487/RFC8100, + March 2017, . + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Szigeti, et al. Standards Track [Page 36] + +RFC 8325 Mapping Diffserv to IEEE 802.11 February 2018 + + +Acknowledgements + + The authors wish to thank David Black, Gorry Fairhurst, Ruediger + Geib, Vincent Roca, Brian Carpenter, David Blake, Cullen Jennings, + David Benham, and the TSVWG. + + The authors also acknowledge a great many inputs, notably from David + Kloper, Mark Montanez, Glen Lavers, Michael Fingleton, Sarav + Radhakrishnan, Karthik Dakshinamoorthy, Simone Arena, Ranga Marathe, + Ramachandra Murthy, and many others. + +Authors' Addresses + + Tim Szigeti + Cisco Systems + Vancouver, British Columbia V6K 3L4 + Canada + + Email: szigeti@cisco.com + + + Jerome Henry + Cisco Systems + Research Triangle Park, North Carolina 27709 + United States of America + + Email: jerhenry@cisco.com + + + Fred Baker + Santa Barbara, California 93117 + United States of America + + Email: FredBaker.IETF@gmail.com + + + + + + + + + + + + + + + + + +Szigeti, et al. Standards Track [Page 37] + -- cgit v1.2.3