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/rfc2381.txt | 2411 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 2411 insertions(+) create mode 100644 doc/rfc/rfc2381.txt (limited to 'doc/rfc/rfc2381.txt') diff --git a/doc/rfc/rfc2381.txt b/doc/rfc/rfc2381.txt new file mode 100644 index 0000000..513fcb3 --- /dev/null +++ b/doc/rfc/rfc2381.txt @@ -0,0 +1,2411 @@ + + + + + + +Network Working Group M. Garrett +Request for Comments: 2381 Bellcore +Category: Standards Track M. Borden + Bay Networks + August 1998 + + + Interoperation of Controlled-Load Service + and Guaranteed Service with ATM + +Status of this Memo + + This document specifies an Internet standards track protocol for the + Internet community, and requests discussion and suggestions for + improvements. Please refer to the current edition of the "Internet + Official Protocol Standards" (STD 1) for the standardization state + and status of this protocol. Distribution of this memo is unlimited. + +Copyright Notice + + Copyright (C) The Internet Society (1998). All Rights Reserved. + +Abstract + + This document provides guidelines for mapping service classes, and + traffic management features and parameters between Internet and ATM + technologies. The service mappings are useful for providing + effective interoperation and end-to-end Quality of Service for IP + Integrated Services networks containing ATM subnetworks. + + The discussion and specifications given here support the IP + integrated services protocols for Guaranteed Service (GS), + Controlled-Load Service (CLS) and the ATM Forum UNI specification, + versions 3.0, 3.1 and 4.0. Some discussion of IP best effort service + over ATM is also included. + + The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", + "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this + document are to be interpreted as described in RFC 2119 [1]. (Note, + in many cases the use of "MUST" or "REQUIRED" reflects our + interpretation of the requirements of a related standard, e.g., ATM + Forum UNI 4.0, rsvp, etc.) + + + + + + + + + +Garrett & Borden Standards Track [Page 1] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + +Table of Contents + +1.0 Introduction .................................................... 3 + 1.1 General System Architecture ................................. 4 + 1.2 Related Documents ........................................... 7 +2.0 Major Protocol Features for Traffic Management and QoS .......... 8 + 2.1 Service Category and Bearer Capability ...................... 8 + 2.1.1 Service Categories for Guaranteed Service ............. 9 + 2.1.2 Service Categories for Controlled Load ................ 10 + 2.1.3 Service Categories for Best Effort .................... 11 + 2.2 Cell Loss Priority Bit, Tagging and Conformance Definitions . 11 + 2.3 ATM Adaptation Layer ........................................ 13 + 2.4 Broadband Low Layer Information ............................. 13 + 2.5 Traffic Descriptors ......................................... 13 + 2.5.1 Translating Traffic Descriptors for Guaranteed Service. 15 + 2.5.2 Translating Traffic Descriptors for Controlled Load + Service .............................................. 18 + 2.5.3 Translating Traffic Descriptors for Best Effort Service 19 + 2.6 QoS Classes and Parameters .................................. 19 + 2.7 Additional Parameters -- Frame Discard Mode ................. 22 +3.0 Additional IP-Integrated Services Protocol Features ............. 22 + 3.1 Path Characterization Parameters for IP Integrated Services . 22 + 3.2 Handling of Excess Traffic .................................. 24 + 3.3 Use of Guaranteed Service Adspec Parameters and Slack Term .. 25 +4.0 Miscellaneous Items ............................................. 26 + 4.1 Units Conversion ............................................ 26 +5.0 Summary of ATM VC Setup Parameters for Guaranteed Service ....... 27 + 5.1 Encoding GS Using Real-Time VBR ............................. 28 + 5.2 Encoding GS Using CBR ....................................... 29 + 5.3 Encoding GS Using Non-Real-Time VBR ......................... 30 + 5.4 Encoding GS Using ABR ....................................... 30 + 5.5 Encoding GS Using UBR ....................................... 30 + 5.6 Encoding GS Using UNI 3.0 and UNI 3.1. ...................... 31 +6.0 Summary of ATM VC Setup Parameters for Controlled Load Service .. 32 + 6.1 Encoding CLS Using Non-Real-Time VBR ........................ 32 + 6.2 Encoding CLS Using ABR ...................................... 33 + 6.3 Encoding CLS Using CBR ...................................... 35 + 6.4 Encoding CLS Using Real-Time VBR ............................ 35 + 6.5 Encoding CLS Using UBR ...................................... 35 + 6.6 Encoding CLS Using UNI 3.0 and UNI 3.1. ..................... 35 +7.0 Summary of ATM VC Setup Parameters for Best Effort Service ...... 36 + 7.1 Encoding Best Effort Service Using UBR ...................... 37 +8.0 Security Considerations ......................................... 38 +9.0 Acknowledgements ................................................ 38 +Appendix 1 Abbreviations ........................................... 39 +References .......................................................... 40 +Authors' Addresses .................................................. 42 +Full Copyright Statement ............................................ 43 + + + +Garrett & Borden Standards Track [Page 2] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + +1.0 Introduction + + We consider the problem of providing IP Integrated Services [2] with + an ATM subnetwork. This document is intended to be consistent with + the rsvp protocol [3] for IP-level resource reservation, although it + applies also in the general case where GS and CLS services are + supported through other mechanisms. In the ATM network, we consider + ATM Forum UNI Signaling, versions 3.0, 3.1 and 4.0 [4, 5, 6]. The + latter uses the more complete service model of the ATM Forum's TM 4.0 + specification [7, 8]. + + This is a complex problem with many facets. In this document, we + focus on the service types, parameters and signalling elements needed + for service interoperation. The resulting service mappings can be + used to provide effective end-to-end Quality of Service (QoS) for IP + traffic that traverses ATM networks. + + The IP services considered are Guaranteed Service (GS) [9] and + Controlled Load Service (CLS) [10]. We also discuss the default Best + Effort Service (BE) in parallel with these. Our recommendations for + BE are intended to be consistent with RFC 1755 [11], and [12], which + define how ATM VCs can be used in support of normal BE IP service. + The ATM services we consider are: + + CBR Constant Bit Rate + rtVBR Real-time Variable Bit Rate + nrtVBR Non-real-time Variable Bit Rate + UBR Unspecified Bit Rate + ABR Available Bit Rate + + In the case of UNI 3.x signalling, where these service are not all + clearly distinguishable, we identify the appropriate available + services. + + We recommend the following service mappings, since they follow most + naturally from the service definitions: + + Guaranteed Service -> CBR or rtVBR + Controlled Load -> nrtVBR or ABR (with a minimum + cell rate) + Best Effort -> UBR or ABR + + For completeness, however, we provide detailed mappings for all + service combinations in Sections 5, 6, 7 and identify how each meets + or fails to meet the requirements of the higher level IP services. + The reason for not restricting mappings to the most obvious or + natural ones is that we cannot predict how widely available all of + these services will be as ATM deployment evolves. A number of + + + +Garrett & Borden Standards Track [Page 3] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + differences in service definitions, such as the treatment of packets + in excess of the flow traffic descriptor, make service mapping a + relatively complicated subject. + + The remainder of this introduction provides a general discussion of + the system configuration and other assumptions. Section 2 considers + the relevant ATM protocol elements and the corresponding features of + Guaranteed, Controlled Load and Best Effort services (the latter + being the default "service"). Section 3 discusses a number of + remaining features of the IP services and how they can be handled on + an ATM subnetwork. Section 4 addresses the conversion of traffic + descriptors to account for ATM-layer overheads. Section 5 gives the + detailed VC setup parameters for Guaranteed Service, and considers + the effect of using each of the ATM service categories. Section 6 + provides a similar treatment for Controlled Load Service. Section 7 + considers Best Effort service. + + This document is only a part of the total solution to providing the + interworking of IP integrated services with ATM subnetworks. The + important issue of VC management, including flow aggregation, is + considered in [13, 14, 15]. We do not consider how routing, QoS + sensitive or not, interacts with the use of ATM VCs. We expect that + a considerable degree of implementation latitude will exist, even + within the guidelines presented here. Many aspects of interworking + between IP and ATM will depend on economic factors, and will not be + subject to standardization. + +1.1 General System Architecture + + We assume that the reader has a general working knowledge of IP, rsvp + and ATM protocols. The network architecture we consider is + illustrated in Figure 1. An IP-attached host may send unicast + datagrams to another host, or may use an IP multicast address to send + packets to all of the hosts which have "joined" the multicast "tree". + In either case, a destination host may then use RSVP to establish + resource reservation in routers along the internet path for the data + flow. + + An ATM network lies in the path (chosen by the IP routing), and + consists of one or more ATM switches. It uses SVCs to provide both + resources and QoS within the ATM cloud. These connections are set + up, added to (in the case of multipoint trees), torn down, and + controlled by the edge devices, which act as both IP routers and ATM + interfaces, capable of initiating and managing VCs across the ATM + user-to-network (UNI) interface. The edge devices are assumed to be + fully functional in both the IP int-serv/RSVP protocols and the ATM + UNI protocols, as well as translating between them. + + + + +Garrett & Borden Standards Track [Page 4] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + ATM Cloud + ----------------- + H ----\ ( ) /------- H + H ---- R -- R -- E-( X -- X -- X )-E -- R -- R -- H + H ----/ | ( ) \ + | ----------------- \------ H + H ----------R + + Figure 1: Network Architecture with Hosts (H), + Routers (R), Edge Devices (E) and ATM + Switches (X). + + + When considering the edge devices with respect to traffic flowing + from source to destination, the upstream edge device is called the + "ingress" point and the downstream device the "egress" point. The + edge devices may be considered part of the IP internet or part of the + ATM cloud, or both. They process RSVP messages, reserve resources, + and maintain soft state (in the control path), and classify and + schedule packets (in the data path). They also initiate ATM + connections by signalling, and accept or refuse connections signalled + to them. They police and schedule cells going into the ATM cloud. + The service mapping function occurs when an IP-level reservation + (RESV message) triggers the edge device to translate the RSVP service + requirements into ATM VC (UNI) semantics. + + A range of VC management policies are possible, which determine + whether a flow initiates a new VC or joins an existing one. VCs are + managed according to a combination of standards and local policy + rules, which are specific to either the implementation (equipment) or + the operator (network service provider). Point-to-multipoint + connections within the ATM cloud can be used to support general IP + multicast flows. In ATM, a point to multipoint connection can be + controlled by the source (or root) node, or a leaf initiated join + (LIJ) feature in ATM may be used. The topic of VC management is + considered at length in other ISSLL documents [13, 14, 15]. + + Figure 2 shows the functions of an edge device, summarizing the work + not part of IP or ATM abstractly as an InterWorking Function (IWF), + and segregating the control and data planes. + + + + + + + + + + + +Garrett & Borden Standards Track [Page 5] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + IP ATM + ____________________ + | IWF | + | | + admission and <--> | service mapping | <--> ATM + policy control | VC management | signalling & + | address resolution | admission + |....................| control + | | + classification, |ATM Adaptation Layer| cell + policing & <--> | Segmentation and | <--> scheduling/ + scheduling | Reassembly | shaping + | Buffering | + ____________________ + + Figure 2: Edge Device Functions showing the IWF + + + In the logical view of Figure 2, some functions, such as scheduling, + are shown separately, since these functions are present on both the + IP and ATM sides. However it may be possible in an integrated + implementation to combine such functions. + + The service mapping and VC management functions can be highly + interdependent. For example: (i) Multiple integrated-services flows + may be aggregated to use one point-to-multipoint VC. In this case, + we assume the IP flows are of the same service type and their + parameters have been merged appropriately. (ii) The VC management + function may choose to allocate extra resources in anticipation of + further reservations or based on an empiric of changing TSpecs. + (iii) There MUST exist a path for best effort flows and for sending + the rsvp control messages. How this interacts with the establishment + of VCs for QoS traffic may alter the desired characteristics of those + VCs. See [13, 14, 15] for further details on VC management. + + Therefore, in discussing the service mapping problem, we will assume + that the VC management function of the IWF can always express its + result in terms of an IP-level service with some QoS and TSpec. The + service mapping algorithm can then identify the appropriate VC + parameters as if a new VC were to be created for this service. The + VC management function can then use this information consistent with + its own policy, which determines whether the resulting action uses + new or existing VCs. + + + + + + + + +Garrett & Borden Standards Track [Page 6] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + +1.2 Related Documents + + Earlier ATM Forum documents combined signalling, traffic management + and other areas into a single document, e.g., UNI 3.0 [4] and UNI 3.1 + [5]. The 3.1 release was used to correct errors and fix alignment + with the ITU. While UNI 3.0 and 3.1 are incompatible in terms of + actual codepoints, the semantics are generally the same. Therefore, + we will often refer to UNI 3.x to mean either version of the ATM + protocol. + + After 3.1, the ATM Forum released documents separately for each + technical working group. The UNI Signalling 4.0 [6] and Traffic + Management 4.0 [7] documents represent a consistent overall ATM + protocol, and we will sometime refer to the combination as TM/UNI + 4.0. + + Within the IETF, related material includes the work of the rsvp [3], + int-serv [2, 9, 10, 16, 17] and ion working groups [11, 12]. Rsvp + defines the resource reservation protocol (which is analogous to + signalling in ATM). Int-serv defines the behavior and semantics of + particular services (analogous to the Traffic Management working + group in the ATM Forum). Ion defines interworking of IP and ATM for + traditional Best Effort service, and generally covers issues related + to IP/ATM routing and addressing. + + A large number of ATM signalling details are covered in RFC 1755 + [10]; e.g., differences between UNI 3.0 and UNI 3.1, encapsulation, + frame-relay interworking, etc. These considerations extend to IP + over ATM with QoS as well. The description given in this document of + IP Best Effort service (i.e. the default behavior) over ATM is + intended to be consistent with RFC 1755 and it's extension for UNI + 4.0 [11], and those documents are to be considered definitive. For + non-best-effort services, certain IP/ATM features will diverge from + the following RFC 1755. We have attempted to note such differences + explicitly. (For example, best effort VCs may be taken down on + timeout by either edge device, while QoS VCs are only removed by the + upstream edge device when the corresponding rsvp reservation is + deleted.) + + Another related document is RFC 1821 [17], which represents an early + discussion of issues involved with interoperating IP and ATM + protocols for integrated services and QoS. + + + + + + + + + +Garrett & Borden Standards Track [Page 7] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + +2.0 Major Protocol Features for Traffic Management and QoS + + The ATM Call Setup is sent by the ingress edge device to the ATM + network to establish end-to-end (ATM) service. This setup contains + the following information. + + Service Category/Broadband Bearer Capability + AAL Parameters + Broadband Low Layer Information + Calling and Called Party Addressing Information + Traffic Descriptors + QoS Class and/or Parameters + Additional Parameters of TM/UNI 4.0 + + In this section, we discuss each of these items as they relate to + creating ATM VCs suitable for GS, CLS and BE services. We do not + discuss routing and addressing at all, since they are (at least + presently) independent of QoS. Following the section on service + categories, we discuss tagging and conformance definitions for IP and + ATM. These do not appear explicitly as set-up parameters in the + above list, since they are implied by the policing method used. + +2.1 Service Category and Bearer Capability + + The highest level of abstraction distinguishing features of ATM VCs + is in the service category or bearer capability. Service categories + were introduced in TM/UNI 4.0; previously the bearer capability was + used to discriminate at this level. + + These elements indicate the general properties of a VC: whether there + is a real-time delay constraint, whether the traffic is constant or + variable rate, the applicable traffic and QoS description parameters + and (implicitly) the complexity of some supporting switch mechanisms + (e.g., ABR). + + For UNI 3.0 and UNI 3.1, there are only two distinct options for + bearer capabilities (in our context): + + BCOB-A: constant rate, timing required, unicast/multipoint; + BCOB-C: variable rate, timing not required, unicast/multipoint. + + A third capability, BCOB-X, can be used as a substitute for the above + two capabilities, with its dependent parameters (traffic type and + timing requirement) set appropriately. The distinction between the + BCOB-X formulation and the "equivalent" (for our purposes) BCOB-A and + BCOB-C constructs is whether the ATM network is to provide pure cell + relay service or interwork with other technologies (with + interoperable signalling), such as narrowband ISDN. Where this + + + +Garrett & Borden Standards Track [Page 8] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + distinction is applicable, the appropriate code SHOULD be used (see + [5] and related ITU specs, e.g., I.371). + + In TM/UNI 4.0 the service categories are: + + Constant Bit Rate (CBR) + Real-time Variable Bit Rate (rtVBR) + Non-real-time Variable Bit Rate (nrtVBR) + Unspecified Bit Rate (UBR) + Available Bit Rate (ABR) + + The first two of these are real-time services, so that rtVBR is new + to TM/UNI 4.0. The ABR service is also new to TM/UNI 4.0. UBR + exists in all specifications, although it is called "best effort" in + UNI 3.x. In either case it is indicated by the "best effort" + indication flag (and the QoS Class set to 0). + + The Service Category in TM/UNI 4.0 is encoded into the same signalled + Information Element (IE) as the Bearer Capability in UNI 3.x, for the + purpose of backward compatibilty. Thus, we use the convention of + referring to Service Category (CBR, rtVBR, nrtVBR, UBR, ABR) for + TM/UNI 4.0 (where the bearer capability is implicit). When we refer + to the Bearer Capability explicitly (BCOB-A, BCOB-C, BCOB-X), we are + describing a UNI 3.x signalling message. + + In principle, it is possible to support any service through the use + of BCOB-A/CBR. This is because the CBR service is equivalent to + having a "pipe" of a specified bandwidth. However, it may be + significantly more efficient to use the other ATM services where + applicable and available [17]. + +2.1.1 Service Categories for Guaranteed Service + + There are two possible mappings for GS: + + CBR (BCOB-A) + rtVBR + + Real-time support is REQUIRED for GS. Thus in UNI 3.x, the Bearer + Class BCOB-A (or an equivalent BCOB-X formulation) MUST be used. In + TM/UNI 4.0 either CBR or rtVBR is appropriate. The use of rtVBR may + encourage recovery of allocated bandwidth left unused by a source. + It also accommodates more bursty sources with a larger token bucket + burst parameter, and permits the use of tagging for excess traffic + (see Section 2.2). + + + + + + +Garrett & Borden Standards Track [Page 9] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + Neither the BCOB-C Bearer Class, nor nrtVBR, UBR, ABR are good + matches for the GS service. These provide no delay estimates and + cannot guarantee consistently low delay for every packet. + + For BCOB-A or CBR, specification of a peak cell rate (PCR) is + REQUIRED by ATM standards. In these cases, PCR is the nominal + clearing rate with a nominal jitter toleration (bucket size), CDVT. + + When rtVBR is specifed, two rates, PCR and SCR are REQUIRED (by ATM + standards). This models bursty traffic with specified peak and + sustainable rates. The corresponding ATM token bucket depth values + are CDVT, and CDVT+BT, respectively. + +2.1.2 Service Categories for Controlled Load + + There are three possible good mappings for CLS: + + CBR (BCOB-A) + nrtVBR (BCOB-C) + ABR + + Note that under UNI 3.x, there are equivalent services to CBR and + nrtVBR, but not ABR. The first, with a CBR/BCOB-A connection, + provides a higher level of QoS than is necessary, but it may be + convenient to simply allocate a fixed-rate "pipe", which we expect to + be ubiquitously supported in ATM networks. However unless this is + the only choice available, it would probably be wasteful of network + resources. + + The nrtVBR/BCOB-C category is perhaps the best match, since it + provides for allocation of bandwidth and buffers with an additional + peak rate indication, similar to the CLS TSpec. Excess traffic can + be handled by CLP bit tagging with VBR. + + The ABR category with a positive MCR aligns with the CLS idea of + "best effort with a floor." The ATM network agrees to forward cells + with a rate of at least MCR, which MUST be directly converted from + the token bucket rate of the receiver TSpec. The bucket size + parameter measures approximately the amount of buffer necessary at + the IWF. This buffer serves to absorb the bursts allowed by the + token bucket, since they cannot be passed directly into an ABR VC. + + The rtVBR category can be used, although the edge device MUST then + determine values for CTD and CDV. Since there are no corresponding + IP-level parameters, their values are set as a matter of local + policy. + + + + + +Garrett & Borden Standards Track [Page 10] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + The UBR category does not provide enough capability for Controlled + Load. The point of CLS is to allow an allocation of resources. This + is facilitated by the token bucket traffic descriptor, which is + unavailable with UBR. + +2.1.3 Service Categories for Best Effort + + All of the service categories have the capability to carry Best + Effort service, but the natural service category is UBR (or, in UNI + 3.x, BCOB-C or BCOB-X, with the best effort indication set). CBR or + rtVBR clearly could be used, and since the service is not real-time, + a nrtVBR connection could also be used. In these cases the rate + parameter used reflects a bandwidth allocation in support of the + ingress edge device's best effort connectivity to the egress edge + router. It would be normal for traffic from many source/destination + pairs to be aggregated on this connection; indeed, since Best Effort + is the default IP behavior, the individual flows are not normally + identified or accounted for. CBR may be a preferred solution in the + case where best effort traffic is sufficiently highly aggregated that + a simple fixed-rate pipe is efficient. Both CBR and nrt-VBR provide + explicit bandwidth allocation which may be useful for billing + purposes. In the case of UBR, the network operator SHOULD allocate + bandwidth for the overall service through the admission control + function, although such allocation is not done explicitly per VC. + + An ABR connection could similarly be used to support Best Effort + traffic. Indeed, the support of data communications protocols such + as TCP/IP is the explicit purpose for which ABR was designed. It is + conceivable that a separate ABR connection would be made for each IP + flow, although the normal case would probably have all IP Best Effort + traffic with a common egress router sharing a single ABR connection. + + The rt-VBR service category may be considered less suitable, simply + because both the real-time delay constraint and the use of SCR/BT add + unnecessary complexity. + + See specifications from the IETF ion working group [10, 11] for + related work on support of Best Effort service with ATM. + +2.2 Cell Loss Priority Bit, Tagging and Conformance Definitions + + Each ATM cell header carries a Cell Loss Priority (CLP) bit. Cells + with CLP=1 are said to be "tagged" or "marked" and have lower + priority. This tagging may be done by the source, to indicate + relative priority within the VC, or by a switch, to indicate traffic + in violation of policing parameters. Options involving the use of + tagging are decided at call setup time. + + + + +Garrett & Borden Standards Track [Page 11] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + A Conformance Definition is a rule that determines whether a cell is + conforming to the traffic descriptor of the VC. The conformance + definition is given in terms of a Generic Cell Rate Algorithm (GCRA), + also known as a "leaky bucket" algorithm, for CBR and VBR services. + The conformance definition also specifies rules for tagging traffic + in excess of the {SCR, MBS} GCRA traffic descriptor. (Note, the term + "compliance" in ATM is used to describe the behavior of a connection, + as opposed to "conformance", which applies to a single cell.) + + The network may tag cells that are non-conforming, rather than + dropping them if the VC set-up requests tagging and the network + supports the tagging option. When tagging is used and congestion + occurs, a switch MUST attempt to discard tagged cells in preference + to discarding CLP=0 cells. However, the mechanism for doing this is + completely implementation specific. The behavior that best meets the + requirements of IP Integrated Services is where tagged cells are + treated as "best effort" in the sense that they are transported when + bandwidth is available, queued when buffers are available, and + dropped when resources are overcommitted. ATM standards, however, do + not explicitly specify treatment of tagged traffic. Providers of GS + and CLS service with ATM subnetworks SHOULD ascertain the actual + behavior of ATM implementation with respect to tagged cells. + + Since GS and CLS services REQUIRE excess traffic to be treated as + best effort, the tagging option SHOULD always be chosen (if + supported) in the VC setup as a means of "downgrading" the cells + comprising non-conformant packets. The term "best effort" can be + interpreted in two ways. The first is as a service class that, for + example, may be implemented as a separate queue. The other sense is + more generic, meaning that the network makes a best effort to + transport the traffic. A reasonable interpretation of this is that a + network with no contending traffic would transport the packet, while + a very congested network would drop the packet. A mechanism that + tags best effort packets with lower loss priority (such as with the + ATM CLP bit) would drop some of these packets, but would not reorder + the remaining ones with respect to the conforming portion of the + flow. The "best effort" mechanism for excess traffic does not + necessarily have to be the same as that for best effort "service", as + long as it fits this generic sense of best effort. + + There are three conformance definitions of VBR service (for both + rtVBR and nrtVBR) to consider. In VBR, only the conformance + definition VBR.3 supports tagging and applies the GCRA with rate PCR + to the aggregate CLP=0+1 cells, and another GCRA with rate SCR to the + CLP=0 cells. This conformance definition SHOULD always be used with + a VBR service supporting IP integrated services. For UBR service, + conformance definition UBR.2 supports the use of tagging, but a CLP=1 + cell does not imply non-conformance; rather, it may be used by the + + + +Garrett & Borden Standards Track [Page 12] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + network to indicate congestion. + + In TM/UNI 4.0 tagging is not a feature of the conformance definitions + for the CBR or ABR service categories. (Since conformance + definitions are generally network specific, some implementations CBR + or ABR may, in fact, use tagging in some way.) Wherever an ATM + network does support tagging, in the sense of transporting CLP=1 + cells on a "best effort" basis, it is a useful and preferable + mechanism for handling excess traffic. + + It is always better for the IWF to tag cells when it can anticipate + that the ATM network would do so. This is because the IWF knows the + IP packet boundaries and can tag all of the cells corresponding to a + packet. If left to the ATM layer UPC, the network would inevitably + drop some of the cells of a packet while carrying others, which would + then be dropped by the receiver. Therefore, the IWF, knowing the VC + GCRA parameters, SHOULD always anticipate the cells which will be + tagged by the ATM UPC and tag all of the cells uniformly across each + affected packet. See Section 3.2 for further discussion of excess + traffic. + +2.3 ATM Adaptation Layer + + The AAL type 5 encoding SHOULD be used, as specified in RFC 1483 and + RFC 1755. For AAL-5, specification of the maximum SDU size in both + the forward and reverse directions is REQUIRED. Both GS and CLS + specify a maximum packet size, M, as part of the TSpec and this value + SHOULD be used (corrected for AAL headers) as the maximum SDU in each + direction for unicast connections, and for unidirectional point-to- + multipoint connections. When multiple flows are aggregated into a + single VC, the M parameters of the receiver TSpecs are merged + according to rules given in the GS and CLS specs. + +2.4 Broadband Low Layer Information + + The B-LLI Information Element is transferred transparently by the ATM + network between the edge devices and is used to specify the + encapsulation method. Multiple B-LLI IEs may be sent as part of + negotiation. The LLC/SNAP encapsulation [18] SHOULD be supported as + the default, but "null" or "VC encapsulation" MAY also be allowed. + Implementations SHOULD follow RFC 1577 [19] and RFC 1755 [10] for + BLLI usage. + +2.5 Traffic Descriptors + + The ATM traffic descriptor always contains a peak cell rate (PCR) + (for each direction). For VBR services it also contains a + sustainable cell rate (SCR) and maximum burst size (MBS). The SCR + + + +Garrett & Borden Standards Track [Page 13] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + and MBS form a leaky bucket pair (rate, depth), while the bucket + depth parameter for PCR is CDVT. Note that CDVT is not signalled + explicitly, but is determined by the network operator, and can be + viewed as a measure of the jitter imposed by the network. + + Since CDVT is generally presumed to be small (equivalent to a few + cells of token bucket depth), and cannot be set independently for + each connection, it cannot be used to account for the burstiness + permitted by b of the IP-layer TSpec. Additional buffering may be + needed at the IWF to account for the depth of the token bucket. + + The ATM Burst Tolerance (BT) is equivalent to MBS (see TM 4.0 [6] for + the exact equation). They are both expressions of the bucket depth + parameter associated with SCR. The units of BT are time while the + units of MBS are cells. Since both SCR and MBS are signalled, they + can be computed directly from the IP layer traffic description. The + specific manner in which resources are allocated from the traffic + description is implementation specific. Note that when translating + the traffic parameters, the segmentation overhead and minimum policed + unit need to be taken into account (see Section 4.1 below). + + In ATM UNI Signalling 4.0 there are the notions of Alternative + Traffic Descriptors and Minimal Traffic Descriptors. Alternative + Traffic Descriptors enumerate other acceptable choices for traffic + descriptors and are not considered here. Minimal Traffic Descriptors + are used in "negotiation," which refers to the specific way in which + an ATM connection is set up. To illustrate, roughly, taking PCR as + an example: A minimal PCR and a requested PCR are signalled, the + requested PCR being the usual item signalled, and the minimal PCR + being the absolute minimum that the source edge device will accept. + When both minimal and requested parameters are present, the + intermediate switches along the path may reduce the requested PCR to + a "comfortable" level. This choice is part of admission control, and + is therefore implementation specific. If at any point the requested + PCR falls below the minimal PCR then the call is cleared. Minimal + Traffic Descriptors can be used to present an acceptable range for + parameters and ensure a higher likelihood of call admission. In + general, our discussion of connection parameters assumes the values + resulting from successful connection setup. + + The Best Effort indicator (used only with UBR) and Tagging indicators + (see Section 2.2) are also part of the signalled information element + (IE) containing the traffic descriptor. In the UNI 4.0 traffic + descriptor IE there is an additional parameter, the Frame Discard + indicator, which is discussed below in Section 2.7. + + + + + + +Garrett & Borden Standards Track [Page 14] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + +2.5.1 Translating Traffic Descriptors for Guaranteed Service + + For Guaranteed Service the source TSpec contains peak rate, rate and + and bucket depth parameters, p_s, r_s, b_s. The receiver TSpec + contains corresponding parameters p_r, r_r, b_r. The (receiver) + RSpec also has a rate, R. The two different TSpec rates are intended + to support receiver heterogeneity, in the sense that receivers can + accept different rates representing different subsets of the sender's + traffic. Whenever rates from different receivers differ, the values + MUST always be merged appropriately before being mapping into ATM + parameters. + + Note that when the sender and receiver TSpec rates r_s, r_r differ, + there is no mechanism specified (in either rsvp or the int-serv + specs) for indicating which subset of the traffic is to be + transported. Implementation of this feature is therefore completely + network specific. The policing and scheduling mechanisms may simply + be parameterized with the (lower) receiver rate, resulting in the + random loss of traffic sufficient to make up the difference in rates. + + The receiver TSpec rate describes the traffic for which resources are + to be reserved, and may be used for policing, while the RSpec rate + (which cannot be smaller) is used (perhaps in an implementation + specific way) to modify the allocated service bandwidth in order to + reduce the delay. + + When mapping Guaranteed Service onto a rtVBR VC, the ATM traffic + descriptor parameters (PCR, SCR, MBS) can be set cannonically as: + + PCR = p_r + SCR = R + MBS = b_r. + + There are a number of conditions that may lead to different choices. + The following discussion is not intended to set hard requirements, + but to provide some interpretation and guidance on the bounds of + possible parameter mappings. The ingress edge device generally + includes a buffer preceding the ATM network interface. This buffer + can be used to absorb bursts that fall within the IP-level TSpec, but + not within the ATM traffic descriptor. The minimal REQUIREMENT for + guaranteed service is that the delay in this buffer MUST NOT exceed + b/R, and the delays within the ATM network MUST be accurately + accounted for in the values of Adspec parameters C and D advertised + by the ingress router (see Section 3.3 below). + + If either an edge device buffer of size b_r exists or the ATM maximum + burst size (MBS) parameter is at least b_r, then the various rate + parameters will generally exhibit the following relationship: + + + +Garrett & Borden Standards Track [Page 15] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + r_r <= SCR <= R <= PCR <= APB <= line rate + + r_r <= p_r <= APB + + APB refers to the General Characterization Parameter, + AVAILABLE_PATH_BANDWIDTH, which is negotiated in the Adspec portion + of the PATH message. APB reflects the narrowest bottleneck rate + along the path, and so is always no larger than the local line rate. + The receiver SHOULD choose a peak rate no greater than APB for the + reservation to be accepted, although the source peak rate, p_s, could + be higher, as the source does not know the value of APB. There is no + advantage to allocating any rate above APB of course, so it is an + upper bound for all the other parameters. + + We might normally expect to find R <= p_r, as would be necessary for + the simple mapping of PCR = p_r, SCR = R given above. However, a + receiver is free to choose R > p_r to lower the GS delay [8]. In + this case, PCR cannot be set below R, because a burst of size b + arriving into the buffer MUST be cleared at rate R to keep the first + component of GS delay down to b/R. So here we will have PCR = R. It + may seem that PCR = p_r would be sufficient to avoid buffer overflow, + since data is generated at the source at a rate bounded by p_r. + However, setting PCR < R, can result in the delay bound advertised by + C and D not being met. Also, traffic is always subject to jitter in + the network, and the arrival rate at a network element can exceed p_r + for short periods of time. + + In the case R <= p_r, we may still choose PCR such that R <= PCR < + p_r. The edge device buffer is then necessary (and sufficient) to + absorb the bursts (limited to size b_r + C_sum + R D_sum) which + arrive faster than they depart. For example, it may be the case that + the cost of the ATM VC depends on PCR, while the cost of the Internet + service reservation is not strongly dependent on the IP-level peak + rate. The user may then have an incentive to set p_r to APB, while + the operator of the IP/ATM edge router has an incentive to reduce PCR + as much as possible. This may be a realistic concern, since the + charging models of IP and ATM are historically different as far as + usage sensitivity, and the value of p_r, if set close to APB, could + be many times the nominal GS allocated rate of R. Thus, we can set + PCR to R, with a buffer of size b_r + C_sum + R D_sum, with no loss + of traffic, and no violation of the GS delay bound. + + A more subtle, and perhaps controversial case is where we set SCR to + a value below R. The major feature of the GS service is to allow a + receiver to specify the allocated rate R to be larger than the rate + r_r sufficient to transport the traffic, in order to lower the + queueing delay (roughly) from b/r + C_TOT/r + D_TOT to b/R + C_TOT/R + + D_TOT. To effectively allocate bandwidth R to the flow, we set SCR + + + +Garrett & Borden Standards Track [Page 16] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + to match R. (Note it is unnecessary in any case to set SCR above R, + so the relation, SCR <= R, is still true.) It is possible to set SCR + to a value as low as r_r, without violating the delay bounds or + overflowing the edge device buffer. With PCR = R, a burst of size b + will be buffered and sent into the ATM network at rate R, so the last + byte suffers delay only b/R. Any further traffic will be limited to + rate r_r, which is SCR, so with the arriving and departing rates + matched, its delay will also be no more than b/R. + + While this scenario meets the GS service requirements, the penalty + for allocating SCR = r_r rather than R is that the delay in the ATM + network will have a component of MBS/SCR, which will be b/r rather + than b/R, contained in the D term advertised for the ATM sub-network + (see further discussion in Section 3.3 below). It is also true that + allocating r instead of R in a portion of the path is rather against + the spirit of GS. As mentioned above, this mapping may however be + useful in practice in the case where pricing in the ATM network leads + to different incentives in the tradeoff between delay and bandwidth + than those of the user who buys IP integrated services. + + Another point of view on parameter mapping suggests that SCR may + merely reflect the traffic description, hence SCR = r_r, while the + service requirement is expressed in the QoS parameter as CDV = b/R. + Thus the ATM network may internally allocate bandwidth R, but it is + free to use other methods as well to achieve the delay constraint. + Mechanisms such as statistical flow/connection aggregation may be + implemented in the ATM network and hidden from the user (or parameter + mapping module in the edge router) which sees only the interface + implemented in the signalled parameters. + + Note that this discussion considers an edge device buffer size of + b_r. In practice, it may be necessary for the AAL/segmentation + module to buffer M bytes in converting packets to cells. Also an + additional amount of buffer equal to C_sum + R D_sum is generally + necessary to absorb jitter imposed by the upstream network [8]. + + With ATM, it is possible to have little or no buffer in the edge + router, because the ATM VC can be set to accept bursts at peak rate. + This may be unusual, since the edge router normally has enough buffer + to absorb bursts according to the TSpec token bucket parameters. We + consider two cases. First, if PCR >= p_r, then MBS can be set to b_r + and no buffering is necessary to absorb non-excessive bursts. The + extra buffering needed to absorb jitter can also be transferred to + MBS. This effectively moves the buffering across the UNI into the + ATM network. + + + + + + +Garrett & Borden Standards Track [Page 17] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + For completeness, we consider an edge router with no burst-absorbing + buffers and an MBS parameter of approximately zero. In this case it + is sufficient to set the rate parameters to PCR = SCR = max (R, p_r). + This amounts to peak-rate allocation of bandwidth, which will not + usually be very cost effective. This case may be relevant where the + IP routers and ATM switches differ substantially in their buffering + designs. IP-level users may typically specify much larger burst + parameters than can be handled in the ATM subnet. Peak-rate + bandwidth allocation provides a means to work around this problem. + It is also true that intermediate tradeoffs can be formulated, where + the burst-absorbing buffer is less than b bytes, and SCR is set above + R and below p_r. Note that jitter-absorbing buffers (C_sum + R + D_sum) can not be avoided, generally, by increasing ATM rates, unless + SCR is set to exceed the physical line rate(s) into the edge device + for the flow. + + For GS over CBR, the value of PCR may be mapped to the RSpec rate R, + if the edge device has a buffer of size b_r + C_sum + R D_sum. With + little or no burst buffering, the requirements resemble the zero- + buffer case above, and we have PCR = max (R, p_r). Additional + buffers sufficient to absorb network jitter, given by C_sum, D_sum, + MUST always be provided in the edge router, or in the ATM network via + MBS. + +2.5.2 Translating Traffic Descriptors for Controlled Load Service + + The Controlled Load service TSpec has a peak rate, p, a "token + bucket" rate, r, and a corresponding token bucket depth parameter, b. + The receiver TSpec values are used to determine resource allocation, + and a simple mapping for the nrtVBR service category is given by, + + PCR = p_r + SCR = r_r + MBS = b_r. + + The discussions in the preceding section on using edge device buffers + to reduce PCR and/or MBS apply generally to the CLS over nrtVBR case + as well. Extra buffers to accommodate jitter accumulated (beyond the + b_r burst size allowed at the source) MUST be provided. For CLS, + there are no Adspec parameters C and D, so the dimensioning of such + buffers is an implementation design issue. + + For ABR VCs, the TSpec rate r_r is used to set the minimum cell rate + (MCR) parameter. Since there is no corresponding signalled bucket + depth parameter, the edge device SHOULD have a buffer of at least b_r + bytes, plus additional buffers to absorb jitter. With ABR, the ATM + network can quickly throttle the actual transfer rate down to MCR, so + a source transmitting above that rate can experience high loss at the + + + +Garrett & Borden Standards Track [Page 18] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + ingress edge device when the ATM network becomes congested. + + For CBR, the TSpec rate r_r sets a lower bound on PCR, and again, the + available buffering in the edge device SHOULD be adequate to + accommodate possible bursts of b_r. + + The REQUIREMENT for CLS that network delays approximate "best-effort + service under unloaded conditions", is interpreted here to mean that + it would be sufficient to allocate bandwidth resources so that the + last byte of a burst of size b_r sees a delay approximately b_r/r_r. + For example, a network element with no cross-traffic, a work + conserving scheduler and an output link rate of r_L, might provide + delays in the range from M/r_L to b_r/r_L, that are much lower than + b_r/r_r. While the access to the full link bandwidth (r_L), as + reflected in this example, is a more literal interpretation of delay + "under unloaded conditions" for a shared link, an ATM VC may only + have access to bandwidth equal to its nominal allocation (some + implementation specific function of SCR and PCR). + +2.5.3 Translating Traffic Descriptors for Best Effort Service + + For Best Effort service, there is no traffic description. The UBR + service category allows negotiation of PCR simply to allow the source + to discover the smallest physical bottleneck along the path. The + ingress edge router may set PCR to the ATM line rate, and then when + the VC setup is complete, the returned value indicates an upper bound + on throughput. For UBR service, resources may be allocated for the + overall service (i.e., not per-VC) using the (implementation + specific) admission control features of the ATM switches. + + Often a service provider will statically configure large VCs with a + certain bandwidth allocation to handle all best effort traffic + between two edge routers. ABR, CBR or nrtVBR VCs are appropriate for + this design, with traffic parameters set to comfortably accommodate + the expected traffic load. See IETF ION specifications for IP over + ATM signalling [10, 11]. + +2.6 QoS Classes and Parameters + + In UNI 3.x the quality of service is indicated by a single parameter + called "QoS Class," which is essentially an index to a network + specific table of values for the actual QoS parameters. In TM/UNI + 4.0 three QoS parameters may be individually signalled, and the + signalled values override those implied by the QoS Class, which is + still present. These parameters are the Cell Loss Ratio (CLR), Cell + Transfer Delay (CTD), and Cell Delay Variation (CDV) [6]. + + + + + +Garrett & Borden Standards Track [Page 19] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + A network provider may choose to associate other parameters, such as + Severely Errored Cell Block Ratio, with a QoS Class definition, but + these cannot be signalled individually. The ATM Forum UNI 3.0, 3.1 + and TM 4.0 specs, following prior ITU specs, give vague qualitative + definitions for QoS Classes 1 to 4. (QoS Class 0 is well-defined as + "no QoS parameters defined".) Since our mapping is based on these + specifications, we generally follow this guidance by setting the QoS + Class value to 0 for UBR and ABR (as REQUIRED), 1 for CBR and rtVBR + and 3 for nrtVBR. Note that the QoS Class follows the ATM service + category, and not the IP service, to avoid combination that are + unlikely to be supported. For example, if only nrtVBR is available + for GS, then choosing QoS Class = 1 would probably result in + connection failure. The QoS Class MUST NOT be interpreted as a way + to add real-time behavior to an inherently non-real-time service. + + The ITU has included a standard set of parameter values for a (small) + number of QoS Classes in the latest version of Recommendation I.356 + [21]. Network providers may choose to define further network- + specific QoS Classes in addition to these. Note that the QoS class + definitions in the new I.356 version might not align with the model + we follow from the ATM Forum UNI specs. Apart from these + definitions, there is no consistent agreement on QoS Class + definitions among providers in practice. + + The ATM QoS parameters have no explicitly signalled IP layer + counterparts. The values that are signalled in the ATM network are + determined by the IP service definitions and knowledge of the + underlying ATM network characteristics, as explained below. + + The ingress edge router SHOULD keep a table of QoS information for + the set of egress routers that it may establish VCs with. This table + may be simplified by using default values, but it will probably be + good practice to maintain a table of current data for the most + popular egress points. An edge device that initiates VC setup + generally needs to have some way to propose initial value for CDV and + CTD, even if they are changed by negotiation; so by positing such a + table, we are not creating any new design burden. Cached information + can be updated when VCs are successfully established, and to the + extent that IP-layer reservations can wait for VCs to complete, the + values can be refined through iterated negotiation. + + Both GS and CLS REQUIRE that losses of packets due to congestion be + minimized, so that the loss rate is approximately the same as for an + unloaded network. The characteristic loss behavior of the physical + medium not due to congestion (e.g., bit errors or fading on wireless + channels) determines the order of the permitted packet loss rate. + The ingress edge device MUST choose a value of CLR that provides the + appropriate IP-level packet loss rate. The CLR value may be uniform + + + +Garrett & Borden Standards Track [Page 20] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + over all egress points in the ATM network, or may differ, e.g., when + wireless or satellite ATM links are in some paths. The determination + of CLR MUST account for the effects of packet size distribution and + ATM Frame Discard mode (which can change the effective packet loss + rate by orders of magnitude [22]). + + The ingress router will also tabulate values for the Minimum Path + Latency (MPL) and estimated queueing delays (D_ATM) for each egress + point. The latter will be used as part of the Adspec "D" parameter + for GS, but its use here applies to CLS as well (when the VC setup + includes delay parameters). MPL represents all constant (non- + congestion related) delays, including propagation delay. D_ATM + accounts for the variable component of delays in the ATM network. + (It may depend on non-signalled parameters such as CDVT.) Given + these quantities, a new VC can be set up with delay-related QoS + parameters given by + + CDV = D_ATM + CTD = D_ATM + MPL. + + (CDV and CTD may be adjusted (increased) by the slack term in GS, see + Section 3.3 below.) + + It is interesting (and perhaps unfortunate) to note that in a typical + GS/rtVBR service, the delay bound advertised can contain two + components of b/R instead of one. Consider the simple case where SCR + = R is the rate allocated to the flow in both IP routers and ATM + switches along the path, and the buffer allocation is MBS = b. + Parekh's theory [23], which is the basis of the GS delay formula [8] + states that the b/R delay term occurs only once, because once a burst + of size b has been served by a congested node at rate R, the packets + will not arrive at a subsequent node as a single burst. However, we + can't tell a priori if this bottleneck will occur in the ATM network + or elsewhere in the IP network, so the declaration of CDV SHOULD + account for it (i.e., CDV >= b/R). Once CDV is set, the ATM network + can impose this delay, whether or not the traffic arrives in a burst. + Since the delay b/R can also occur elsewhere, it cannot be removed + from the first term of the GS delay formula. The ATM b/R delay + component appears in the third term of the GS delay formula, D_tot. + See Section 3.3 below for more on GS Adspec parameters. This effect + may be mitigated when the ATM network employs more efficient + statistical resource allocation schemes. + + + + + + + + + +Garrett & Borden Standards Track [Page 21] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + +2.7 Additional Parameters -- Frame Discard Mode + + TM/UNI 4.0 allows the user to choose a mode where the ATM network is + aware, for the purpose of congestion management, of PDUs larger than + an ATM cell (i.e., AAL PDUs that correspond in our context to IP + packets). This facilitates implementation of algorithms such as + partial packet discard, where a dropped cell causes subsequent cells + in the same AAL-5 PDU to be dropped as well. Several other + applicable buffer management schemes have been proposed [22, 24]. + + Frame discard can improve the efficiency and performance of end-to- + end protocols such as TCP, since the remaining cells of a damaged PDU + are generally useless to the receiver. For IP over ATM, Frame + Discard MUST always be indicated, if available. + +3.0 Additional IP-Integrated Services Protocol Features + +3.1 Path Characterization Parameters for IP Integrated Services with ATM + + This section discusses the setting of General Characterization + Parameters (GCPs) at an ATM egress edge router. GCPs are signalled + from IP source to IP destination, and modified by intermediate nodes + using the Adspec portion of PATH messages in rsvp. The GS-specific + Adspec parameters are discussed below in Section 3.3. These + parameters are denoted as where x is the service and y is the + parameter number. Service number 1 indicates default or general + parameter values. Please refer to [25] for definitions and details. + + The IS break bit <1,2> MUST, of course, be left alone by + implementations following these guidelines (as they are presumably + IS-aware). Similarly, the router MUST always increment IS_HOPS + <1,4>. The GS and CLS service-specific break bits, <2,2> and <5,2> + respectively, MUST be set if the support of the service is + inadequate. In general GS is adequately supported by CBR (BCOB-A) + and rtVBR service categories, and not adequately supported by UBR, + ABR and nrtVBR because delays are not controlled. CLS may be + adequately supported by all service categories except UBR (or Best + Effort in UNI 3.x). See Sections 5, 6 for further discussion. + + For GS, the ATM network MUST meet the delay performance advertised + through the Adspec parameters, MPL, C, and D. If it cannot + predictably meet these requirements, the GS break bit MUST be set. + Similarly both break bits MUST be set if reservations are honored, + but sufficient resources to avoid congestion loss are not allocated + in practice. If the service break bits are not set, then the + corresponding service hop counters, <2,4>, <5,4>, MUST be + incremented. + + + + +Garrett & Borden Standards Track [Page 22] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + The Available Path Bandwidth (APB) parameters indicate the + minimum physical bottleneck rate along the path. This may be + discoverable in an ATM network as the negotiated PCR value for any + UBR VC along the same path. This value MUST be corrected for AAL, + ATM and physical-layer headers, as necessary, to reflect the + effective IP datagram bandwidth. With ATM, it is possible that there + is some policy limitation on the value of PCR, below the physical + link bottleneck. In this case, the advertised value of APB (in + general, and for each service if the values of APB signalled are + service specific) MUST reflect this limit, since excess traffic + beyond this rate will be dropped. (Note that there is no tagging of + traffic in excess of PCR for TM/UNI 4.0.) These values SHOULD + generally be cached by the ingress router for the set of egress + routers with which it typically needs to establish VCs. The APB + parameters are only adjusted down, to reflect the minimum as the + composed value. + + In the case of a multipoint VC, several parameters can be different + for each egress point, e.g., because the characteristics of the + physical links of the VC branches differ. When this occurs, the IWF + at the egress routers MUST correct these values in PATH messages as + they exit the ATM network. (We use the word "correct" because the + ingress router SHOULD set the parameters to a value that is + appropriate for the largest number of branches, or a value that would + do the least harm if the egress routers failed to correct such + parameters for each branch.) This is the only case where the egress + router needs to operate on rsvp control messages. (A similar + correction MUST be implemented for any non-rsvp set-up mechanism). + The parameters for which such correction is REQUIRED are the + Available Path Bandwidth (APB), the Minimum Path Latency (MPL), the + Path MTU (although for ATM/AAL-5 this may typically be constant), and + the ATM-specific components of the GS Adspec parameters C_ATM and + D_ATM. + + The ingress router table SHOULD store values for the ATM-network MPL + for the various egress points. The composed values are + formed by addition and forwarded along the path. In the cases where + ATM routing chooses different paths, depending on the service + category, for VCs to a given egress point, the table will generally + reflect different values for each service. If the ATM network is + very large and complex, it may become difficult to predict the routes + that VCs will take once they are set up. This could be a significant + source of misconfiguration, resulting in discrepancies between GS + delay advertisements and actual results. The RSpec Slack term may be + useful in mitigating this problem. + + AAL-5 will support any message size up to 65,535 bytes, so setting + the AAL SDU to the receiver TSpec M parameter value (plus 8 bytes for + + + +Garrett & Borden Standards Track [Page 23] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + the LLC/SNAP header) will generally not be an issue. In the PATH + Adspec, however, the PATH_MTU parameter for each service + SHOULD be set to 9188 bytes, which is the default MTU for AAL-5 [19]. + +3.2 Handling of Excess Traffic + + For IP Integrated Services, network elements will transport traffic + in excess of the TSpec parameters whenever physical resources + (bandwidth, buffers and processing) are available. (In CLS a + "network element MUST attempt to forward the excess traffic on a + best-effort basis" under certain conditions; and in GS a traffic + policers "SHOULD relegate non-conforming datagrams to best effort".) + While excess traffic SHOULD be supported on a best effort basis, it + MUST NOT interfere with the QoS (delay and loss) of conforming CLS + and GS traffic, nor with normal service of non-reserved best effort + traffic. + + There are several solutions with ATM: the most attractive is to use a + VBR service category (with an appropriate conformance definition) and + tag excess traffic as low priority using the CLP bit. This avoids + reordering of the flow, but necessitates careful design of the egress + router scheduler. To avoid reordering, the excess traffic can be + queued with conforming traffic. A threshold SHOULD be used to ensure + that conforming traffic is not unnecessarily delayed by the excess. + Also, for GS, the extra delay that would be incurred due to excess + traffic in the queue ahead of conforming packets would have to be + accurately reflected in the delay advertisement. Note that the + ingress router SHOULD tag all cells of each non-conforming packet, + rather than letting the ATM network apply tagging due to ATM-level + non-conformance. + + There is no requirement in ATM standards that tagged cells, marked + either by the user or by policing, be transported if possible. + Therefore, the operator of an edge router supporting IP-IS SHOULD + ascertain the actual behavior of the ATM equipment in the path, which + may span multiple administrative domains in the ATM network. If + tagged cells are simply dropped at some point, regardless of load, + then the operator may consider setting the break bit, at least for + CLS service. + + The other solutions generally involve a separate VC to carry the + excess. A distinct VC can be set up for each VC supporting a GS or + CLS flow, or, if many flows are aggregated into a single QoS VC, then + another VC can handle the excess traffic for that set of flows. A VC + can be set up to handle all excess traffic from the ingress router to + the egress point. Since the QoS of the excess traffic is not + particularly constrained, the design is quite flexible. However, + using a separate VC may cause misordering of packets within a flow. + + + +Garrett & Borden Standards Track [Page 24] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + The service category for the excess-traffic VC may typically be UBR + or ABR, although one could use CBR or nrtVBR if the excess traffic + were predictable enough to know what rate to allocate. (This + wouldn't normally be expected for excess traffic, though.) + + Whether a separate VC is used may be influenced by the design of the + router scheduler. The CLS spec suggests two possible + implementations: one where excess traffic shares the Best Effort + class scheduler allocation, but at lower priority than other best + effort traffic. The other, where a separate allocation is made. The + first would allow excess traffic to use the same VC as normal best + effort traffic, and the second would suggest a separate VC. + + TM/UNI 4.0. does not support tagging of traffic in excess of PCR. + Although UNI 3.x does have a separate PCR parameter for CLP=0 cells + only, we do not recommend using this feature for reasons of + interoperability with TM/UNI 4.0 equipment. This restricts CBR VCs + to use solutions other than tagging. The value of PCR can be set + higher than necessary for conformant traffic, in an effort to support + excess traffic on the same VC. In some cases this may be a viable + solution, such as when there is little additional cost imposed for a + high PCR. If PCR can be set as high as APB, then the excess traffic + is fully accommodated. + +3.3 Use of Guaranteed Service Adspec Parameters and Slack Term + + The Adspec is used by the Guaranteed Service to allow a receiver to + calculate the worst-case delay associated with a GS flow. Three + quantities, C, D, and MPL, are accumulated (by simple addition of + components corresponding to each network element) in the PATH message + from source to receiver. The resulting delay values can be different + for each unique receiver. The maximum delay is computed as + + delay <= b_r/R + C_TOT/R + D_TOT + MPL + + The Minimum Path Latency (MPL) includes propagation delay, while + b_r/R accounts for bursts due to the source and C and D include other + queueing, scheduling and serialization delays. (We neglect the + effect of maximum packet size and peak rate here; see the GS + specification [8] for a more detailed equation.) The service rate + requested by the receiver, R, can be greater than the TSpec rate, + r_r, resulting in lower delay. The burst size, b_r, is the leaky + bucket parameter from the receiver TSpec. + + The values of C and D that a router advertises depend on both the + router packet scheduler and the characteristics of the subnet + attached to the router. Each router (or the source host) takes + responsibility for its downstream subnet in its advertisement. For + + + +Garrett & Borden Standards Track [Page 25] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + example, if the subnet is a simple point-to-point link, the subnet- + specific parts of C and D need to account for the link transmission + rate and MTU. An ATM subnet is generally more complex. + + For this discussion, we consider only the ATM subnet-specific + components, denoted C_ATM and D_ATM. The ATM network can be + represented as a "pure delay" element, where the variable queueing + delay, given by CVD is captured in D_ATM, and C_ATM is set to zero. + It is possible to use C_ATM only when the ATM service rate equals R. + This may be the case, for example with a CBR VC with PCR = R. + + Usually it will be simpler to just advertise the total delay + variation (CDV) in D_ATM. + + As discussed in Section 2.6, the edge router keeps a table with + values of MPL and D_ATM for each egress router it needs to share VCs + with. The value of D_ATM contributes to the D parameter advertised + by the edge router, and SHOULD accurately reflect the CDV that the + router will get in a VC when it is set up. Factors that affect CDV, + such as statistical multiplexing in the ATM network, SHOULD be taken + into account when compiling data for the router's table. In case of + uncertainty, D_ATM can be set to an upper bound. When an RESV + message arrives, causing a VC to be set up, the requested values for + CTD and CDV can be relaxed using the slack term in the receiver + RSpec: + + CTD = D_ATM + MPL + S_ATM + CDV = D_ATM + S_ATM. + + The term S_ATM is the portion of the slack term applied to the ATM + portion of the path. Recall that the slack term [8] is positive when + the receiver can afford more delay than that computed from the + Adspec. The ATM edge device may take part (or all) of the slack + term, S. The distribution of delay slack among the nodes and subnets + is network specific. + + Note that with multipoint VCs the egress edge router may need to + correct advertised values of C and D. See discussion in Section 3.1. + +4.0 Miscellaneous Items + +4.1 Units Conversion + + All rates and token bucket depth parameters that are mapped from IP- + level parameters to ATM parameters MUST be corrected for the effects + of added headers and the segmentation of packets into cells. At the + IP layer, token bucket depths and rates are measured in bytes and + bytes/sec, respectively, whereas for ATM, they are measured in cells + + + +Garrett & Borden Standards Track [Page 26] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + and cells/sec. + + Each IP Packet is wrapped into an AAL-5 PDU, having a number of + additional header bytes (8 for LLC/SNAP and perhaps others, e.g. 12 + for MPOA, etc.), and an 8-byte AAL-5 trailer. The AAL-5 PDU is then + segmented into multiple ATM cells, each having a 5-byte cell header + followed by a 48-byte cell payload. The number of cells used to + carry an IP packet with + + B = number of IP-packet Bytes, + H = number of AAL-5 header bytes (LLC/SNAP etc.) + C = number of cells, + + is roughly + + C = B/48, + + and more precisely + + C = floor[(H + B + 8 + 47)/48] + + where floor[] is rounds down to the nearest integer. The '8' + accounts for the AAL-5 trailer and the '47' accounts for the last + cell which may be only partially filled. + +5.0 Summary of ATM VC Setup Parameters for Guaranteed Service + + This section describes how to create ATM VCs appropriately matched + for Guaranteed Service. The key points are that real-time timing is + REQUIRED, that the data flow may have a variable rate, and that + demotion of non-conforming traffic to best effort is REQUIRED to be + in agreement with the definition of GS. For this reason, we prefer + an rtVBR service in which tagging is supported. Another good match + is to use CBR with special handling of any non-conforming traffic, + e.g., through another VC, since a CBR VC will not accommodate traffic + in excess of PCR. + + Note, these encodings assume point to multipoint connections, where + the backward channel is not used. If the IP session is unicast only, + then a point-to-point VC may be used and the IWF may make use of the + backward channel, with QoS parameters set appropriately for the + service provided. + + We provide a mapping for all combinations of IP service and ATM + service category, and comments indicating whether or not each + combination meets the requirements of the IP-IS service. + + + + + +Garrett & Borden Standards Track [Page 27] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + +5.1 Encoding GS Using Real-Time VBR (ATM Forum TM/UNI 4.0) + + RtVBR with conformance definition VBR.3 [6] MEETS the requirements of + GS. + + AAL + Type 5 + Forward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + Backward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + SSCS Type 0 (Null SSCS) + + Traffic Descriptor + Forward PCR CLP=0+1 Note 1 + Backward PCR CLP=0+1 0 + Forward SCR CLP=0 Note 1 + Backward SCR CLP=0 0 + Forward MBS (CLP=0) Note 1 + Backward MBS (CLP=0) 0 + BE indicator NOT included + Forward Frame Discard bit 1 + Backward Frame Discard bit 1 + Tagging Forward bit 1 (Tagging requested) + Tagging Backward bit 1 (Tagging requested) + + Broadband Bearer Capability + Bearer Class 16 (BCOB-X) Note 2 + ATM Transfer Capability 9 (Real time VBR) Note 3 + Susceptible to Clipping 00 (Not Susceptible) + User Plane Configuration 01 (Point-to-Multipoint) + + Broadband Low Layer Information + User Information Layer 2 + Protocol 12 (ISO 8802/2) + User Information Layer 3 + Protocol 11 (ISO/IEC TR 9577) Note 4 + ISO/IEC TR 9577 IPI 204 + + QoS Class + QoS Class Forward 1 Note 5 + QoS Class Backward 1 Note 5 + + Extended QoS Parameters Note 6 + Acceptable Forward CDV + Acceptable Forward CLR + Forward Max CTD + + Note 1: See discussion in Section 2.5.1. + + + + +Garrett & Borden Standards Track [Page 28] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + Note 2: Value 3 (BCOB-C) can also be used. + If Bearer Class C is chosen the ATC field MUST be absent. + Note 3: The ATC value 19 is not used. The value 19 implies that the + CLR objective applies to the aggregate CLP=0+1 stream and + that does not give desirable treatment of excess traffic. + Note 4: For QoS VCs supporting GS or CLS, the layer 3 protocol + SHOULD be specified. For BE VCs, it can be left + unspecified, allowing the VC to be shared by multiple + protocols, following RFC 1755. + Note 5: Cf ITU Rec. I.356 [21] for new QoS Class definitions. + Note 6: See discussion in Section 2.6. + +5.2 Encoding GS Using CBR (ATM Forum TM/UNI 4.0) + + A CBR VC MEETS the requirements of GS. The main advantage of this is + that CBR is widely supported; the disadvantage is that data flows + might not fill the pipe (utilization loss) and there is no tagging + option available. Excess traffic MUST be handled using a separate + VC. + + AAL + Type 5 + Forward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + Backward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + SSCS Type 0 (Null SSCS) + + Traffic Descriptor + Forward PCR CLP=0+1 Note 1 + Backward PCR CLP=0+1 0 + BE indicator NOT included + Forward Frame Discard bit 1 + Backward Frame Discard bit 1 + Tagging Forward bit 0 (Tagging not requested) + Tagging Backward bit 0 (Tagging not requested) + + Broadband Bearer Capability + Bearer Class 16 (BCOB-X) Note 2 + ATM Transfer Capability 5 (CBR) Note 3 + Susceptible to Clipping 00 (Not Susceptible) + User Plane Configuration 01 (Point-to-Multipoint) + + Broadband Low Layer Information + User Information Layer 2 + Protocol 12 (ISO 8802/2) + User Information Layer 3 + Protocol 11 (ISO/IEC TR 9577) Note 4 + ISO/IEC TR 9577 IPI 204 + + + + +Garrett & Borden Standards Track [Page 29] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + QoS Class + QoS Class Forward 1 Note 5 + QoS Class Backward 1 Note 5 + + Extended QoS Parameters Note 6 + Acceptable Forward CDV + Acceptable Forward CLR + Forward Max CTD + + Note 1: See discussion in Section 2.5.1. + Note 2: Value 1 (BCOB-A) can also be used. + If Bearer Class A is chosen the ATC field MUST be absent. + Note 3: The ATC value 7 is not used. The value 7 implies CLR + objective applies to the aggregate CLP=0+1 stream and that + does not give desirable treatment of excess traffic. + Note 4: For QoS VCs supporting GS or CLS, the layer 3 protocol + SHOULD be specified. For BE VCs, it can be left + unspecified, allowing the VC to be shared by multiple + protocols, following RFC 1755. + Note 5: Cf ITU Rec. I.356 [21] for new QoS Class definitions. + Note 6: See discussion in Section 2.6. + +5.3 Encoding GS Using Non-Real-Time VBR (ATM Forum TM/UNI 4.0) + + NrtVBR does not provide delay guarantees and is NOT RECOMMENDED for + GS. If GS/nrtVBR is used and network utilization is low, the delay + may be `reasonable', but will not be controlled. The encoding of GS + with nrtVBR is the same as that for CLS using nrtVBR. See Section + 6.1 below. + +5.4 Encoding GS Using ABR (ATM Forum TM/UNI 4.0) + + GS using ABR is a very unlikely combination, and DOES NOT meet the + service requirements of GS. The objective of the ABR service is to + provide "low" loss rates. The delay objectives for ABR SHOULD be + expected to be very loose. If ABR were used for GS, the VC + parameters would follow as for CLS over ABR. See Section 6.2. + +5.5 Encoding GS Using UBR (ATM Forum TM/UNI 4.0) + + The UBR service is the lowest common denominator of the services. It + cannot provide delay or loss guarantees, and therefore DOES NOT meet + the requirements of GS. However if it is used for GS, it will be + encoded in the same way as Best Effort over UBR, with the exception + that the Forward PCR would be determined from the peak rate of the + receiver TSpec. See Section 7.1. + + + + + +Garrett & Borden Standards Track [Page 30] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + +5.6 Encoding GS Using ATM Forum UNI 3.0/3.1 Specifications + + It is not recommended to support GS using UNI 3.x VBR mode because + the BCOB-C Bearer Class does not represent real-time behavior. Also, + Appendix F of the UNI 3.1 specification precludes the specification + of traffic type "VBR" with the timing requirement "End to End timing + Required" in conjunction with Bearer Class X. + + A CBR VC MEETS the requirements of GS. The following table specifies + the support of GS using CBR. + + AAL + Type 5 + Forward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + Backward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + Mode 1 (Message mode) Note 1 + SSCS Type 0 (Null SSCS) + + Traffic Descriptor + Forward PCR CLP=0 Note 2 + Backward PCR CLP=0 0 + Forward PCR CLP=0+1 Note 2 + Backward PCR CLP=0+1 0 + BE indicator NOT included + Tagging Forward bit 1 (Tagging requested) + Tagging Backward bit 1 (Tagging requested) + + Broadband Bearer Capability + Bearer Class 16 (BCOB-X) Note 3 + Traffic Type 001 (Constant Bit Rate) + Timing Requirements 01 (Timing Required) + Susceptible to Clipping 00 (Not Susceptible) + User Plane Configuration 01 (Point-to-Multipoint) + + Broadband Low Layer Information + User Information Layer 2 + Protocol 12 (ISO 8802/2) + User Information Layer 3 + Protocol 11 (ISO/IEC TR 9577) Note 4 + ISO/IEC TR 9577 IPI 204 + + + QoS Class Note 5 + QoS Class Forward 1 + QoS Class Backward 1 + + Note 1: Only included for UNI 3.0. + Note 2: See discussion in Section 2.5.1. PCR CLP=0 SHOULD be set + + + +Garrett & Borden Standards Track [Page 31] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + identical to PCR CLP=0+1. Although this could potentially + allow a CBR VC to carry excess traffic as tagged cells, it + is not recommended since it is not supported in UNI 4.0 + Note 3: Value 1 (BCOB-A) can also be used. If BCOB-A is used Traffic + Type and Timing Requirements fields are not included. + Note 4: For QoS VCs supporting GS or CLS, the layer 3 protocol + SHOULD be specified. For BE VCs, it can be left + unspecified, allowing the VC to be shared by multiple + protocols, following RFC 1755. + Note 5: QoS Parameters are implied by the QoS Class. + +6.0 Summary of ATM VC Setup Parameters for Controlled Load Service + + This section describes how to create ATM VCs appropriately matched + for Controlled Load Service. CLS traffic is partly delay tolerant + and has variable rate. NrtVBR and ABR (TM/UNI 4.0 only) are the best + choices for supporting CLS. + + Note, these encodings assume point to multipoint connections where + the backward channel is not used. If the IP session is unicast only, + then a point-to-point VC may be used and the IWF may make use of the + backward channel, with QoS parameters set appropriately for the + service provided. + + We provide a mapping for all combinations of IP service and ATM + service category, and comments indicating whether or not each + combination meets the requirements of the IP-IS service. + +6.1 Encoding CLS Using Non-Real-Time VBR (ATM Forum TM/UNI 4.0) + + NrtVBR MEETS the requirements for CLS. + + AAL + Type 5 + Forward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + Backward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + SSCS Type 0 (Null SSCS) + + Traffic Descriptor + Forward PCR CLP=0+1 Note 1 + Backward PCR CLP=0+1 0 + Forward SCR CLP=0 Note 1 + Backward SCR CLP=0 0 + Forward MBS (CLP=0) Note 1 + Backward MBS (CLP=0) 0 + BE indicator NOT included + Forward Frame Discard bit 1 + Backward Frame Discard bit 1 + + + +Garrett & Borden Standards Track [Page 32] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + Tagging Forward bit 1 (Tagging requested) + Tagging Backward bit 1 (Tagging requested) + + Broadband Bearer Capability + Bearer Class 16 (BCOB-X) Note 2 + ATM Transfer Capability 10 (Non-real time VBR) Note 3 + Susceptible to Clipping 00 (Not Susceptible) + User Plane Configuration 01 (Point-to-Multipoint) + + Broadband Low Layer Information + User Information Layer 2 + Protocol 12 (ISO 8802/2) + User Information Layer 3 + Protocol 11 (ISO/IEC TR 9577) Note 4 + ISO/IEC TR 9577 IPI 204 + + + QoS Class + QoS Class Forward 3 Note 5 + QoS Class Backward 3 Note 5 + + Extended QoS Parameters Note 6 + Acceptable Forward CDV + Acceptable Forward CLR + Forward Max CTD + + + Note 1: See discussion in Section 2.5.2. + Note 2: Value 3 (BCOB-C) can also be used. + If Bearer Class C is used, the ATC field MUST be absent. + Note 3: The ATC value 11 is not used. The value 11 implies CLR + objective applies to the aggregate CLP=0+1 stream and + that does not give desirable treatment of excess traffic. + Note 4: For QoS VCs supporting GS or CLS, the layer 3 protocol SHOULD + be specified. For BE VCs, it can be left unspecified, allowing + the VC to be shared by multiple protocols, following RFC 1755. + Note 5: Cf ITU Rec. I.356 [21] for new QoS Class definitions. + Note 6: See discussion in Section 2.6. + +6.2 Encoding CLS Using ABR (ATM Forum TM/UNI 4.0) + + ABR MEETS the requirements for CLS when MCR is set to the CLS TSpec + rate. + + AAL + Type 5 + Forward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + Backward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + + + +Garrett & Borden Standards Track [Page 33] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + SSCS Type 0 (Null SSCS) + + Traffic Descriptor + Forward PCR CLP=0+1 Note 1 + Backward PCR CLP=0+1 0 + Forward MCR CLP=0+1 Note 1 + Backward MCR CLP=0+1 0 + BE indicator NOT included + Forward Frame Discard bit 1 + Backward Frame Discard bit 1 + Tagging Forward bit 0 (Tagging not requested) + Tagging Backward bit 0 (Tagging not requested) + + Broadband Bearer Capability + Bearer Class 16 (BCOB-X) Note 2 + ATM Transfer Capability 12 (ABR) + Susceptible to Clipping 00 (Not Susceptible) + User Plane Configuration 00 (Point-to-Point) + + Broadband Low Layer Information + User Information Layer 2 + Protocol 12 (ISO 8802/2) + User Information Layer 3 + Protocol 11 (ISO/IEC TR 9577) Note 3 + ISO/IEC TR 9577 IPI 204 + + + QoS Class + QoS Class Forward 0 Note 4 + QoS Class Backward 0 Note 4 + + Extended QoS Parameters Note 5 + Acceptable Forward CDV + Acceptable Forward CLR + Forward Max CTD + + ABR Setup Parameters Note 6 + ABR Additional Parameters Note 6 + + Note 1: See discussion in Section 2.5.2. + Note 2: Value 3 (BCOB-C) can also be used. + If Bearer Class C is chosen the ATC field MUST be absent. + Note 3: For QoS VCs supporting GS or CLS, the layer 3 protocol + SHOULD be specified. For BE VCs, it can be left + unspecified, allowing the VC to be shared by multiple + protocols, following RFC 1755. + Note 4: Cf ITU Rec. I.356 [21] for new QoS Class definitions. + Note 5: See discussion in Section 2.6. + + + +Garrett & Borden Standards Track [Page 34] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + Note 6: The ABR-specific parameters are beyond the scope of this + document. These generally depend on local implementation + and not on values mapped from IP level service parameters + (except for MCR). See [6, 11] for further information. + +6.3 Encoding CLS Using CBR (ATM Forum TM/UNI 4.0) + + Although CBR does not explicitly take into account the variable rate + of source data, it may be convenient to use ATM connectivity between + edge routers to provide a simple "pipe" service, as a leased line + replacement. Since no tagging option is available with CBR, excess + traffic MUST be handled using a separate VC. Under this condition, + CBR MEETS the requirements of CLS. + + To use CBR for CLS, the same encoding for GS over CBR (Section 5.2) + would be used. See discussion in Section 2.5.2. + +6.4 Encoding CLS Using Real-Time VBR (ATM Forum TM/UNI 4.0) + + The encoding of CLS using rtVBR implies a hard limit on the end-to- + end delay in the ATM network. This creates more complexity in the VC + setup than the CLS service requires, and is therefore not a preferred + combination, although it DOES MEET the requirements of CLS. + + If rtVBR is used to encode CLS, then the encoding is essentially the + same as that for GS. See discussions in Section 5.1 and Section + 2.5.2. + +6.5 Encoding CLS Using UBR (ATM Forum TM/UNI 4.0) + + This encoding gives no QoS guarantees and DOES NOT MEET the + requirements of CLS. If used, it is coded in the same way as for BE + over UBR (Section 7.1), except that the PCR would be determined from + the peak rate of the receiver TSpec. + +6.6 Encoding CLS Using ATM Forum UNI 3.0/3.1 Specifications + + This encoding is equivalent to the nrtVBR service category. It MEETS + the requirements of CLS. + + AAL + Type 5 + Forward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + Backward CPCS-SDU Size parameter M of rcvr TSpec + 8 Bytes + Mode 1 (Message mode) Note 1 + SSCS Type 0 (Null SSCS) + + + + + +Garrett & Borden Standards Track [Page 35] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + Traffic Descriptor + Forward PCR CLP=0+1 Note 2 + Backward PCR CLP=0+1 0 + Forward SCR CLP=0 Note 2 + Backward SCR CLP=0 0 + Forward MBS (CLP=0) Note 2 + Backward MBS (CLP=0) 0 + BE indicator NOT included + Tagging Forward bit 1 (Tagging requested) + Tagging Backward bit 1 (Tagging requested) + + Broadband Bearer Capability + Bearer Class 16 (BCOB-X) Note 3 + Traffic Type 010 (Variable Bit Rate) + Timing Requirements 00 (No Indication) + Susceptible to Clipping 00 (Not Susceptible) + User Plane Configuration 01 (Point-to-Multipoint) + + Broadband Low Layer Information + User Information Layer 2 + Protocol 12 (ISO 8802/2) + User Information Layer 3 + Protocol 11 (ISO/IEC TR 9577) Note 4 + ISO/IEC TR 9577 IPI 204 + + + QoS Class + QoS Class Forward 3 Note 5 + QoS Class Backward 3 Note 5 + + Note 1: Only included for UNI 3.0. + Note 2: See discussion in Section 2.5.2. + Note 3: Value 3 (BCOB-C) can also be used. If BCOB-C is used Traffic + Type and Timing Requirements fields are not included. + Note 4: For QoS VCs supporting GS or CLS, the layer 3 protocol + SHOULD be specified. For BE VCs, it can be left + unspecified, allowing the VC to be shared by multiple + protocols, following RFC 1755. + Note 5: Cf ITU Rec. I.356 [21] for new QoS Class definitions. QoS + Parameters are implied by the QoS Class. + +7.0 Summary of ATM VC Setup Parameters for Best Effort Service + + This section is provided for completeness only. The IETF ION working + group documents on ATM signalling support for IP over ATM [10, 11] + provide definitive specifications for Best Effort IP service over + ATM. + + + + +Garrett & Borden Standards Track [Page 36] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + The best-matched ATM service category to IP Best Effort is UBR. We + provide the setup details for this case below. The BE service does + not involve reservation of resources. ABR and nrtVBR are also well + suited to BE service. See discussion in Section 2.1.3. + + Note, VCs supporting best effort service are usually point to point, + rather than point to multipoint, and the backward channels of VCs are + used. In cases where VCs are set up to support best effort multicast + sessions, multipoint VCs can be used and the backward channels would + be not have resources reserved. Related situations include transport + of excess traffic on IP-multicast QoS sessions, or to support the + subset of multicast end systems that have not made rsvp reservations. + See the discussion on VC management in [12]. + +7.1 Encoding Best Effort Service Using UBR (ATM Forum TM/UNI 4.0) + + AAL + Type 5 + Forward CPCS-SDU Size 9188 Bytes (default MTU for AAL-5) + Backward CPCS-SDU Size 9188 Bytes (default MTU for AAL-5) + SSCS Type 0 (Null SSCS) + + Traffic Descriptor + Forward PCR CLP=0+1 Note 1 + Backward PCR CLP=0+1 0 + BE indicator included + Forward Frame Discard bit 1 + Backward Frame Discard bit 1 + Tagging Forward bit 1 (Tagging requested) + Tagging Backward bit 1 (Tagging requested) + + Broadband Bearer Capability + Bearer Class 16 (BCOB-X) Note 2 + ATM Transfer Capability 10 (Non-real time VBR) + Susceptible to Clipping 00 (Not Susceptible) + User Plane Configuration 01 (Point-to-Multipoint) + + Broadband Low Layer Information + User Information Layer 2 + Protocol 12 (ISO 8802/2) Note 3 + + QoS Class + QoS Class Forward 0 + QoS Class Backward 0 + + + Note 1: See discussion in Section 2.5.3. + Note 2: Value 3 (BCOB-C) can also be used. + + + +Garrett & Borden Standards Track [Page 37] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + If Bearer Class C is used, the ATC field MUST be absent + Note 3: For QoS VCs supporting GS or CLS, the layer 3 protocol SHOULD + be specified. For BE VCs, it can be left unspecified, allowing + the VC to be shared by multiple protocols, following RFC 1755. + +8.0 Security Considerations + + IP Integrated Services (including rsvp) and ATM are both complex + resource reservation protocols, and SHOULD be expected to have + complex feature interactions. + + Differences in IP and ATM billing styles could cause unforeseen + problems since RESV messages can set up VCs. For example, an end- + user paying a flat rate for (non-rsvp aware) internet service may + send an rsvp RESV message that encounters a (perhaps distant) ATM + network with a usage-sensitive billing model. Insufficient + authentication could result in services being accidentally billed to + an innocent third party, intentional theft of service, or malicious + denial of service attacks where high volumes of reservations consume + transport or processing resources at the edge devices. + + The difference in styles of handling excess traffic could result in + denial of service attacks where the ATM network uses transport + resources (bandwidth, buffers) or connection processing resources + (switch processor cycles) in an attempt to accommodate excess traffic + that was admitted by the internet service. + + Problems associated with translation of resource reservations at edge + devices are probably more complex and susceptible to abuse when the + IP-ATM edge is also an administrative boundary between service + providers. Note also that administrative boundaries can exist within + the ATM cloud, i.e., the ingress and egress edge devices are operated + by different service providers. + + Note, the ATM Forum Security Working Group is currently defining + ATM-level security features such as data encryption and signalling + authentication. See also the security issues raised in the rsvp + specification [3]. + +9.0 Acknowledgements + + The authors received much useful input from the members of the ISSLL + working group. In particular, thanks to Drew Perkins and Jon Bennett + of Fore Systems, Roch Guerin of IBM, Susan Thomson and Sudha Ramesh + of Bellcore. + + + + + + +Garrett & Borden Standards Track [Page 38] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + +Appendix 1 Abbreviations + + AAL ATM Adaptation Layer + ABR Available Bit Rate + APB Available Path Bandwidth (int-serv GCP) + ATC ATM Transfer Capability + ATM Asynchronous Transfer Mode + B-LLI Broadband Low Layer Information + BCOB Broadband Connection-Oriented Bearer Capability + BCOB-{A,C,X} Bearer Class A, C, or X + BE Best Effort + BT Burst Tolerance + CBR Constant Bit Rate + CDV Cell Delay Variation + CDVT Cell Delay Variation Tolerance + CLP Cell Loss Priority (bit) + CLR Cell Loss Ratio + CLS Controlled Load Service + CPCS Common Part Convergence Sublayer + CTD Cell Transfer Delay + EOM End of Message + GCP General Characterization Parameter + GCRA Generic Cell Rate Algorithm + GS Guaranteed Service + IE Information Element + IETF Internet Engineering Task Force + ION IP Over Non-broadcast multiple access networks + IP Internet Protocol + IPI Initial Protocol Identifier + IS Integrated Services + ISSLL Integrated Services over Specific Link Layers + ITU International Telecommunication Union + IWF Interworking Function + LIJ Leaf Initiated Join + LLC Logical Link Control + MBS Maximum Burst Size + MCR Minimum Cell Rate + MPL Minimum Path Latency + MTU Maximum Transfer Unit + nrtVBR Non-real-time VBR + PCR Peak Cell Rate + PDU Protocol Data Unit + PVC Permanent Virtual Connection + QoS Quality of Service + RESV Reservation Message (of rsvp protocol) + RFC Request for Comments + RSVP Resource Reservation Protocol + RSpec Reservation Specification + + + +Garrett & Borden Standards Track [Page 39] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + rtVBR Real-time VBR + SCR Sustainable Cell Rate + SDU Service Data Unit + SNAP Subnetwork Attachment Point + SSCS Service-Specific Convergence Sub-layer + SVC Switched Virtual Connection + TCP Transport Control Protocol + TM Traffic Management + TSpec Traffic Specification + UBR Unspecified Bit Rate + UNI User-Network Interface + UPC Usage Parameter Control (ATM traffic policing function) + VBR Variable Bit Rate + VC (ATM) Virtual Connection + +REFERENCES + + [1] Bradner, S., "Key words for use in RFCs to Indicate Requirement + Levels", BCP 14, RFC 2119, March 1997. + + [2] Braden, R., Clark, D., and S. Shenker, "Integrated Services in + the Internet Architecture: an Overview", RFC 1633, June 1994. + + [3] Braden, R., Zhang, L., Berson, S., Herzog, S., and S. Jamin, + "Resource ReSerVation Protocol (RSVP) - Version 1 Functional + Specification", RFC 2205, September 1997. + + [4] The ATM Forum, "ATM User-Network Interface Specification, + Version 3.0", Prentice Hall, Englewood Cliffs NJ, 1993. + + [5] The ATM Forum, "ATM User-Network Interface Specification, + Version 3.1", Prentice Hall, Upper Saddle River NJ, 1995. + + [6] The ATM Forum, "ATM User-Network Interface (UNI) Signalling + Specification, Version 4.0", July 1996. Available at + ftp://ftp.atmforum.com/pub/approved-specs/af-sig-0061.000.ps. + + [7] The ATM Forum, "ATM Traffic Management Specification, Version + 4.0", April 1996. Available at + ftp://ftp.atmforum.com/pub/approved-specs/af-tm-0056.000.ps. + + [8] M. W. Garrett, "A Service Architecture for ATM: From + Applications to Scheduling", IEEE Network Mag., Vol. 10, No. 3, + pp. 6-14, May 1996. + + [9] Shenker, S., Partridge, C., and R. Guerin, "Specification of + Guaranteed Quality of Service", RFC 2212, September 1997. + + + + +Garrett & Borden Standards Track [Page 40] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + [10] Wroclawski, J., "Specification of the Controlled-Load Network + Element Service", RFC 2211, September 1997. + + [11] Perez, M., Liaw, F., Mankin, A., Hoffman, E., Grossman, D., and + A. Malis, "ATM Signaling Support for IP over ATM", RFC 1755, + February 1995. + + [12] Maher, M., "ATM Signalling Support for IP over ATM - UNI + Signalling 4.0 Update", RFC 2331, April 1998. + + [13] Crawley, E., Berger, L., Berson, S., Baker, F., Borden, M., and + J. Krawczyk, "A Framework for Integrated Services and RSVP over + ATM", RFC 2382, August 1998. + + [14] Berger, L., "RSVP over ATM Implementation Requirements", RFC + 2380, August 1998. + + [15] Berger, L., "RSVP over ATM Implementation Guidelines", BCP 24, + RFC 2379, August 1998. + + [16] Shenker, S., and J. Wroclawski, "Network Element Service + Specification Template", RFC 2216, September 1997. + + [17] Wroclawski, J., "The Use of RSVP with IETF Integrated Services", + RFC 2210, September 1997. + + [18] Borden, M., Crawley, E., Davie, B., and S. Batsell, "Integration + of Real-time Services in an IP-ATM Network Architecture", RFC + 1821, August 1995. + + [19] Heinanen, J., "Multiprotocol Encapsulation over ATM Adaptation + Layer 5", RFC 1483, July 1993. + + [20] Laubach, M., "Classical IP and ARP over ATM", RFC 1577, January + 1994. + + [21] ITU Recommendation I.356, "B-ISDN ATM layer cell transfer + performance", International Telecommunication Union, Geneva, + October 1996. + + [22] A. Romanow, S. Floyd, "Dynamics of TCP Traffic over ATM + Networks", IEEE J. Sel. Areas in Commun., Vol. 13, No. 4, pp. + 633-41, May 1995. + + + + + + + + +Garrett & Borden Standards Track [Page 41] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + + [23] A. K. Parekh, R. G. Gallager, "A Generalized Processor Sharing + Approach to Flow Control in Integrated Services Networks: The + Multiple Node Case", IEEE/ACM Trans. Networking, Vol. 2, No. 2, + pp. 137-150, April 1994. + + [24] S. Floyd, V. Jacobson, "Link-sharing and Resource Management + Models for Packet Networks", IEEE/ACM Trans. Networking, Vol. 3, + No. 4, August 1995. + + [25] S. Shenker and J. Wroclawski, "General Characterization + Parameters for Integrated Service Network Elements", RFC 2215, + September 1997. + +Authors' Addresses + + Mark W. Garrett + Bellcore + 445 South Street + Morristown, NJ 07960 + USA + + Phone: +1 201 829-4439 + EMail: mwg@bellcore.com + + + Marty Borden + Bay Networks + 42 Nagog Park + Acton MA, 01720 + USA + + Phone: +1 508 266-1011 + EMail: mborden@baynetworks.com + + + + + + + + + + + + + + + + + + +Garrett & Borden Standards Track [Page 42] + +RFC 2381 Interoperation of CLS and GS with ATM August 1998 + + +Full Copyright Statement + + Copyright (C) The Internet Society (1998). All Rights Reserved. + + This document and translations of it may be copied and furnished to + others, and derivative works that comment on or otherwise explain it + or assist in its implementation may be prepared, copied, published + and distributed, in whole or in part, without restriction of any + kind, provided that the above copyright notice and this paragraph are + included on all such copies and derivative works. However, this + document itself may not be modified in any way, such as by removing + the copyright notice or references to the Internet Society or other + Internet organizations, except as needed for the purpose of + developing Internet standards in which case the procedures for + copyrights defined in the Internet Standards process must be + followed, or as required to translate it into languages other than + English. + + The limited permissions granted above are perpetual and will not be + revoked by the Internet Society or its successors or assigns. + + This document and the information contained herein is provided on an + "AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING + TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING + BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION + HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF + MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. + + + + + + + + + + + + + + + + + + + + + + + + +Garrett & Borden Standards Track [Page 43] + -- cgit v1.2.3