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RFC 4652

Evaluation of Existing Routing Protocols against Automatic Switched Optical Network (ASON) Routing Requirements

Pages: 22

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Network Working Group                              D. Papadimitriou, Ed.
Request for Comments: 4652                                       Alcatel
Category: Informational                                            L.Ong
                                                               J. Sadler
                                                                 S. Shew
                                                                 D. Ward
                                                            October 2006

           Evaluation of Existing Routing Protocols against
    Automatic Switched Optical Network (ASON) Routing Requirements

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 (2006).


The Generalized MPLS (GMPLS) suite of protocols has been defined to control different switching technologies as well as different applications. These include support for requesting TDM connections including Synchronous Optical Network/Synchronous Digital Hierarchy (SONET/SDH) and Optical Transport Networks (OTNs). This document provides an evaluation of the IETF Routing Protocols against the routing requirements for an Automatically Switched Optical Network (ASON) as defined by ITU-T.
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1. Introduction

Certain capabilities are needed to support the ITU-T Automatically Switched Optical Network (ASON) control plane architecture as defined in [G.8080]. [RFC4258] details the routing requirements for the GMPLS routing suite of protocols to support the capabilities and functionality of ASON control planes identified in [G.7715] and in [G.7715.1]. The ASON routing architecture provides for a conceptual reference architecture, with definition of functional components and common information elements to enable end-to-end routing in the case of protocol heterogeneity and to facilitate management of ASON networks. This description is only conceptual: no physical partitioning of these functions is implied. However, [RFC4258] does not address GMPLS routing protocol applicability or capabilities. This document evaluates the IETF Routing Protocols against the requirements identified in [RFC4258]. The result of this evaluation is detailed in Section 5. Close examination of applicability scenarios and the result of the evaluation of these scenarios are provided in Section 6. ASON (Routing) terminology sections are provided in Appendices A and B.

2. 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 RFC 2119 [RFC2119]. The reader is expected to be familiar with the terminology introduced in [RFC4258].

3. Contributors

This document is the result of the CCAMP Working Group ASON Routing Solution design team's joint effort. Dimitri Papadimitriou (Alcatel, Team Leader and Editor) EMail: Chris Hopps (Cisco) EMail: Lyndon Ong (Ciena Corporation) EMail: Jonathan Sadler (Tellabs) EMail:
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      Stephen Shew (Nortel Networks)
      Dave Ward (Cisco)

4. Requirements: Overview

The following functionality is expected from GMPLS routing protocols to instantiate the ASON hierarchical routing architecture realization (see [G.7715] and [G.7715.1]): - Routing Areas (RAs) shall be uniquely identifiable within a carrier's network, each having a unique RA Identifier (RA ID) within the carrier's network. - Within a RA (one level), the routing protocol shall support dissemination of hierarchical routing information (including summarized routing information for other levels) in support of an architecture of multiple hierarchical levels of RAs; the number of hierarchical RA levels to be supported by a routing protocol is implementation specific. - The routing protocol shall support routing information based on a common set of information elements as defined in [G.7715] and [G.7715.1], divided between attributes pertaining to links and abstract nodes (each representing either a sub-network or simply a node). [G.7715] recognizes that the manner in which the routing information is represented and exchanged will vary with the routing protocol used. - The routing protocol shall converge such that the distributed Routing DataBases (RDB) become synchronized after a period of time. To support dissemination of hierarchical routing information, the routing protocol must deliver: - Processing of routing information exchanged between adjacent levels of the hierarchy (i.e., Level N+1 and N), including reachability and (upon policy decision) summarized topology information. - Self-consistent information at the receiving level resulting from any transformation (filter, summarize, etc.) and forwarding of information from one Routing Controller (RC) to RC(s) at different levels when multiple RCs are bound to a single RA. - A mechanism to prevent re-introduction of information propagated into the Level N RA's RC back to the adjacent level RA's RC from which this information has been initially received.
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   Note: The number of hierarchical levels to be supported is routing
   protocol specific and reflects a containment relationship.

   Reachability information may be advertised either as a set of UNI
   Transport Resource address prefixes, or as a set of associated
   Subnetwork Point Pool (SNPP) link IDs/SNPP link ID prefixes, assigned
   and selected consistently in their applicability scope.  The formats
   of the control plane identifiers in a protocol realization are
   implementation specific.  Use of a routing protocol within a RA
   should not restrict the choice of routing protocols for use in other
   RAs (child or parent).

   As ASON does not restrict the control plane architecture choice,
   either a co-located architecture or a physically separated
   architecture may be used.  A collection of links and nodes, such as a
   sub-network or RA, must be able to represent itself to the wider
   network as a single logical entity with only its external links
   visible to the topology database.

5. Evaluation

This section evaluates support of existing IETF routing protocols with respect to the requirements summarized from [RFC4258] in Section 4. Candidate routing protocols are Interior Gateway Protocol (IGP) (OSPF and Intermediate System to Intermediate System (IS-IS)) and BGP. The latter is not addressed in the current version of this document. BGP is not considered a candidate protocol mainly because of the following reasons: - Non-support of TE information exchange. Each BGP router advertises only its path to each destination in its vector for loop avoidance, with no costs or hop counts; each BGP router knows little about network topology. - BGP can only advertise routes that are eligible for use (local RIB) or routing loops can occur; there is one best route per prefix, and that is the route that is advertised. - BGP is not widely deployed in optical equipment and networks.

5.1. Terminology and Identification

- Pi is a physical (bearer/data/transport plane) node. - Li is a logical control plane entity that is associated to a single data plane (abstract) node. The Li is identified by the TE Router_ID. The latter is a control plane identifier defined as follows:
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        [RFC3630]: Router_Address (top level) TLV of the Type 1 TE LSA
        [RFC3784]: Traffic Engineering Router ID TLV (Type 134)

     Note: This document does not define what the TE Router ID is.  This
     document simply states the use of the TE Router ID to identify Li.
     [RFC3630] and [RFC3784] provide the definitions.

   - Ri is a logical control plane entity that is associated to a
     control plane "router".  The latter is the source for topology
     information that it generates and shares with other control plane
     "routers".  The Ri is identified by the (advertising) Router_ID

        [RFC2328]: Router ID (32-bit)
        [RFC1195]: IS-IS System ID (48-bit)

     The Router_ID, which is represented by Ri and which corresponds to
     the RC_ID [RFC4258], does not enter into the identification of the
     logical entities representing the data plane resources such as
     links.  The Routing DataBase (RDB) is associated to the Ri.  Note
     that, in the ASON context, an arrangement consisting of multiple
     Ris announcing routing information related to a single Li is under

   Aside from the Li/Pi mappings, these identifiers are not assumed to
   be in a particular entity relationship except that the Ri may have
   multiple Lis in its scope.  The relationship between Ri and Li is
   simple at any moment in time: an Li may be advertised by only one Ri
   at any time.  However, an Ri may advertise a set of one or more Lis.
   Thus, the routing protocol MUST be able to advertise multiple TE
   Router IDs (see Section 5.7).

   Note: Si is a control plane signaling function associated with one or
   more Lis.  This document does not assume any specific constraint on
   the relationship between Si and Li.  This document does not discuss
   issues of control plane accessibility for the signaling function, and
   it makes no assumptions about how control plane accessibility to the
   Si is achieved.

5.2. RA Identification

G.7715.1 notes some necessary characteristics for RA identifiers, e.g., that they may provide scope for the Ri, and that they must be provisioned to be unique within an administrative domain. The RA ID format itself is allowed to be derived from any global address space. Provisioning of RA IDs for uniqueness is outside the scope of this document.
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   Under these conditions, GMPLS link state routing protocols provide
   the capability for RA Identification without further modification.

5.3. Routing Information Exchange

In this section, the focus is on routing information exchange Ri entities (through routing adjacencies) within a single hierarchical level. Routing information mapping between levels require specific processing (see Section 5.5). The control plane does not transport Pi identifiers, as these are data plane addresses for which the Li/Pi mapping is kept (link) local; see, for instance the transport LMP document [RFC4394] where such an exchange is described. Example: The transport plane identifier is the Pi (the identifier assigned to the physical element) that could be, for instance, "666B.F999.AF10.222C", whereas the control plane identifier is the Li (the identifier assigned by the control plane), which could be, for instance, "". The control plane exchanges the control plane identifier information, but not the transport plane identifier information (i.e., not "666B.F999.AF10.222C", but only ""). The mapping Li/Pi is kept local. So, when the Si receives a control plane message requesting the use of "", Si knows locally that this information refers to the data plane entity identified by the transport plane identifier "666B.F999.AF10.222C". Note also that the Li and Pi addressing spaces may be identical. The control plane carries: 1) its view of the data plane link end-points and other link connection end-points. 2) the identifiers scoped by the Lis, i.e., referred to as an associated IPv4/IPv6 addressing space. Note that these identifiers may be either bundled TE link addresses or component link addresses. 3) when using OSPF or ISIS as the IGP in support of traffic engineering, [RFC3477] RECOMMENDS that the Li value (referred to the "LSR Router ID") be set to the TE Router ID value. Therefore, OSPF and IS-IS carry sufficient node identification information without further modification.
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5.3.1. Link Attributes

[RFC4258] provides a list of link attributes and characteristics that need to be advertised by a routing protocol. All TE link attributes and characteristics are currently handled by OSPF and IS-IS (see Table 1) with the exception of Local Adaptation support. Indeed, GMPLS routing does not currently consider the use of dedicated TE link attribute(s) to describe the cross/inter-layer relationships. In addition, the representation of bandwidth requires further consideration. GMPLS Routing defines an Interface Switching Capability Descriptor (ISCD) that delivers information about the (maximum/ minimum) bandwidth per priority of which an LSP can make use. This information is usually used in combination with the Unreserved Bandwidth sub-TLV that provides the amount of bandwidth not yet reserved on a TE link. In the ASON context, other bandwidth accounting representations are possible, e.g., in terms of a set of tuples <signal_type; number of unallocated timeslots>. The latter representation may also require definition of additional signal types (from those defined in [RFC3946]) to represent support of contiguously concatenated signals, i.e., STS-(3xN)c SPE / VC-4-Nc, N = 4, 16, 64, 256. However, the method proposed in [RFC4202] is the most straightforward without requiring any bandwidth accounting change from an LSR perspective (in particular, when the ISCD sub-TLV information is combined with the information provided by the Unreserved Bandwidth sub-TLV).
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   Link Characteristics     GMPLS OSPF
   -----------------------  ----------
   Local SNPP link ID       Link-local part of the TE link identifier
                            sub-TLV [RFC4203]
   Remote SNPP link ID      Link remote part of the TE link identifier
                            sub-TLV [RFC4203]
   Signal Type              Technology specific part of the Interface
                            Switching Capability Descriptor sub-TLV
   Link Weight              TE metric sub-TLV [RFC3630]
   Resource Class           Administrative Group sub-TLV [RFC3630]
   Local Connection Types   Switching Capability field part of the
                            Interface Switching Capability Descriptor
                            sub-TLV [RFC4203]
   Link Capacity            Unreserved bandwidth sub-TLV [RFC3630]
                            Max LSP Bandwidth part of the Interface
                            Switching Capability Descriptor sub-TLV
   Link Availability        Link Protection sub-TLV [RFC4203]
   Diversity Support        SRLG sub-TLV [RFC4203]
   Local Adaptation support See above

                Table 1.  TE link attributes in GMPLS OSPF-TE

   Link Characteristics     GMPLS IS-IS
   -----------------------  -----------
   Local SNPP link ID       Link-local part of the TE link identifier
                            sub-TLV [RFC4205]
   Remote SNPP link ID      Link-remote part of the TE link identifier
                            sub-TLV [RFC4205]
   Signal Type              Technology specific part of the Interface
                            Switching Capability Descriptor sub-TLV
   Link Weight              TE Default metric [RFC3784]
   Resource Class           Administrative Group sub-TLV [RFC3784]
   Local Connection Types   Switching Capability field part of the
                            Interface Switching Capability Descriptor
                            sub-TLV [RFC4205]
   Link Capacity            Unreserved bandwidth sub-TLV [RFC3784]
                            Max LSP Bandwidth part of the Interface
                            Switching Capability Descriptor sub-TLV
   Link Availability        Link Protection sub-TLV [RFC4205]
   Diversity Support        SRLG sub-TLV [RFC4205]
   Local Adaptation support See above

               Table 2.  TE link attributes in GMPLS IS-IS-TE
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   Note: Link Attributes represent layer resource capabilities and
   their utilization i.e. the IGP should be able to advertise these
   attributes on a per-layer basis.

5.3.2. Node Attributes

Node attributes are the "Logical Node ID" (described in Section 5.1) and the reachability information described in Section 5.3.3.

5.3.3. Reachability Information

Advertisement of reachability can be achieved using the techniques described in [OSPF-NODE], where the set of local addresses are carried in an OSPF TE LSA node attribute TLV (a specific sub-TLV is defined per address family, e.g., IPv4 and IPv6). However, [OSPF-NODE] is restricted to advertisement of Host addresses and not prefixes, and therefore it requires enhancement (see below). Thus, in order to advertise blocks of reachable address prefixes a summarization mechanism is additionally required. This mechanism may take the form of a prefix length (which indicates the number of significant bits in the prefix) or a network mask. A similar mechanism does not exist for IS-IS. Moreover, the Extended IP Reachability TLV [RFC3784] focuses on IP reachable end-points (terminating points), as its name indicates.

5.4. Routing Information Abstraction

G.7715.1 describes both static and dynamic methods for abstraction of routing information for advertisement at a different level of the routing hierarchy. However, the information that is advertised continues to be in the form of link and node advertisements consistent with the link state routing protocol used at that level. Hence, no specific capabilities need to be added to the routing protocol beyond the ability to locally identify when routing information originates outside of a particular RA. The methods used for abstraction of routing information are outside the scope of GMPLS routing protocols.

5.5. Dissemination of Routing Information in Support of Multiple Hierarchal Levels of RAs

G.7715.1 does not define specific mechanisms to support multiple hierarchical levels of RAs beyond the ability to support abstraction as discussed above. However, if RCs bound to adjacent levels of the RA hierarchy are allowed to redistribute routing information in both
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   directions between adjacent levels of the hierarchy without any
   additional mechanisms, they would not be able to determine looping of
   routing information.

   To prevent this looping of routing information between levels, IS-IS
   [RFC1195] allows only advertising routing information upward in the
   level hierarchy and disallows the advertising of routing information
   downward in the hierarchy.  [RFC2966] defines the up/down bit to
   allow advertising downward in the hierarchy the "IP Internal
   Reachability Information" TLV (Type 128) and "IP External
   Reachability Information" TLV (Type 130).  [RFC3784] extends its
   applicability for the "Extended IP Reachability" TLV (Type 135).
   Using this mechanism, the up/down bit is set to 0 when routing
   information is first injected into IS-IS.  If routing information is
   advertised from a higher level to a lower level, the up/down bit is
   set to 1, indicating that it has traveled down the hierarchy.
   Routing information that has the up/down bit set to 1 may only be
   advertised down the hierarchy, i.e., to lower levels.  This mechanism
   applies independently of the number of levels.  However, this
   mechanism does not apply to the "Extended IS Reachability" TLV (Type
   22) used to propagate the summarized topology (see Section 5.3),
   traffic engineering information as listed in Table 1, as well as
   reachability information (see Section 5.3.3).

   OSPFv2 [RFC2328] prevents inter-area routes (which are learned from
   area 0) from being passed back to area 0.  However, GMPLS makes use
   of Type 10 (area-local scope) LSAs to propagate TE information
   [RFC3630], [RFC4202].  Type 10 Opaque LSAs are not flooded beyond the
   borders of their associated area.  It is therefore necessary to have
   a means by which Type 10 Opaque LSA may carry the information that a
   particular piece of routing information has been learned from a
   higher-level RC when propagated to a lower-level RC.  Any downward RC
   from this level, which receives an LSA with this information would
   omit the information in this LSA and thus not re-introduce this
   information back into a higher-level RC.

5.6. Routing Protocol Convergence

Link state protocols have been designed to propagate detected topological changes (such as interface failures and link attributes modification). The convergence period is short and involves a minimum of routing information exchange. Therefore, existing routing protocol convergence involves mechanisms that are sufficient for ASON applications.
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5.7. Routing Information Scoping

The routing protocol MUST support a single Ri advertising on behalf of more than one Li. Since each Li is identified by a unique TE Router ID, the routing protocol MUST be able to advertise multiple TE Router IDs. That is, for [RFC3630], multiple Router Addresses and for [RFC3784] multiple Traffic Engineering Router Ids. The Link sub-TLV that is currently part of the top level Link TLV associates the link to the Router_ID. However, having the Ri advertising on behalf of multiple Lis creates the following issue, as there is no longer a 1:1 relationship between the Router_ID and the TE Router_ID, but a 1:N relationship is possible (see Section 5.1). As the link-local and link-remote (unnumbered) ID association may not be unique per abstract node (per Li unicity), the advertisement needs to indicate the remote Lj value and rely on the initial discovery process to retrieve the {Li;Lj} relationship(s). In brief, as unnumbered links have their ID defined on per Li bases, the remote Lj needs to be identified to scope the link remote ID to the local Li. Therefore, the routing protocol MUST be able to disambiguate the advertised TE links so that they can be associated with the correct TE Router ID. Moreover, when the Ri advertises on behalf multiple Lis, the routing protocol MUST be able to disambiguate the advertised reachability information (see Section 5.3.3) so that it can be associated with the correct TE Router ID.

6. Evaluation Scenarios

The evaluation scenarios are the following; they are respectively referred to as cases 1, 2, 3, and 4. In Figure 1, below, - R3 represents an LSR with all components collocated. - R2 shows how the "router" component may be disjoint from the node. - R1 shows how a single "router" may manage multiple nodes.
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                -------------------     -------
               |R1                 |   |R2     |
               |                   |   |       |    ------
               |  L1    L2    L3   |   |   L4  |   |R3    |
               |   :     :     :   |   |   :   |   |      |
               |   :     :     :   |   |   :   |   |  L5  |
   Control      ---+-----+-----+---     ---+---    |   :  |
   Plane           :     :     :           :       |   :  |
   Data            :     :     :           :       |   :  |
   Plane          --     :    --          --       |  --  |
                  -- \   :  / --          --       |  --  |
                      \ -- /                       |      |
                       |P2|                         ------

                Figure 1.  Evaluation Cases 1, 2, and 3

   Case 1 as represented refers either to direct links between edges or
   to "logical links" as shown in Figure 2 (or any combination of them).

                   ------                        ------
                  |      |                      |      |
                  |  L1  |                      |  L2  |
                  |  :   |                      |  :   |
                  |  : R1|                      |  : R2|
   Control Plane   --+---                        --+---
   Elements          :                             :
   Data Plane        :                             :
   Elements          :                             :
                |    :                             :     |
                |   ---            ---            ---    |
                |  |   |----------| P |----------|   |   |
             ---+--|   |           ---           |   |---+---
                |  |   |                         |   |   |
                |  | P1|-------------------------| P2|   |
                |   ---                           ---    |

                    Figure 2.  Case 1 with Logical Links

   Another case (referred to as Case 4) is constituted by the Abstract
   Node as represented in Figure 3.  There is no internal structure
   associated (externally) to the abstract node.
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                      |R4            |
                      |              |
                      |      L6      |
                      |       :      |
                      |    ......    |
   Control Plane          :      :
   Data Plane             :      :
                      |P8 :      :   |
                      |  --      --  |
                    --+-|P |----|P |-+--
                      |  --      --  |

                      Figure 3.  Case 4: Abstract Node

   Note: the "signaling function" referred to as Si, i.e., the control
   plane entity that processes the signaling messages, is not
   represented in these figures.

7. Summary of Necessary Additions to OSPF and IS-IS

The following sections summarize the additions to be provided to OSPF and IS-IS in support of ASON routing.

7.1. OSPFv2

Reachability Extend Node Attribute sub-TLVs to support address prefixes (see Section 5.3.3). Link Attributes Representation of cross/inter-layer relationships in link top-level link TLV (see Section 5.3.1). Optionally, provide for per-signal-type bandwidth accounting (see Section 5.3.1). Scoping TE link advertisements to allow for retrieving their respective local-remote TE Router_ID relationship(s) (see Section 5.7). Prefixes part of the reachability advertisement (using Node Attribute top-level TLV) needs to be associated to its respective local TE Router_ID (see Section 5.7).
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   Hierarchy         Provide a mechanism by which Type 10 Opaque LSA may
                     carry the information that a particular piece of
                     routing information has been learned from a
                     higher-level RC when propagated to a lower-level RC
                     (so as not to re-introduce this information into a
                     higher-level RC).

7.2. IS-IS

Reachability Provide for reachability advertisement (in the form of reachable TE prefixes). Link Attributes Representation of cross/inter-layer relationships in Extended IS Reachability TLV (see Section 5.3.1). Optionally, provide for per-signal-type bandwidth accounting (see Section 5.3.1). Scoping Extended IS Reachability TLVs to allow for retrieving their respective local-remote TE Router_ID relationship(s) (see Section 5.7). Prefixes part of the reachability advertisement needs to be associated to its respective local TE Router_ID (see Section 5.7). Hierarchy Extend the up/down bit mechanisms to propagate the summarized topology (see Section 5.3) and traffic engineering information as listed in Table 1, as well as reachability information (see Section 5.3.3).

8. Security Considerations

The introduction of a dynamic control plane to an ASON network exposes it to additional security risks that may have been controlled or limited by the use of management plane solutions. The routing protocols play a part in the control plane and may be attacked so that they become unstable or provide incorrect information for use in path computation or by the signaling protocols. Nevertheless, there is no reason why the control plane components cannot be secured, and the security mechanisms developed for the routing protocol and used within the Internet are equally applicable within an ASON context.
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   [RFC4258] describes the requirements for security of routing
   protocols for the Automatically Switched Optical Network.  Reference
   is made to [M.3016], which lays out the overall security objectives
   of confidentiality, integrity, and accountability.  These are well
   discussed for the Internet routing protocols in [THREATS].

   A detailed discussion of routing threats and mechanisms that are
   currently deployed in operational networks to counter these threats
   is found in [OPSECPRACTICES].  A detailed listing of the device
   capabilities that can be used to support these practices can be found
   in [RFC3871].

9. Acknowledgements

The authors would like to thank Adrian Farrel for having initiated the proposal of an ASON Routing Solution Design Team and the ITU-T SG15/Q14 for their careful review and input.

10. References

10.1. Normative References

[RFC1195] Callon, R., "Use of OSI IS-IS for routing in TCP/IP and dual environments", RFC 1195, December 1990. [RFC2966] Li, T., Przygienda, T., and H. Smit, "Domain-wide Prefix Distribution with Two-Level IS-IS", RFC 2966, October 2000. [RFC2328] Moy, J., "OSPF Version 2", STD 54, RFC 2328, April 1998. [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC3477] Kompella, K. and Y. Rekhter, "Signalling Unnumbered Links in Resource ReSerVation Protocol - Traffic Engineering (RSVP-TE)", RFC 3477, January 2003. [RFC3630] Katz, D., Kompella, K., and D. Yeung, "Traffic Engineering (TE) Extensions to OSPF Version 2", RFC 3630, September 2003. [RFC3784] Smit, H. and T. Li, "Intermediate System to Intermediate System (IS-IS) Extensions for Traffic Engineering (TE)", RFC 3784, June 2004.
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   [RFC3871]         Jones, G., Ed., "Operational Security Requirements
                     for Large Internet Service Provider (ISP) IP
                     Network Infrastructure", RFC 3871, September 2004.

   [RFC3946]         Mannie, E. and D. Papadimitriou, "Generalized
                     Multi-Protocol Label Switching (GMPLS) Extensions
                     for Synchronous Optical Network (SONET) and
                     Synchronous Digital Hierarchy (SDH) Control", RFC
                     3946, October 2004.

   [RFC4202]         Kompella, K., Ed., and Y. Rekhter, Ed., "Routing
                     Extensions in Support of Generalized Multi-Protocol
                     Label Switching (GMPLS)", RFC 4202, October 2005.

   [RFC4203]         Kompella, K., Ed., and Y. Rekhter, Ed., "OSPF
                     Extensions in Support of Generalized Multi-Protocol
                     Label Switching (GMPLS)", RFC 4203, October 2005.

   [RFC4205]         Kompella, K., Ed., and Y. Rekhter, Ed.,
                     "Intermediate System to Intermediate System (IS-IS)
                     Extensions in Support of Generalized Multi-Protocol
                     Label Switching (GMPLS)", RFC 4205, October 2005.

   [RFC4258]         Brungard, D., "Requirements for Generalized Multi-
                     Protocol Label Switching (GMPLS) Routing for the
                     Automatically Switched Optical Network (ASON)", RFC
                     4258, November 2005.

10.2. Informative References

[RFC4394] Fedyk, D., Aboul-Magd, O., Brungard, D., Lang, J., and D. Papadimitriou, "A Transport Network View of the Link Management Protocol (LMP)", RFC 4394, February 2006. [OPSECPRACTICES] Kaeo, M., "Operational Security Current Practices", Work in Progress, July 2006. [OSPF-NODE] Aggarwal, R. and K. Kompella, "Advertising a Router's Local Addresses in OSPF TE Extensions", Work in Progress, June 2006. [THREATS] Barbir, A., Murphy, S., and Y. Yang, "Generic Threats to Routing Protocols", RFC 4593, October 2006.
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   For information on the availability of ITU Documents, please see

   [G.7715]          ITU-T Rec. G.7715/Y.1306, "Architecture and
                     Requirements for the Automatically Switched Optical
                     Network (ASON)", June 2002.

   [G.7715.1]        ITU-T Draft Rec. G.7715.1/Y.1706.1, "ASON Routing
                     Architecture and Requirements for Link State
                     Protocols", November 2003.

   [G.8080]          ITU-T Rec. G.8080/Y.1304, "Architecture for the
                     Automatically Switched Optical Network (ASON)",
                     June 2006.

   [M.3016]          ITU-T Rec. M.3016.0, "Security for the Management
                     Plane:  Overview", May 2005.
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Appendix A. ASON Terminology

This document makes use of the following terms: Administrative domain (see Recommendation G.805): For the purposes of [G.7715.1], an administrative domain represents the extent of resources that belong to a single player such as a network operator, a service provider, or an end-user. Administrative domains of different players do not overlap amongst themselves. Control plane: Performs the call control and connection control functions. Through signaling, the control plane sets up and releases connections and may restore a connection in case of a failure. (Control) Domain: Represents a collection of (control) entities that are grouped for a particular purpose. The control plane is subdivided into domains matching administrative domains. Within an administrative domain, further subdivisions of the control plane are recursively applied. A routing control domain is an abstract entity that hides the details of the RC distribution. External NNI (E-NNI): Interfaces are located between protocol controllers between control domains. Internal NNI (I-NNI): Interfaces are located between protocol controllers within control domains. Link (see Recommendation G.805): A "topological component" that describes a fixed relationship between a "subnetwork" or "access group" and another "subnetwork" or "access group". Links are not limited to being provided by a single server trail. Management plane: Performs management functions for the Transport Plane, the control plane, and the system as a whole. It also provides coordination between all the planes. The following management functional areas are performed in the management plane: performance, fault, configuration, accounting, and security management Management domain (see Recommendation G.805): A management domain defines a collection of managed objects that are grouped to meet organizational requirements according to geography, technology, policy, or other structure, and for a number of functional areas such as fault, configuration, accounting, performance, and security (FCAPS), for the purpose of providing control in a consistent manner. Management domains can be disjoint, contained, or overlapping. As such, the resources within an administrative domain can be distributed into several possible overlapping management domains.
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   The same resource can therefore belong to several management domains
   simultaneously, but a management domain shall not cross the border of
   an administrative domain.

   Subnetwork Point (SNP): The SNP is a control plane abstraction that
   represents an actual or potential transport plane resource.  SNPs (in
   different subnetwork partitions) may represent the same transport
   resource.  A one-to-one correspondence should not be assumed.

   Subnetwork Point Pool (SNPP): A set of SNPs that are grouped together
   for the purposes of routing.

   Termination Connection Point (TCP): A TCP represents the output of a
   Trail Termination function or the input to a Trail Termination Sink

   Transport plane: Provides bi-directional or unidirectional transfer
   of user information, from one location to another.  It can also
   provide transfer of some control and network management information.
   The Transport Plane is layered; it is equivalent to the Transport
   Network defined in G.805 Recommendation.

   User Network Interface (UNI): Interfaces are located between protocol
   controllers between a user and a control domain.  Note: There is no
   routing function associated with a UNI reference point.

Appendix B. ASON Routing Terminology

This document makes use of the following terms: Routing Area (RA): An RA represents a partition of the data plane, and its identifier is used within the control plane as the representation of this partition. Per [G.8080], an RA is defined by a set of sub-networks, the links that interconnect them, and the interfaces representing the ends of the links exiting that RA. An RA may contain smaller RAs inter-connected by links. The limit of subdivision results in an RA that contains two sub-networks interconnected by a single link. Routing Database (RDB): Repository for the local topology, network topology, reachability, and other routing information that is updated as part of the routing information exchange and that may additionally contain information that is configured. The RDB may contain routing information for more than one Routing Area (RA).
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   Routing Components: ASON routing architecture functions.  These
   functions can be classified as being protocol independent (Link
   Resource Manager or LRM, Routing Controller or RC) and protocol
   specific (Protocol Controller or PC).

   Routing Controller (RC): Handles (abstract) information needed for
   routing and the routing information exchange with peering RCs by
   operating on the RDB.  The RC has access to a view of the RDB.  The
   RC is protocol independent.

   Note: Since the RDB may contain routing information pertaining to
   multiple RAs (and possibly to multiple layer networks), the RCs
   accessing the RDB may share the routing information.

   Link Resource Manager (LRM): Supplies all the relevant component and
   TE link information to the RC.  It informs the RC about any state
   changes of the link resources it controls.

   Protocol Controller (PC): Handles protocol-specific message exchanges
   according to the reference point over which the information is
   exchanged (e.g., E-NNI, I-NNI) and internal exchanges with the RC.
   The PC function is protocol dependent.
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Authors' Addresses

Dimitri Papadimitriou, Ed. Alcatel Francis Wellensplein 1, B-2018 Antwerpen, Belgium Phone: +32 3 2408491 EMail: Lyndon Ong Ciena Corporation PO Box 308 Cupertino, CA 95015 , USA Phone: +1 408 705 2978 EMail: Jonathan Sadler Tellabs 1415 W. Diehl Rd Naperville, IL 60563 EMail: Stephen Shew Nortel Networks 3500 Carling Ave. Ottawa, Ontario, CANADA K2H 8E9 Phone: +1 613 7632462 EMail: Dave Ward Cisco Systems 170 W. Tasman Dr. San Jose, CA 95134 USA Phone: +1-408-526-4000 EMail:
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