Network Working Group Internet Draft K. Kumaki, Ed. Category: Informational KDDI Corporation Expires: August 31, 2007 R. Zhang BT infonet March 1, 2007 Requirements for delivering MPLS Services Over L3VPN draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03.txt Status of this Memo By submitting this Internet-Draft, each author represents that any applicable patent or other IPR claims of which he or she is aware have been or will be disclosed, and any of which he or she becomes aware will be disclosed, in accordance with Section 6 of BCP 79. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet-Drafts. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress." The list of current Internet-Drafts can be accessed at http://www.ietf.org/ietf/1id-abstracts.txt The list of Internet-Draft Shadow Directories can be accessed at http://www.ietf.org/shadow.html. This Internet-Draft will expire on August 31, 2007. Copyright Notice Copyright (C) The IETF Trust (2007). Abstract This document describes Service Provider requirements for providing end-to-end MPLS TE LSPs over L3VPN. K.Kumaki, et al. Expires August 31, 2007 [Page 1] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 The main objective is to present a set of requirements which result in general guidelines for the definition, selection and specification of a technical solution addressing these requirements. Specification for this solution itself is out of scope in this document. Conventions used in this document 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]. Table of Contents 1. Introduction..................................................3 2. Terminology...................................................4 3. Problem Statement.............................................5 4. Reference model...............................................5 5. Application Scenarios..........................................6 5.1 Scenario I: Fast recovery over BGP/MPLS IP-VPN.............7 5.2 Scenario II: Strict C-TE LSP QoS guarantees................7 5.3 Scenario III: load balance of CE-to-CE traffic.............8 6. Detailed Requirements..........................................9 6.1 Selective P-TE LSPs......................................9 6.2 Graceful Restart Support for C-TE LSPs..................10 6.3 Rerouting Support for C-TE LSPs.........................10 6.4 FRR Support for C-TE LSPs...............................10 6.5 Admission Control Support on P-TE LSP Head-Ends.........10 6.6 Policy Control Support for C-TE LSPs....................10 6.7 PCE Features Support for C-TE LSPs......................11 6.8 Diversely Routed C-TE LSPs Support......................11 6.9 Optimal Path Support for C-TE LSPs......................11 6.10 Reoptimization Support for C-TE LSPs....................12 6.11 DS-TE Support for C-TE LSPs.............................12 6.12 Complexity and Risks....................................12 6.13 Backward Compatibility..................................12 6.14 Scalability Considerations..............................12 6.15 Performance Considerations..............................13 6.16 Management Considerations...............................13 7. Security Considerations......................................13 8. IANA Considerations..........................................14 9. Normative References.........................................14 10.Informative References........................................15 11.Appendix A. - RSVP Aggregation over MPLS TE Tunnels on L3VPN Services.........................................................15 12.Acknowledgments...............................................16 13.Author's Addresses............................................16 14.Intellectual Property Statement...............................16 K.Kumaki, et al. Expires August 31, 2007 [Page 2] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 1. Introduction L3VPN service providers are presented with two conflicting requirements. The first requirement states that service provider network must protect itself from any misconfiguration or misbehavior on the part of any particular customer. When one customer behaves badly, the service provider must continue to provide service to its remaining customers. As a consequence, many service providers maintain a security posture in which all customer interfaces are mediated by a Virtual Routing and Forwarding (VRF) instance. Customers cannot forward packets through the service provider's general forwarding instance, nor can they join the service provider's intra-domain routing or MPLS signaling domain. The second requirement is for service providers to offer robust MPLS services to their customers. In order to understand this requirement, assume that the customer maintains sites of connectivity on either side of a service provider network. In order to fulfill the requirement, the customer must be able to establish and maintain an MPLS LSP from any router in one site to any router in the other site. For the purposes of this document, we will call this customer LSP an "end-to-end LSP". The customer deploys end-to-end LSPs in order to construct diverse services that, in turn, are offered to the customer's users. These diverse services might include L1VPN, L2VPN, L3VPN or other MPLS- enabled services that have yet to be defined. The end-to-end LSP must be robust. This is to say that it must be enabled with many of the features that one would expect from a traffic engineered intra-domain LSP. These features include traffic engineering by means of bandwidth reservation, administrative groups and priority. They also include differentiated services on the forwarding plane and fast reroute on the control plane. Furthermore, the solution must offer all of the benefits of a Layer 3 VPN. Specifically, the interfaces that connect the customer's edge router to the service provider's edge router need not be numbered from globally unique address space. They can be numbered from address space that is unique only to the VPN. At first glance, the two requirements discussed above appear to be in conflict with one another. However, they can be harmonized using mechanism such as LSP hierarchies and/or routing and signaling policy. K.Kumaki, et al. Expires August 31, 2007 [Page 3] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 This document defines detailed requirements for providing an end-to- end MPLS TE LSP. Although this document presents a reference model, this reference model may not be considered as part of the solution. The reference model is intended only to provide a conceptual framework for subsequent solution documents. At this time, P2P end-to-end MPLS TE LSPs are discussed in this document. But P2MP end-to-end MPLS TE LSPs are for further study and are therefore beyond the current scope of the document. 2. Terminology LSP: Label Switched Path TE LSP: Traffic Engineering Label Switched Path MPLS TE LSP: Multi Protocol Label Switching TE LSP C-TE LSP: Customer Traffic Engineering Label Switched Path: an end-to-end MPLS TE LSP for customers P-TE LSP: Provider Traffic Engineering Label Switched Path: a transport TE LSP between PEs for service providers P-PSN Tunnel: Provider Packet Switched Network Tunnel: VPN: Virtual Private Network CE: Customer Edge Equipment PE: Provider Edge Equipment that has direct connections to CEs from the Layer3 point of view. P: Provider Equipment that has backbone trunk connections only. VRF: Virtual Private Network (VPN) Routing and Forwarding Instance PCC: Path Computation Client: any client application requesting a path computation to be performed by a Path Computation Element. PCE: Path Computation Element: an entity (component, application or network node) that is capable of computing a network path or route based on a network graph and applying computational constraints. Head-end LSR: ingress LSR Tail-end LSR: egress LSR K.Kumaki, et al. Expires August 31, 2007 [Page 4] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 LSR: Label Switched Router 3. Problem Statement Some service providers think that they provide advanced MPLS services over L3VPN. Service providers have some application scenarios for these services. For example, a C-TE LSP with guaranteed bandwidth between data center or customer sites is required for voice, television and video traffic. Because traffic such as voice, television and video is very sensitive, it is required to ensure sub- 50msec recovery in link/node/SRLG, strict QoS guarantees and optimal path. Thus, service providers require a C-TE LSP to provide these services stably maintaining quality of service. When service providers provide a C-TE LSP over L3VPN, they require that a MPLS TE LSP from a local CE to a remote CE is established. But if service providers provide the C-TE LSP over L3VPN, especially BGP/MPLS IP-VPN [RFC4364], they can't provide it over vrf instance. In current BGP/MPLS IP-VPN architecture, it does not define a vrf instance which receives a RSVP signaling packet and processes this packet. Furthermore, this C-TE LSP is required for a specific application. Thus, service providers must maintain quite a few C-TE LSPs. But, a C-TE LSP established over BGP/MPLS IP-VPN is not scalable due to the number of RSVP control message and retained state because it may result in a lot of MPLS TE LSPs in an actual BGP/MPLS IP-VPN. Therefore, scalable C-TE LSPs are required through BGP/MPLS IP-VPN. This problem happens in carrier's carrier environments [RFC4364] as well as in basic BGP/MPLS IP-VPN environments. As the reasons mentioned above, it is highly desired to support C-TE LSPs over BGP/MPLS IP-VPN. C-TE LSPs are highly desired in order to provide: - Fast recovery over BGP/MPLS IP-VPN to protect traffic for C-TE LSP against CE-PE link failure and PE node failure. - Strict C-TE LSP QoS guarantees. - Resource optimization for C-TE LSPs. - Scalability for C-TE LSPs. 4. Reference model This section describes a C-TE LSP and a P-TE LSP in L3VPN, especially BGP/MPLS IP-VPN. In BGP/MPLS IP-VPN, a C-TE LSP and a P-TE LSP are shown in figure 1. K.Kumaki, et al. Expires August 31, 2007 [Page 5] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 CE0 and/or CE1 send a path message to CE2 and/or CE3 respectively over vrf instance. The rsvp control messages (i.e. a RSVP PATH message and a RSVP RESV message and so on) are forwarded by labeled packet through BGP/MPLS IP-VPN. After CE0 and/or CE1 receive a reservation message from CE2 and/or CE3, it establishes a C-TE LSP through BGP/MPLS IP-VPN. A P-TE LSP is established between PE1 and PE2. This LSP is used by vrf instance to forward customer packets within BGP/MPLS IP-VPN. Generally speaking, C-TE LSPs are used by customers and P-TE LSPs are used by service providers. C-TE LSP <-----------------------------------------------------------> or C-TE LSP <----------------------------------------------> P-TE LSP <---------------------------> ............. ............. . --- --- . --- --- --- --- . --- --- . .|CE0| |CE1|-----|PE1|----|P1 |-----|P2 |----|PE2|-----|CE2| |CE3|. . --- --- . --- --- --- --- . --- --- . ............. ............. ^ ^ | | vrf instance vrf instance <--customer--> <--------BGP/MPLS IP-VPN-------> <--customer-> network network or or another another service provider service provider network network Figure 1 Reference Model 5. Application Scenarios The following sections present a few application scenarios for C-TE LSPs in L3VPN environments, especially BGP/MPLS IP-VPN environments. K.Kumaki, et al. Expires August 31, 2007 [Page 6] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 5.1 Scenario I: Fast recovery over BGP/MPLS IP-VPN In this scenario, a customer uses a VoIP application between its sites (i.e., between CE1 and CE2). H0 and H1 are voice equipments. This scenario I is shown in figure 2. In this case, the customer establishes C-TE LSP1 which is a primary path and C-TE LSP2 which is a backup path. If the link between PE1 and CE1 or the node (i.e., PE1) fails, C-TE LSP1 needs a path protection. C-TE LSP1 <----------------------------------------------> P-TE LSP1 <---------------------------> ............. ............. . --- --- . --- --- --- --- . --- --- . .|H0 | |CE1|-----|PE1|----|P1 |-----|P2 |----|PE2|-----|CE2| |H1 |. . --- --- . --- --- --- --- . --- --- . .........|... --- --- --- --- ...|......... +-------|PE3|----|P3 |-----|P4 |----|PE4|-------+ --- --- --- --- <---------------------------> P-TE LSP2 <----------------------------------------------> C-TE LSP2 <--customer--> <--------BGP/MPLS IP-VPN-------> <--customer-> network network Figure 2 Scenario I 5.2 Scenario II: Strict C-TE LSP QoS guarantees In this scenario, service provider B controls voice, video and television traffic between its sites (i.e., between CE1 and CE2). This scenario II is shown in figure 3. In this case, service provider B establishes C-TE LSP1 with preemption priority 0, available bandwidth 100Mbps for voice traffic and C-TE LSP2 with preemption priority 1, available bandwidth 200Mbps for video and television traffic. On the other hand, service provider A also pre-establishes P-TE LSP1 with preemption priority 0, available bandwidth 1Gbps for voice traffic and P-TE LSP2 with preemption priority 1, available bandwidth 2Gbps for video and television traffic. These P-TE LSP1 and P-TE LSP2 should support DS- TE. [RFC4124] K.Kumaki, et al. Expires August 31, 2007 [Page 7] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 PE1 and PE3 should choose an appropriate P-TE LSP based on preemption priority. In this case, P-TE LSP1 should choose C-TE LSP1 at PE1 and P-TE LSP2 should choose C-TE LSP2 at PE3. Furthermore, PE1 and PE3 head-ends should control the bandwidth of C- TE LSPs. In this case, PE1 and PE3 can choose C-TE LSPs by the amount of max available bandwidth for each P-TE LSP, respectively. C-TE LSP1 <----------------------------------------------> P-TE LSP1 <---------------------------> ............. ............. . --- --- . --- --- --- --- . --- --- . .|CE0| |CE1|-----|PE1|----|P1 |-----|P2 |----|PE2|-----|CE2| |CE3|. . --- --- . --- --- --- --- . --- --- . .........|... --- --- --- --- ...|......... +-------|PE3|----|P3 |-----|P4 |----|PE4|-------+ --- --- --- --- <---------------------------> P-TE LSP2 <----------------------------------------------> C-TE LSP2 <---SP B----> <--------BGP/MPLS IP-VPN-------> <---SP B---> network SP A network network Figure 3 Scenario II 5.3 Scenario III: load balance of CE-to-CE traffic In this scenario, service provider C uses voice, video and television traffic between its sites (i.e., between CE0 and CE5/CE7, between CE2 and CE5/CE7, between CE5 and CE0/CE2, and between CE7 and CE0/CE2). H0 and H1 are voice, video and television equipments. This scenario III is shown in figure 4. In this case, service provider C establishes C-TE LSP1, C-TE LSP3, C- TE LSP5 and C-TE LSP7 with preemption priority 0, available bandwidth 100Mbps for voice traffic, and establishes C-TE LSP2, C-TE LSP4, C-TE LSP6 and C-TE LSP8 with preemption priority 1, available bandwidth 200Mbps for video and television traffic. On the other hand, service provider A also pre-establishes P-TE LSP1 and P-TE LSP3 with preemption priority 0, available bandwidth 1Gbps for voice traffic and P-TE LSP2 and P-TE LSP4 with preemption priority 1, available bandwidth 2Gbps for video and television traffic. These P-TE LSP1, P- TE LSP2, P-TE LSP3 and P-TE LSP4 should support DS-TE. [RFC4124] All PEs should choose an appropriate P-TE LSP based on preemption priority. K.Kumaki, et al. Expires August 31, 2007 [Page 8] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 To minimize the traffic disruption due to a single network failure, diversely routed C-TE LSPs are established. In this case, FRR [RFC4090] is not necessarily required. Also, unconstrained TE LSPs (i.e., C-TE LSPs/P-TE LSPs with 0 bandwidth) are applicable to this scenario. C-TE LSP1(P=0),2(P=1) (CE0->CE1->...->CE4->CE5) (CE0<-CE1<-...<-CE4<-CE5) <--------------------------------------------------> C-TE LSP3(P=0),4(P=1) (CE2->CE1->...->CE4->CE7) (CE2<-CE1<-...<-CE4<-CE7) <--------------------------------------------------> P-TE LSP1 (p=0) <-----------------------> P-TE LSP2 (p=1) <-----------------------> .................. .................. . --- --- . --- --- --- --- . --- --- . . |CE0|-|CE1|---|PE1|---|P1 |---|P2 |---|PE2|---|CE4|-|CE5| . . --- /--- --- . --- --- --- --- . --- ---\ --- . .|H0 | + . + . + |H1 |. . --- \--- --- . --- --- --- --- . --- ---/ --- . . |CE2|-|CE3|---|PE3|---|P3 |---|P4 |---|PE4|---|CE6|-|CE7| . . --- --- . --- --- --- --- . --- --- . .................. .................. <-----------------------> P-TE LSP3 (p=0) <-----------------------> P-TE LSP4 (p=1) <--------------------------------------------------> C-TE LSP5(P=0),6(P=1) (CE0->CE3->...->CE6->CE5) (CE0<-CE3<-...<-CE6<-CE5) <--------------------------------------------------> C-TE LSP7(P=0),8(P=1) (CE2->CE3->...->CE6->CE7) (CE2<-CE3<-...<-CE6<-CE7) <-----SP C-----> <--------BGP/MPLS IP-VPN-------> <-----SP C-----> network SP A network network Figure 4 Scenario III 6. Detailed Requirements This section describes detailed requirements for C-TE LSPs in L3VPN environments, especially BGP/MPLS IP-VPN environments. 6.1 Selective P-TE LSPs K.Kumaki, et al. Expires August 31, 2007 [Page 9] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 The solution MAY provide the ability to decide which P-TE LSP a PE uses for a C-TE LSP. When a PE receives a path message from a CE, it may be able to decide which P-TE LSP it uses. In this case, various kinds of P-TE LSPs exist in service provider network. For example, the PE MAY choose an appropriate P-TE LSP based on local policies such as: 1. preemption priority 2. affinity 3. class-type 4. on the data plane: (DSCP or EXP bits) 6.2 Graceful Restart Support for C-TE LSPs The solution SHOULD provide graceful restart for a C-TE LSP over vrf instance. Graceful restart mechanisms related to this architecture are described in [RFC3473] [RFC3623] [RFC4781]. 6.3 Rerouting Support for C-TE LSPs The solution MUST provide rerouting of a C-TE LSP in case of link/node/SRLG failures or preemption. Such rerouting may be controlled by a CE or by a PE. 6.4 FRR Support for C-TE LSPs The solution MUST support FRR [RFC4090] features for a C-TE LSP over vrf instance. In BGP/MPLS IP-VPN environments, a C-TE LSP from CE traverses over multiple PEs and Ps. To avoid link/node/SRLG failures needs to support a fast local protection or a fast path protection. 6.5 Admission Control Support on P-TE LSP Head-Ends The solution SHOULD support admission control on a transport TE LSP tunnel head-end. C-TE LSPs may potentially reserve over the bandwidth of a P-TE LSP. The transport TE LSP tunnel head-end SHOULD control the number of C-TE LSPs or the bandwidth of C-TE LSPs. For example, the transport TE LSP head-end have configurable limit on the maximum number of C-TE LSPs that it can admit. As for the amount of bandwidth can be reserved by C-TE LSPs: there could be two situations: 1. Let the P-TE LSP does its natural bandwidth admission 2. Set a cap on the amount of bandwidth 6.6 Policy Control Support for C-TE LSPs The solution MAY support policy control for a C-TE LSP at a PE. A PE receives RSVP control messages from a CE. The PE has the possibility that receives unexpected packets from the CE site. K.Kumaki, et al. Expires August 31, 2007 [Page 10] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 The PE MAY control RSVP control messages per vrf instance. Especially, if a CE is not managed by service providers, the PE has the high possibility that receives unexpected packets from the CE site. In this case, the PE should control RSVP control messages per vrf instance. In case that a transport TE LSP tunnel head-end controls the bandwidth of C-TE LSPs, an ingress policy can be applied on the customer facing interface on the PE to control the max reservable resources. Furthermore, PEs cooperated with Operating Support System (OSS) interpret a bandwidth customers require and may assign a bandwidth for a customer. 6.7 PCE Features Support for C-TE LSPs The solution MAY support PCE features for a C-TE LSP over vrf instance. When a C-TE LSP is provided, CEs, PEs and Ps may support PCE [RFC4655] [PCEP] features. In this case, CE routers or PE routers have PCC functions and PE routers and/or P routers have PCE functions. 6.8 Diversely Routed C-TE LSPs Support The solution SHOULD set up a diversely routed C-TE LSP over vrf instance. When a single CE has multiple uplinks which connect to different PEs, it is desirable that multiple C-TE LSPs over vrf instance are established between a pair of LSRs. When two CEs have multiple uplinks which connect to different PEs, it is desirable that multiple C-TE LSPs over vrf instance are established between two different pairs of LSRs. In these cases, for example, the following points will be beneficial to customers. - load balance of CE-to-CE traffic across diverse C-TE LSP so as to minimize the traffic disruption in case of a single network element failure - path protection (e.g. 1:1, 1:N) 6.9 Optimal Path Support for C-TE LSPs The solution MUST support an optimal path of a C-TE LSP over vrf instance. Depending on an application (e.g. voice, television and video), an optimal path is needed for a C-TE LSP over vrf instance. An optimal path may be a shortest path based on TE metric or IGP metric. K.Kumaki, et al. Expires August 31, 2007 [Page 11] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 6.10 Reoptimization Support for C-TE LSPs The solution MUST support reoptimization of a C-TE LSP over vrf instance. These LSPs must be reoptimized by make-before-break. In this case, it is desirable for a head-end LSR to be configured with regard to timer-based or event-driven reoptimization. Furthermore, customers should be able to reoptimize a C-TE LSP manually. To provide delay- or jitter-sensitive traffic (i.e. voice traffic), a C-TE LSP should be optimally established. 6.11 DS-TE Support for C-TE LSPs The solution SHOULD support DS-TE [RFC4124] features for a C-TE LSP over vrf instance. Applications, which have different traffic characteristics, are used in BGP/MPLS IP-VPN environments. Service providers try to achieve fine-grained optimization of transmission resources, efficiency and further enhanced network performance. It may be desirable to perform TE at a per-class 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 TE constraints which are specific to the given class. Requirements for DS-TE are described in [RFC3564]. 6.12 Complexity and Risks The solution SHOULD NOT introduce unnecessary complexity to the current operating network to such a degree that it would affect the stability and diminish the benefits of deploying such a solution over SP networks. 6.13 Backward Compatibility The deployment of C-TE LSPs SHOULD NOT impact existing MPLS TE mechanisms, but allow for a smooth migration or co-existence. 6.14 Scalability Considerations The solution MUST have a minimum impact on network scalability from a C-TE LSP over vrf instance. Scalability of C-TE LSPs MUST addresses the following consideration. - RSVP-TE (e.g. number of RSVP control messages, retained state, message size and so on). - BGP (e.g. number of routes, flaps, overloads events and so on). K.Kumaki, et al. Expires August 31, 2007 [Page 12] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 If the number of required C-TE LSPs increases, there would be scalability issues. In this case, PEs may support a hierarchical LSP [RFC4206]. 6.15 Performance Considerations The solution SHOULD be evaluated with regard to the following criteria. - Degree of path optimality of the C-TE LSP. - TE LSP setup time. - Failure and restoration time. - Impact and scalability of the control plane due to added overheads and so on. - Impact and scalability of the data/forwarding plane due to added overheads and so on. 6.16 Management Considerations Manageability of C-TE LSPs MUST addresses the following considerations for section 5. - Need for a MIB module for control plane and monitoring. - Need for diagnostic tools. MIB module for C-TE LSPs MUST collect per a vrf instance. If a CE is managed by service providers, MIB information for C-TE LSPs from the CE MUST be collected per a customer. Today, diagnostic tools can detect failures of control plane and data plane for general MPLS TE LSPs [RFC4379]. The diagnostic tools MUST detect failures of control and data plane for C-TE LSPs over a vrf instance. MPLS OAM for C-TE LSPs MUST be supported within the context of VRF except for the above. In BGP/MPLS IP-VPN environments, from a CE point of view, IP TTL decreases at a local PE and a remote PE. But from a PE point of view, both IP TTL and MPLS TTL decreases between PEs. 7. Security Considerations Security issues for C-TE LSPs relate to both control plane and data plane. In terms of control plane, a PE receives IPv4 or IPv6 RSVP control packets from a CE. If the CE is an untrusted router for service providers, the PE MUST be able to control IPv4 or IPv6 RSVP control K.Kumaki, et al. Expires August 31, 2007 [Page 13] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 packets. If the CE is a trusted router for service providers, the PE MAY be able to control IPv4 or IPv6 control packets. In terms of data plane, a PE receives labeled IPv4 or IPv6 data packets from a CE. If the CE is an untrusted router for service providers, the PE MUST be able to control labeled IPv4 or IPv6 data packets. If the CE is a trusted router for service providers, the PE MAY be able to control labeled IPv4 or IPv6 data packets. In BGP/MPLS IP-VPN environments, from a CE point of view, IP TTL should decrease at a local PE and a remote PE to hide service provider network topology. 8. IANA Considerations This requirement document makes no requests for IANA action. 9. Normative References [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC3473] Berger, L., "Generalized Multi-Protocol Label Switching (GMPLS) Signaling Resource ReserVation Protocol-Traffic Engineering (RSVP-TE) Extensions ", RFC 3473, January 2003. [RFC3564] Le Faucheur, F., and Lai, W., "Requirements for Support of Differentiated Services-aware MPLS Traffic Engineering ", RFC 3564, July 2003. [RFC3623] Moy, J., et al., "Graceful OSPF Restart", RFC3623, November 2003. [RFC4090] Pan, P., Swallow, G. and A. Atlas, "Fast Reroute Extensions to RSVP-TE for LSP Tunnels", RFC 4090, May 2005. [RFC4124] Le Faucheur, F., "Protocol Extensions for Support of Diffserv-aware MPLS Traffic Engineering", RFC 4124, June 2005. [RFC4206] Kompella, K., and Rekhter, Y., "Label Switched Paths (LSP) Hierarchy with Generalized Multi-Protocol Label Switching (GMPLS) Traffic Engineering (TE)", RFC 4206, October 2005. [RFC4364] Rosen, E., and Rekhter, Y., "BGP/MPLS IP Virtual Private Networks (VPNs)", RFC 4364, February 2006. K.Kumaki, et al. Expires August 31, 2007 [Page 14] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 [RFC4379] Kompella, K. and G. Swallow, "Detecting MPLS Data Plane Failures", RFC 4379, February 2006. [RFC4655] Farrel, A., Vasseur, J.-P., and J. Ash, "Path Computation Element (PCE) Architecture", RFC 4655, August 2006. [RFC4781] Rekhter, Y., and Aggarwal, R., "Graceful Restart Mechanism for BGP with MPLS", RFC 4781, January 2007. 10.Informative References [PCEP] Vasseur, J.-P., et al., "Path Computation Element(PCE) communication Protocol (PCEP) - Version 1", Work in Progress, February 2007. [RSVP-DSTE] Le Faucheur, F., et al., "Aggregation of RSVP Reservations over MPLS TE/DS-TE Tunnels", Work in Progress, September 2006. 11.Appendix A. - RSVP Aggregation over MPLS TE Tunnels on L3VPN Services This appendix describes an application scenario that expands the use of procedures presented in [RSVP-DSTE]. The customer in this case has two hosts connecting off CE1 and CE2 respectively. CE1 and CE2 are connected to PE1 and PE2 respectively within a VRF instance belonging to the same VPN. The requesting host (H1) may request to H2 an e2e path with bandwidth reservation of X. This reservation request from within the context of VRF will get aggregated onto a pre-established P-TE/DS-TE LSP based upon procedures similar to [RSVP-DSTE]. This is further illustrated in the diagram below: C-RSVP e2e path <----------------------------------------------> P-TE LSP <---------------------------> ............. ............. . --- --- . --- --- --- --- . --- --- . .|H1 | |CE1|-----|PE1|----|P1 |-----|P2 |----|PE2|-----|CE2| |H2 |. . --- --- . --- --- --- --- . --- --- . ............. ............. ^ ^ | | vrf instance vrf instance K.Kumaki, et al. Expires August 31, 2007 [Page 15] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 As in the case of [RSVP-DSTE], there may be multiple P-TE LSPs belonging to different DS-TE class-types. Local policies can be implemented to map the incoming RSVP path request from H1 to the P-TE LSP with the appropriate class-type. Please note that the e2e RSVP path request may also be initiated by the CE devices themselves acting as a VoIP codec for example. 12.Acknowledgments The author would like to express the thanks to Ron Bonica, Koh Yamashita, Miya Kohno, Tomohiro Otani for their helpful and useful comments and feedback. 13.Author's Addresses Kenji Kumaki (Editor) KDDI Corporation Garden Air Tower Iidabashi, Chiyoda-ku, Tokyo 102-8460, JAPAN Email: ke-kumaki@kddi.com Raymond Zhang BT Infonet 2160 E. Grand Ave. El Segundo, CA 90025 Email: raymond.zhang@bt.infonet.com 14.Intellectual Property Statement The IETF takes no position regarding the validity or scope of any Intellectual Property Rights or other rights that might be claimed to pertain to the implementation or use of the technology described in this document or the extent to which any license under such rights might or might not be available; nor does it represent that it has made any independent effort to identify any such rights. Information on the procedures with respect to rights in RFC documents can be found in BCP 78 and BCP 79. Copies of IPR disclosures made to the IETF Secretariat and any assurances of licenses to be made available, or the result of an attempt made to obtain a general license or permission for the use of such proprietary rights by implementers or users of this specification can be obtained from the IETF on-line IPR repository at http://www.ietf.org/ipr. The IETF invites any interested party to bring to its attention any copyrights, patents or patent applications, or other proprietary rights that may cover technology that may be required to implement K.Kumaki, et al. Expires August 31, 2007 [Page 16] draft-kumaki-l3vpn-e2e-rsvp-te-reqts-03 March 2007 this standard. Please address the information to the IETF at ietf-ipr@ietf.org. Disclaimer of Validity This document and the information contained herein are provided on an "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY, THE IETF TRUST AND THE INTERNET ENGINEERING TASK FORCE DISCLAIM 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. Copyright Statement Copyright (C) The IETF Trust (2007). This document is subject to the rights, licenses and restrictions contained in BCP 78, and except as set forth therein, the authors retain all their rights. Acknowledgement Funding for the RFC Editor function is currently provided by the Internet Society. K.Kumaki, et al. Expires August 31, 2007 [Page 17]