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/rfc3564.txt | 1235 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1235 insertions(+) create mode 100644 doc/rfc/rfc3564.txt (limited to 'doc/rfc/rfc3564.txt') diff --git a/doc/rfc/rfc3564.txt b/doc/rfc/rfc3564.txt new file mode 100644 index 0000000..360a1a0 --- /dev/null +++ b/doc/rfc/rfc3564.txt @@ -0,0 +1,1235 @@ + + + + + + +Network Working Group F. Le Faucheur +Request for Comments: 3564 Cisco Systems, Inc. +Category: Informational W. Lai + AT&T + July 2003 + + + Requirements for Support of Differentiated Services-aware + MPLS Traffic Engineering + +Status of this Memo + + This memo provides information for the Internet community. It does + not specify an Internet standard of any kind. Distribution of this + memo is unlimited. + +Copyright Notice + + Copyright (C) The Internet Society (2003). All Rights Reserved. + +Abstract + + This document presents Service Provider requirements for support of + Differentiated Services (Diff-Serv)-aware MPLS Traffic Engineering + (DS-TE). + + Its objective is to provide guidance for the definition, selection + and specification of a technical solution addressing these + requirements. Specification for this solution itself is outside the + scope of this document. + + A problem statement is first provided. Then, the document describes + example applications scenarios identified by Service Providers where + existing MPLS Traffic Engineering mechanisms fall short and + Diff-Serv-aware Traffic Engineering can address the needs. The + detailed requirements that need to be addressed by the technical + solution are also reviewed. Finally, the document identifies the + evaluation criteria that should be considered for selection and + definition of the technical solution. + + + + + + + + + + + + +Le Faucheur & Lai Informational [Page 1] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + +Table of Contents + + Specification Requirements ....................................... 2 + 1. Introduction ................................................. 3 + 1.1. Problem Statement ...................................... 3 + 1.2. Definitions ............................................ 3 + 1.3. Mapping of traffic to LSPs ............................. 5 + 2. Application Scenarios ........................................ 6 + 2.1. Scenario 1: Limiting Proportion of Classes on a Link ... 6 + 2.2. Scenario 2: Maintain relative proportion of traffic .... 6 + 2.3. Scenario 3: Guaranteed Bandwidth Services .............. 8 + 3. Detailed Requirements for DS-TE .............................. 9 + 3.1. DS-TE Compatibility .................................... 9 + 3.2. Class-Types ............................................ 9 + 3.3. Bandwidth Constraints .................................. 11 + 3.4. Preemption and TE-Classes .............................. 12 + 3.5. Mapping of Traffic to LSPs ............................. 15 + 3.6. Dynamic Adjustment of Diff-Serv PHBs ................... 15 + 3.7. Overbooking ............................................ 16 + 3.8. Restoration ............................................ 16 + 4. Solution Evaluation Criteria ................................. 16 + 4.1. Satisfying detailed requirements ....................... 17 + 4.2. Flexibility ............................................ 17 + 4.3. Extendibility .......................................... 17 + 4.4. Scalability ............................................ 17 + 4.5. Backward compatibility/Migration ....................... 17 + 4.6. Bandwidth Constraints Model ............................ 18 + 5. Security Considerations ...................................... 18 + 6. Acknowledgment ............................................... 18 + 7. Normative References ......................................... 18 + 8. Informative References ....................................... 19 + 9. Contributing Authors ......................................... 20 + 10. Editors' Addresses ........................................... 21 + 11. Full Copyright Statement ..................................... 22 + +Specification Requirements + + 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 [RFC2119]. + + + + + + + + + + + +Le Faucheur & Lai Informational [Page 2] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + +1. Introduction + +1.1. Problem Statement + + Diff-Serv is used by some Service Providers to achieve scalable + network designs supporting multiple classes of services. + + In some such Diff-Serv networks, where optimization of transmission + resources on a network-wide basis is not sought, MPLS Traffic + Engineering (TE) mechanisms may not be used. + + In other networks, where optimization of transmission resources is + sought, Diff-Serv mechanisms [DIFF-MPLS] may be complemented by + MPLS Traffic Engineering mechanisms [TE-REQ] [ISIS-TE] [OSPF-TE] + [RSVP-TE] which operate on an aggregate basis across all + Diff-Serv classes of service. In this case, Diff-Serv and MPLS TE + both provide their respective benefits. + + To achieve fine-grained optimization of transmission resources and + further enhanced network performance and efficiency, as discussed in + [TEWG-FW], it may be desirable to perform traffic engineering at a + per-class level instead of at an aggregate level. By mapping the + traffic from a given Diff-Serv class of service on a separate LSP, it + allows this traffic to utilize resources available to the given class + on both shortest paths and non-shortest paths, and follow paths that + meet engineering constraints which are specific to the given class. + This is what we refer to as "Diff-Serv-aware Traffic Engineering + (DS-TE)". + + This document focuses exclusively on the specific environments which + would benefit from DS-TE. Some examples include: + + - networks where bandwidth is scarce (e.g., transcontinental + networks) + - networks with significant amounts of delay-sensitive traffic + - networks where the relative proportion of traffic across + classes of service is not uniform + + This document focuses on intra-domain operation. Inter-domain + operation is not considered. + +1.2. Definitions + + For the convenience of the reader, relevant Diff-Serv ([DIFF-ARCH], + [DIFF-NEW] and [DIFF-PDB]) definitions are repeated herein. + + Behavior Aggregate (BA): a collection of packets with the same + (Diff-Serv) codepoint crossing a link in a particular direction. + + + +Le Faucheur & Lai Informational [Page 3] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + Per-Hop-Behavior (PHB): the externally observable forwarding + behavior applied at a DS-compliant node to a Diff-Serv behavior + aggregate. + + PHB Scheduling Class (PSC): A PHB group for which a common + constraint is that ordering of at least those packets belonging to + the same microflow must be preserved. + + Ordered Aggregate (OA): a set of BAs that share an ordering + constraint. The set of PHBs that are applied to this set of + Behavior Aggregates constitutes a PHB scheduling class. + + Traffic Aggregate (TA): a collection of packets with a codepoint + that maps to the same PHB, usually in a DS domain or some subset + of a DS domain. A traffic aggregate marked for the foo PHB is + referred to as the "foo traffic aggregate" or "foo aggregate" + interchangeably. This generalizes the concept of Behavior + Aggregate from a link to a network. + + Per-Domain Behavior (PDB): the expected treatment that an + identifiable or target group of packets will receive from + "edge-to-edge" of a DS domain. A particular PHB (or, if + applicable, list of PHBs) and traffic conditioning requirements + are associated with each PDB. + + We also repeat the following definition from [TE-REQ]: + + Traffic Trunk: an aggregation of traffic flows of the same class + which are placed inside a Label Switched Path. + + In the context of the present document, "flows of the same class" is + to be interpreted as "flows from the same Forwarding Equivalence + Class which are to be treated equivalently from the DS-TE + perspective". + + We refer to the set of TAs corresponding to the set of PHBs of a + given PSC, as a {TA}PSC. A given {TA}PSC will receive the + treatment of the PDB associated with the corresponding PSC. In + this document, we also loosely refer to a {TA}PSC as a "Diff-Serv + class of service", or a "class of service". As an example, the + set of packets within a DS domain with a codepoint that maps to + the EF PHB may form one {TA}PSC in that domain. As another + example, the set of packets within a DS domain with a codepoint + that maps to the AF11 or AF12 or AF13 PHB may form another {TA}PSC + in that domain. + + + + + + +Le Faucheur & Lai Informational [Page 4] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + We refer to the collection of packets which belong to a given Traffic + Aggregate and are associated with a given MPLS Forwarding Equivalence + Class (FEC) ([MPLS-ARCH]) as a . + + We refer to the set of whose TAs belong to a given {TA}PSC + as a . + +1.3. Mapping of traffic to LSPs + + A network may have multiple Traffic Aggregates (TAs) it wishes to + service. Recalling from [DIFF-MPLS], there are several options on + how the set of of a given FEC can be split into Traffic + Trunks for mapping onto LSPs when running MPLS Traffic Engineering. + + One option is to not split this set of so that each + Traffic Trunk comprises traffic from all the {TA}/PSC. This option + is typically used when aggregate traffic engineering is deployed + using current MPLS TE mechanisms. In that case, all the + of a given FEC are routed collectively according to a + single shared set of constraints and will follow the same path. Note + that the LSP transporting such a Traffic Trunk is, by definition, an + E-LSP as defined in [DIFF-MPLS]. + + Another option is to split the different of a given FEC + into multiple Traffic Trunks on the basis of the {TA}PSC. In other + words, traffic, from one given node to another, is split, based on + the "classes of service", into multiple Traffic Trunks which are + transported over separate LSP and can potentially follow different + paths through the network. DS-TE takes advantage of this and + computes a separate path for each LSP. In so doing, DS-TE can take + into account the specific requirements of the Traffic Trunk + transported on each LSP (e.g., bandwidth requirement, preemption + priority). Moreover DS-TE can take into account the specific + engineering constraints to be enforced for these sets of Traffic + Trunks (e.g., limit all Traffic Trunks transporting a particular + {TA}PSC to x% of link capacity). DS-TE achieves per LSP constraint + based routing with paths that match specific objectives of the + traffic while forming the corresponding Traffic Trunk. + + For simplicity, and because this is the specific topic of this + document, the above paragraphs in this section only considered + splitting traffic of a given FEC into multiple Traffic Aggregates on + the basis of {TA}PSC. However, it should be noted that, in addition + to this, traffic from every {TA}PSC may also be split into multiple + Traffic Trunks for load balancing purposes. + + + + + + +Le Faucheur & Lai Informational [Page 5] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + +2. Application Scenarios + +2.1. Scenario 1: Limiting Proportion of Classes on a Link + + An IP/MPLS network may need to carry a significant amount of VoIP + traffic compared to its link capacity. For example, 10,000 + uncompressed calls at 20ms packetization result in about 1Gbps of IP + traffic, which is significant on an OC-48c based network. In case of + topology changes such as link/node failure, VoIP traffic levels can + even approach the full bandwidth on certain links. + + For delay/jitter reasons, some network administrators see it as + undesirable to carry more than a certain percentage of VoIP traffic + on any link. The rest of the available link bandwidth can be used to + route other "classes of service" corresponding to delay/jitter + insensitive traffic (e.g., Best Effort Internet traffic). The exact + determination of this "certain" percentage is outside the scope of + this requirements document. + + During normal operations, the VoIP traffic should be able to preempt + other "classes of service" (if these other classes are designated as + preemptable and they have lower preemption priority), so that it will + be able to use the shortest available path, only constrained by the + maximum defined link utilization ratio/percentage of the VoIP class. + + Existing TE mechanisms only allow constraint based routing of traffic + based on a single bandwidth constraint common to all "classes of + service", which does not satisfy the needs described here. This + leads to the requirement for DS-TE to be able to enforce a different + bandwidth constraint for different "classes of service". In the + above example, the bandwidth constraint to be enforced for VoIP + traffic may be the "certain" percentage of each link capacity, while + the bandwidth constraint to be enforced for the rest of the "classes + of service" might have their own constraints or have access to the + rest of the link capacity. + +2.2. Scenario 2: Maintain relative proportion of traffic + + Suppose an IP/MPLS network supports 3 "classes of service". The + network administrator wants to perform Traffic Engineering to + distribute the traffic load. Also assume that proportion across + "classes of service" varies significantly depending on the + source/destination POPs. + + + + + + + + +Le Faucheur & Lai Informational [Page 6] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + With existing TE mechanisms, the proportion of traffic from each + "class of service" on a given link will vary depending on multiple + factors including: + + - in which order the different TE-LSPs are established + - the preemption priority associated with the different TE-LSPs + - link/node failure situations + + This may make it difficult or impossible for the network + administrator to configure the Diff-Serv PHBs (e.g., queue bandwidth) + to ensure that each "class of service" gets the appropriate + treatment. This leads again to the requirement for DS-TE to be able + to enforce a different bandwidth constraint for different "classes of + service". This could be used to ensure that, regardless of the order + in which tunnels are routed, regardless of their preemption priority + and regardless of the failure situation, the amount of traffic of + each "class of service" routed over a link matches the Diff-Serv + scheduler configuration on that link to the corresponding class + (e.g., queue bandwidth). + + As an illustration of how DS-TE would address this scenario, the + network administrator may configure the service rate of Diff-Serv + queues to (45%,35%,20%) for "classes of service" (1,2,3) + respectively. The administrator would then split the traffic into + separate Traffic Trunks for each "class of service" and associate a + bandwidth to each LSP transporting those Traffic Trunks. The network + administrator may also want to configure preemption priorities of + each LSP in order to give highest restoration priority to the highest + priority "class of service" and medium priority to the medium "class + of service". Then DS-TE could ensure that after a failure, "class of + service" 1 traffic would be rerouted with first access at link + capacity without exceeding its service rate of 45% of the link + bandwidth. "Class of service" 2 traffic would be rerouted with + second access at the link capacity without exceeding its allotment. + Note that where "class of service" 3 is the Best-Effort service, the + requirement on DS-TE may be to ensure that the total amount of + traffic routed across all "classes of service" does not exceed the + total link capacity of 100% (as opposed to separately limiting the + amount of Best Effort traffic to 20 even if there was little "class + of service" 1 and "class of service" 2 traffic). + + In this scenario, DS-TE would allow for the maintenance of a more + steady distribution of "classes of service", even during rerouting. + This would rely on the required capability of DS-TE to adjust the + amount of traffic of each "class of service" routed on a link based + on the configuration of the scheduler and the amount of bandwidth + available for each "class of service". + + + + +Le Faucheur & Lai Informational [Page 7] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + Alternatively, some network administrators may want to solve the + problem by having the scheduler dynamically adjusted based on the + amount of bandwidth of the LSPs admitted for each "class of service". + This is an optional additional requirement on the DS-TE solution. + +2.3. Scenario 3: Guaranteed Bandwidth Services + + In addition to the Best effort service, an IP/MPLS network operator + may desire to offer a point-to-point "guaranteed bandwidth" service + whereby the provider pledges to provide a given level of performance + (bandwidth/delay/loss...) end-to-end through its network from an + ingress port to an egress port. The goal is to ensure that all the + "guaranteed" traffic under the scope of a subscribed service level + specification, will be delivered within the tolerances of this + service level specification. + + One approach for deploying such "guaranteed" service involves: + + - dedicating a Diff-Serv PHB (or a Diff-Serv PSC as defined in + [DIFF-NEW]) to the "guaranteed" traffic + - policing guaranteed traffic on ingress against the traffic contract + and marking the "guaranteed" packets with the corresponding + DSCP/EXP value + + Where a very high level of performance is targeted for the + "guaranteed" service, it may be necessary to ensure that the amount + of "guaranteed" traffic remains below a given percentage of link + capacity on every link. Where the proportion of "guaranteed" traffic + is high, constraint based routing can be used to enforce such a + constraint. + + However, the network operator may also want to simultaneously perform + Traffic Engineering for the rest of the traffic (i.e., + non-guaranteed traffic) which would require that constraint based + routing is also capable of enforcing a different bandwidth + constraint, which would be less stringent than the one for guaranteed + traffic. + + Again, this combination of requirements can not be addressed with + existing TE mechanisms. DS-TE mechanisms allowing enforcement of a + different bandwidth constraint for guaranteed traffic and for + non-guaranteed traffic are required. + + + + + + + + + +Le Faucheur & Lai Informational [Page 8] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + +3. Detailed Requirements for DS-TE + + This section specifies the functionality that the above scenarios + require out of the DS-TE solution. Actual technical protocol + mechanisms and procedures to achieve such functionality are outside + the scope of this document. + +3.1. DS-TE Compatibility + + Since DS-TE may impact scalability (as discussed later in this + document) and operational practices, DS-TE is expected to be used + when existing TE mechanisms combined with Diff-Serv cannot address + the network design requirements (i.e., where constraint based routing + is required and where it needs to enforce different bandwidth + constraints for different "classes of service", such as in the + scenarios described above in section 2). Where the benefits of DSTE + are only required in a topological subset of their network, some + network operators may wish to only deploy DS-TE in this topological + subset. + + Thus, the DS-TE solution MUST be developed in such a way that: + + (i) it raises no interoperability issues with existing deployed TE + mechanisms. + (ii) it allows DS-TE deployment to the required level of + granularity and scope (e.g., only in a subset of the topology, + or only for the number of classes required in the considered + network) + +3.2. Class-Types + + The fundamental requirement for DS-TE is to be able to enforce + different bandwidth constraints for different sets of Traffic Trunks. + + [TEWG-FW] introduces the concept of Class-Types when discussing + operations of MPLS Traffic Engineering in a Diff-Serv environment. + + We refine this definition into the following: + + Class-Type (CT): the set of Traffic Trunks crossing a link, + that is governed by a specific set of Bandwidth constraints. + CT is used for the purposes of link bandwidth allocation, + constraint based routing and admission control. A given + Traffic Trunk belongs to the same CT on all links. + + Note that different LSPs transporting Traffic Trunks from the same CT + may be using the same or different preemption priorities as explained + in more details in section 3.4 below. + + + +Le Faucheur & Lai Informational [Page 9] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + Mapping of {TA}PSC to Class-Types is flexible. Different {TA}PSC can + be mapped to different CTs, multiple {TA}PSC can be mapped to the + same CT and one {TA}PSC can be mapped to multiple CTs. + + For illustration purposes, let's consider the case of a network + running 4 Diff-Serv PDBs which are respectively based on the EF PHB + [EF], the AF1x PSC [AF], the AF2x PSC and the Default (i.e., + Best-Effort) PHB [DIFF-FIELD]. The network administrator may decide + to deploy DS-TE in the following way: + + o from every DS-TE Head-end to every DS-TE Tail-end, split the + traffic into 4 Traffic Trunks: one for traffic of each + {TA}PSC + o because the QoS objectives for the AF1x PDB and for the AF2x + PDB may be of similar nature (e.g., both targeting low loss + albeit at different levels perhaps), the same (set of) + Bandwidth Constraint(s) may be applied collectively over the + AF1x Traffic Trunks and the AF2x Traffic Trunks. Thus, the + network administrator may only define three CTs: one for the + EF Traffic Trunks, one for the AF1x and AF2x Traffic Trunks + and one for the Best Effort Traffic Trunks. + + As another example of mapping of {TA}PSC to CTs, a network operator + may split the traffic from the {TA}PSC associated with EF into two + different sets of traffic trunks, so that each set of traffic trunks + is subject to different constraints on the bandwidth it can access. + In this case, two distinct CTs are defined for the EF {TA}PSC + traffic: one for the traffic subset subject to the first (set of) + bandwidth constraint(s), the other for the traffic subset subject to + the second (set of) bandwidth constraint(s). + + The DS-TE solution MUST support up to 8 CTs. Those are referred to + as CTc, 0 <= c <= MaxCT-1 = 7. + The DS-TE solution MUST be able to enforce a different set of + Bandwidth Constraints for each CT. + A DS-TE implementation MUST support at least 2 CTs, and MAY support + up to 8 CTs. + + In a given network, the DS-TE solution MUST NOT require the network + administrator to always deploy the maximum number of CTs. The DS-TE + solution MUST allow the network administrator to deploy only the + number of CTs actually utilized. + + + + + + + + + +Le Faucheur & Lai Informational [Page 10] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + +3.3. Bandwidth Constraints + + We refer to a Bandwidth Constraint Model as the set of rules + defining: + + - the maximum number of Bandwidth Constraints; and + - which CTs each Bandwidth Constraint applies to and how. + + By definition of CT, each CT is assigned either a Bandwidth + Constraint, or a set of Bandwidth Constraints. + + We refer to the Bandwidth Constraints as BCb, 0 <= b <= MaxBC-1 + + For a given Class-Type CTc, 0 <= c <= MaxCT-1, let us define + "Reserved(CTc)" as the sum of the bandwidth reserved by all + established LSPs which belong to CTc. + + Different models of Bandwidth Constraints are conceivable for control + of the CTs. + + For example, a model with one separate Bandwidth Constraint per CT + could be defined. This model is referred to as the "Maximum + Allocation Model" and is defined by: + + - MaxBC= MaxCT + - for each value of b in the range 0 <= b <= (MaxCT - 1): + Reserved (CTb) <= BCb + + For illustration purposes, on a link of 100 unit of bandwidth where + three CTs are used, the network administrator might then configure + BC0=20, BC1= 50, BC2=30 such that: + + - All LSPs supporting Traffic Trunks from CT2 use no more than 30 + (e.g., Voice <= 30) + - All LSPs supporting Traffic Trunks from CT1 use no more than 50 + (e.g., Premium Data <= 50) + - All LSPs supporting Traffic Trunks from CT0 use no more than 20 + (e.g., Best Effort <= 20) + + As another example, a "Russian Doll" model of Bandwidth Constraints + may be defined whereby: + + - MaxBC= MaxCT + - for each value of b in the range 0 <= b <= (MaxCT - 1): + SUM (Reserved (CTc)) <= BCb, + for all "c" in the range b <= c <= (MaxCT - 1) + + + + + +Le Faucheur & Lai Informational [Page 11] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + For illustration purposes, on a link of 100 units of bandwidth where + three CTs are used, the network administrator might then configure + BC0=100, BC1= 80, BC2=60 such that: + + - All LSPs supporting Traffic Trunks from CT2 use no more than 60 + (e.g., Voice <= 60) + - All LSPs supporting Traffic Trunks from CT1 or CT2 use no more than + 80 (e.g., Voice + Premium Data <= 80) + - All LSPs supporting Traffic Trunks from CT0 or CT1 or CT2 use no + more than 100 (e.g., Voice + Premium Data + Best Effort <= 100). + + Other Bandwidth Constraints model can also be conceived. Those could + involve arbitrary relationships between BCb and CTc. Those could + also involve additional concepts such as associating minimum + reservable bandwidth to a CT. + + The DS-TE technical solution MUST have the capability to support + multiple Bandwidth Constraints models. The DS-TE technical solution + MUST specify at least one bandwidth constraint model and MAY specify + multiple Bandwidth Constraints models. Additional Bandwidth + Constraints models MAY also be specified at a later stage if deemed + useful based on operational experience from DS-TE deployments. The + choice of which (or which set of) Bandwidth Constraints model(s) is + to be supported by a given DS-TE implementation, is an implementation + choice. For simplicity, a network operator may elect to use the same + Bandwidth Constraints Model on all the links of his/her network. + However, if he/she wishes/needs to do so, the network operator may + elect to use different Bandwidth Constraints models on different + links in a given network. + + Regardless of the Bandwidth Constraint Model, the DS-TE solution MUST + allow support for up to 8 BCs. + +3.4. Preemption and TE-Classes + + [TEWG-FW] defines the notion of preemption and preemption priority. + The DS-TE solution MUST retain full support of such preemption. + However, a network administrator preferring not to use preemption for + user traffic MUST be able to disable the preemption mechanisms + described below. + + The preemption attributes defined in [TE-REQ] MUST be retained and + applicable across all Class Types. The preemption attributes of + setup priority and holding priority MUST retain existing semantics, + and in particular these semantics MUST not be affected by the Ordered + Aggregate transported by the LSP or by the LSP's Class Type. This + means that if LSP1 contends with LSP2 for resources, LSP1 may preempt + LSP2 if LSP1 has a higher set-up preemption priority (i.e., lower + + + +Le Faucheur & Lai Informational [Page 12] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + numerical priority value) than LSP2's holding preemption priority + regardless of LSP1's OA/CT and LSP2's OA/CT. + + We introduce the following definition: + + TE-Class: A pair of: + (i) a Class-Type + (ii) a preemption priority allowed for that + Class-Type. This means that an LSP transporting a + Traffic Trunk from that Class-Type can use that + preemption priority as the set-up priority, as the + holding priority or both. + + Note that by definition: + + - for a given Class-Type, there may be one or multiple + TE-classes using that Class-Type, each using a different preemption + priority + - for a given preemption priority, there may be one or multiple + TE-Class(es) using that preemption priority, each using a different + Class-Type. + + The DS-TE solution MUST allow all LSPs transporting Traffic Trunks of + a given Class-Type to use the same preemption priority. In other + words, the DS-TE solution MUST allow a Class-Type to be used by + single TE-Class. This effectively allows the network administrator + to ensure that no preemption happens within that Class-Type, when so + desired. + + As an example, the DS-TE solution MUST allow the network + administrator to define a Class-Type comprising a single TE-class + using preemption 0. + + The DS-TE solution MUST allow two LSPs transporting Traffic Trunks of + the same Class-Type to use different preemption priorities, and allow + the LSP with higher (numerically lower) set-up priority to preempt + the LSP with lower (numerically higher) holding priority when they + contend for resources. In other words, the DS-TE solution MUST allow + multiple TE-Classes to be defined for a given Class-Type. This + effectively allows the network administrator to enable preemption + within a Class-Type, when so desired. + + As an example, the DS-TE solution MUST allow the network + administrator to define a Class-Type comprising three TE-Classes; one + using preemption 0, one using preemption 1 and one using preemption + 4. + + + + + +Le Faucheur & Lai Informational [Page 13] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + The DS-TE solution MUST allow two LSPs transporting Traffic Trunks + from different Class-Types to use different preemption priorities, + and allow the LSP with higher setup priority to preempt the one with + lower holding priority when they contend for resources. + + As an example, the DS-TE solution MUST allow the network + administrator to define two Class-Types (CT0 and CT1) each comprising + two TE-Classes where say: + + -one TE-Class groups CT0 and preemption 0 + -one TE-Class groups CT0 and preemption 2 + -one TE-Class groups CT1 and preemption 1 + -one TE-Class groups CT1 and preemption 3 + + The network administrator would then, in particular, be able to: + + - transport a CT0 Traffic Trunk over an LSP with setup priority=0 and + holding priority=0 + - transport a CT0 Traffic Trunk over an LSP with setup priority=2 and + holding priority=0 + - transport a CT1 Traffic Trunk over an LSP with setup priority=1 and + holding priority=1 + - transport a CT1 Traffic Trunk over an LSP with setup priority=3 and + holding priority=1. + + The network administrator would then, in particular, NOT be able to: + + - transport a CT0 Traffic Trunk over an LSP with setup priority=1 and + holding priority=1 + - transport a CT1 Traffic Trunk over an LSP with setup priority=0 and + holding priority=0 + + The DS-TE solution MUST allow two LSPs transporting Traffic Trunks + from different Class-Types to use the same preemption priority. In + other words, the DS-TE solution MUST allow TE-classes using different + CTs to use the same preemption priority. This effectively allows the + network administrator to ensure that no preemption happens across + Class-Types, if so desired. + + As an example, the DS-TE solution MUST allow the network + administrator to define three Class-Types (CT0, CT1 and CT2) each + comprising one TE-Class which uses preemption 0. In that case, no + preemption will ever occur. + + Since there are 8 preemption priorities and up to 8 Class-Types, + there could theoretically be up to 64 TE-Classes in a network. This + is felt to be beyond current practical requirements. The current + practical requirement is that the DS-TE solution MUST allow support + + + +Le Faucheur & Lai Informational [Page 14] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + for up to 8 TE-classes. The DS-TE solution MUST allow these + TE-classes to comprise any arbitrary subset of 8 (or less) from the + (64) possible combinations of (8) Class-Types and (8) preemption + priorities. + + As with existing TE, an LSP which gets preempted is torn down at + preemption time. The Head-end of the preempted LSP may then attempt + to reestablish that LSP, which involves re-computing a path by + Constraint Based Routing based on updated available bandwidth + information and then signaling for LSP establishment along the new + path. It is to be noted that there may be cases where the preempted + LSP cannot be reestablished (e.g., no possible path satisfying LSP + bandwidth constraints as well as other constraints). In such cases, + the Head-end behavior is left to implementation. It may involve + periodic attempts at reestablishing the LSP, relaxing of the LSP + constraints, or other behaviors. + +3.5. Mapping of Traffic to LSPs + + The DS-TE solution MUST allow operation over E-LSPs onto which a + single is transported. + + The DS-TE solution MUST allow operation over L-LSPs. + + The DS-TE solution MAY allow operation over E-LSPs onto which + multiple of a given FEC are transported, under the + condition that those multiple can effectively be + treated by DS-TE as a single atomic traffic trunk (in particular this + means that those multiple are routed as a whole based + on a single collective bandwidth requirement, a single affinity + attribute, a single preemption level, a single Class-Type, etc.). In + that case, it is also assumed that the multiple {TA}PSCs are grouped + together in a consistent manner throughout the DS-TE domain (e.g., if + and are transported together on an + E-LSP, then there will not be any L-LSP transporting + or on its own, and there will not be any E-LSP + transporting and/or with + ). + +3.6. Dynamic Adjustment of Diff-Serv PHBs + + As discussed in section 2.2, the DS-TE solution MAY support + adjustment of Diff-Serv PHBs parameters (e.g., queue bandwidth) based + on the amount of TE-LSPs established for each OA/Class-Type. Such + dynamic adjustment is optional for DS-TE implementations. + + + + + + +Le Faucheur & Lai Informational [Page 15] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + Where this dynamic adjustment is supported, it MUST allow for + disabling via configuration (thus reverting to PHB treatment with + static scheduler configuration independent of DS-TE operations). It + MAY involve a number of configurable parameters which are outside the + scope of this specification. Those MAY include configurable + parameters controlling how scheduling resources (e.g., service rates) + need to be apportioned across multiple OAs when those belong to the + same Class-Type and are transported together on the same E-LSP. + + Where supported, the dynamic adjustment MUST take account of the + performance requirements of each PDB when computing required + adjustments. + +3.7. Overbooking + + Existing TE mechanisms allow overbooking to be applied on LSPs for + Constraint Based Routing and admission control. Historically, this + has been achieved in TE deployment through factoring overbooking + ratios at the time of sizing the LSP bandwidth and/or at the time of + configuring the Maximum Reservable Bandwidth on links. + + The DS-TE solution MUST also allow overbooking and MUST effectively + allow different overbooking ratios to be enforced for different CTs. + + The DS-TE solution SHOULD optionally allow the effective overbooking + ratio of a given CT to be tweaked differently in different parts of + the network. + +3.8. Restoration + + With existing TE, restoration policies use standard priority + mechanisms such as, for example, the preemption priority to + effectively control the order/importance of LSPs for restoration + purposes. + + The DS-TE solution MUST ensure that similar application of the use of + standard priority mechanisms for implementation of restoration policy + are not prevented since those are expected to be required for + achieving the survivability requirements of DS-TE networks. + + Further discussion of restoration requirements are presented in the + output document of the TEWG Requirements Design Team [SURVIV-REQ]. + +4. Solution Evaluation Criteria + + A range of solutions is possible for the support of the DS-TE + requirements discussed above. For example, some solutions may + require that all current TE protocols syntax (IGP, RSVP-TE,) be + + + +Le Faucheur & Lai Informational [Page 16] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + extended in various ways. For instance, current TE protocols could + be modified to support multiple bandwidth constraints rather than the + existing single aggregate bandwidth constraint. Alternatively, other + solutions may keep the existing TE protocols syntax unchanged but + modify their semantics to allow for the multiple bandwidth + constraints. + + This section identifies the evaluation criteria that MUST be used to + assess potential DS-TE solutions for selection. + +4.1. Satisfying detailed requirements + + The solution MUST address all the scenarios described in section 2 + and satisfy all the requirements listed in section 3. + +4.2. Flexibility + + - number of Class-Types that can be supported, compared to number + identified in Requirements section + - number of PDBs within a Class-Type + +4.3. Extendibility + + - how far can the solution be extended in the future if requirements + for more Class-Types are identified in the future. + +4.4. Scalability + + - impact on network scalability in what is propagated, processed, + stored and computed (IGP signaling, IGP processing, IGP database, + TE-Tunnel signaling ,...). + - how does scalability impact evolve with number of + Class-Types/PDBs actually deployed in a network. In particular, + is it possible to keep overhead small for a large networks which + only use a small number of + Class-Types/PDBs, while allowing higher number of + Class-Types/PDBs in smaller networks which can bear higher + overhead) + +4.5. Backward compatibility/Migration + + - backward compatibility/migration with/from existing TE mechanisms + - backward compatibility/migration when increasing/decreasing the + number of Class-Types actually deployed in a given network. + + + + + + + +Le Faucheur & Lai Informational [Page 17] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + +4.6. Bandwidth Constraints Model + + Work is currently in progress to investigate the performance and + trade-offs of different operational aspects of Bandwidth Constraints + models (for example see [BC-MODEL], [BC-CONS] and [MAR]). In this + investigation, at least the following criteria are expected to be + considered: + + (1) addresses the scenarios in Section 2 + (2) works well under both normal and overload conditions + (3) applies equally when preemption is either enabled or disabled + (4) minimizes signaling load processing requirements + (5) maximizes efficient use of the network + (6) Minimizes implementation and deployment complexity. + + In selection criteria (2), "normal condition" means that the network + is attempting to establish a volume of DS-TE LSPs for which it is + designed; "overload condition" means that the network is attempting + to establish a volume of DS-TE LSPs beyond the one it is designed + for; "works well" means that under these conditions, the network + should be able to sustain the expected performance, e.g., under + overload it is x times worse than its normal performance. + +5. Security Considerations + + The solution developed to address the DS-TE requirements defined in + this document MUST address security aspects. DS-TE does not raise + any specific additional security requirements beyond the existing + security requirements of MPLS TE and Diff-Serv. The solution MUST + ensure that the existing security mechanisms (including those + protecting against DOS attacks) of MPLS TE and Diff-Serv are not + compromised by the protocol/procedure extensions of the DS-TE + solution or otherwise MUST provide security mechanisms to address + this. + +6. Acknowledgment + + We thank David Allen for his help in aligning with up-to-date + Diff-Serv terminology. + +7. Normative References + + [AF] Heinanen, J., Baker, F., Weiss, W. and J. Wroclawski, + "Assured Forwarding PHB Group", RFC 2597, June 1999. + + [DIFF-ARCH] Blake, S., Black, D., Carlson, M., Davies, E., Wang, Z. + and W. Weiss, "An Architecture for Differentiated + Services", RFC 2475, December 1998. + + + +Le Faucheur & Lai Informational [Page 18] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + [DIFF-FIELD] Nichols, K., Blake, S., Baker, F. and D. Black, + "Definition of the Differentiated Services Field (DS + Field) in the IPv4 and IPv6 Headers", RFC 2474, December + 1998. + + [MPLS-ARCH] Rosen, E., Viswanathan, A. and R. Callon, "Multiprotocol + Label Switching Architecture", RFC 3031, January 2001. + + [DIFF-MPLS] Le Faucheur, F., Wu, L., Davie, B., Davari, S., + Vaananen, P., Krishnan, R., Cheval, P. and J. Heinanen, + "Multi-Protocol Label Switching (MPLS) Support of + Differentiated Services", RFC 3270, May 2002. + + [DIFF-NEW] Grossman, D., "New Terminology and Clarifications for + Diffserv", RFC 3260, April 2002. + + [EF] Davie, B., Charny, A., Bennet, J.C.R., Benson, K., Le + Boudec, J.Y., Davari, S., Courtney, W., Firioiu, V. and + D. Stiliadis, "An Expedited Forwarding PHB (Per-Hop + Behavior)", RFC 3246, March 2002. + + [TEWG-FW] Awduche, D., Chiu, A., Elwalid, A., Widjaja, I. and X. + Xiao, "Overview and Principles of Internet Traffic + Engineering", RFC 3272, May 2002. + + [TE-REQ] Awduche, D., Malcolm, J., Agogbua, J., O'Dell, M. and J. + McManus, "Requirements for Traffic Engineering over + MPLS", RFC 2702, September 1999. + + [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate + Requirement Levels", BCP 14, RFC 2119, March 1997. + +8. Informative References + + [DIFF-PDB] Nichols, K. and B. Carpenter, "Definition of + Differentiated Services Per Domain Behaviors and Rules + for their Specification", RFC 3086, April 2001. + + [ISIS-TE] Smit, Li, "IS-IS extensions for Traffic Engineering", + Work in Progress, December 2002. + + [OSPF-TE] Katz, et al., "Traffic Engineering Extensions to OSPF", + Work in Progress, October 2002. + + [RSVP-TE] Awduche, D., Berger, L., Gan, D., Li, T., Srinivasan, V. + and G. Swallow, "RSVP-TE: Extensions to RSVP for LSP + Tunnels", RFC 3209, December 2001. + + + + +Le Faucheur & Lai Informational [Page 19] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + [SURVIV-REQ] Lai, W. and D. McDysan, "Network Hierarchy and + Multilayer Survivability", RFC 3386, November 2002. + + [BC-MODEL] Lai, W., "Bandwidth Constraints Models for + Diffserv-aware MPLS Traffic Engineering: Performance + Evaluation", Work in Progress, June 2002. + + [BC-CONS] F. Le Faucheur, "Considerations on Bandwidth Constraints + Models for DS-TE", Work in Progress, June 2002. + + [MAR] Ash, J., "Max Allocation with Reservation Bandwidth + Constraint Model for MPLS/DiffServ TE & Performance + Comparisons", Work in Progress, May 2003. + +9. Contributing Authors + + This document was the collective work of several people. The text + and content of this document was contributed by the editors and the + co-authors listed below. (The contact information for the editors + appears below.) + + Martin Tatham Thomas Telkamp + BT Global Crossing + Adastral Park, Martlesham Heath, Oudkerkhof 51, 3512 GJ Utrecht + Ipswich IP5 3RE, UK The Netherlands + Phone: +44-1473-606349 Phone: +31 30 238 1250 + EMail: martin.tatham@bt.com EMail: telkamp@gblx.net + + David Cooper Jim Boyle + Global Crossing Protocol Driven Networks, Inc. + 960 Hamlin Court 1381 Kildaire Farm Road #288 + Sunnyvale, CA 94089, USA Cary, NC 27511, USA + Phone: (916) 415-0437 Phone: (919) 852-5160 + EMail: dcooper@gblx.net EMail: jboyle@pdnets.com + + Luyuan Fang Gerald R. Ash + AT&T Labs AT&T Labs + 200 Laurel Avenue 200 Laurel Avenue + Middletown, New Jersey 07748, USA Middletown, New Jersey 07748,USA + Phone: (732) 420-1921 Phone: (732) 420-4578 + EMail: luyuanfang@att.com EMail: gash@att.com + + + + + + + + + + +Le Faucheur & Lai Informational [Page 20] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + + Pete Hicks Angela Chiu + CoreExpress, Inc AT&T Labs-Research + 12655 Olive Blvd, Suite 500 200 Laurel Ave. Rm A5-1F13 + St. Louis, MO 63141, USA Middletown, NJ 07748, USA + Phone: (314) 317-7504 Phone: (732) 420-9061 + EMail: pete.hicks@coreexpress.net EMail: chiu@research.att.com + + William Townsend Thomas D. Nadeau + Tenor Networks Cisco Systems, Inc. + 100 Nagog Park 300 Beaver Brook Road + Acton, MA 01720, USA Boxborough, MA 01719 + Phone: +1 978-264-4900 Phone: +1-978-936-1470 + EMail:btownsend@tenornetworks.com EMail: tnadeau@cisco.com + + Darek Skalecki + Nortel Networks + 3500 Carling Ave, + Nepean K2H 8E9, + Phone: (613) 765-2252 + EMail: dareks@nortelnetworks.com + +10. Editors' Addresses + + Francois Le Faucheur + Cisco Systems, Inc. + Village d'Entreprise Green Side - Batiment T3 + 400, Avenue de Roumanille + 06410 Biot-Sophia Antipolis, France + + Phone: +33 4 97 23 26 19 + EMail: flefauch@cisco.com + + + Wai Sum Lai + AT&T Labs + 200 Laurel Avenue + Middletown, New Jersey 07748, USA + + Phone: (732) 420-3712 + EMail: wlai@att.com + + + + + + + + + + + +Le Faucheur & Lai Informational [Page 21] + +RFC 3564 Requirements for Diff-Serv-aware TE July 2003 + + +11. Full Copyright Statement + + Copyright (C) The Internet Society (2003). 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. + +Acknowledgement + + Funding for the RFC Editor function is currently provided by the + Internet Society. + + + + + + + + + + + + + + + + + + + +Le Faucheur & Lai Informational [Page 22] + -- cgit v1.2.3