Network Working Group O. Gonzalez de Dios, Ed.
Internet-Draft Telefonica GCTO
Intended status: Informational J. Meuric, Ed.
Expires: August 18, 2014 Orange
D. Ceccarelli
Ericsson
February 14, 2014

Terminology and Models for Control of Traffic Engineered Networks with Provider-Customer Relationship
draft-dios-ccamp-control-models-customer-provider-00

Abstract

Different kinds of relationships can be established among interconnected Traffic Engineered Networks. In particular, this document focuses on the case where there is a customer-provider relation between the network domains. The domain interconnection is a policy and administrative boundary. This informational document collects current terminology and provides a taxonomy for the posible control plane based operation models.

Each control model defines, on the one hand, the level of information that the domain acting as customer receives by control plane means from the domain acting as provider and, on the other hand, the control model will determine what can be requested from the customer domain to the provider domain.

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Table of Contents

1. Introduction

Traffic Engineered Networks can be interconnected, establishing different types of relationships among them. For example, both network can have a peering relation, where connections starting in one domain and end in the other domain. This document is focused on the case where the interconnected network domains have a customer-provider relationship among them. Such customer-provider relation comes from the two main points. On the one hand, end-to-end services in the customer network can be set up using services of a network acting as provider. On the other hand, the customer-provider relation comes from the fact that their interconnection is a policy and administrative boundary, limiting the amount of information allowed to be exchanged between networks. In the case of interconnected TE domains where there is no administrative nor strict policy boundary between customer and provider (typically, just a technolgy change), the MLN/MRN model can be applied.

The interface between the customer and the provider domain is typically called "User-to-Network Interface" (UNI), and regarded as signaling-only [RFC4208]. Due to the strict asociation of functionality to the UNI term, its exact scope has become highly controversial. This document compiles different definitions of the term used so far and propose some terminology to serve as a foundation to move the work forward.

What is more, the document compiles the possible operation models of customer-provider network from the control plane perspective. Each control model defines, on the one hand, the level of information of the domain acting as customer provides through the control plane to the domain acting as provider. On the other hand, the control model will determine what can be requested from the customer domain to the provider domain.

1.1. Examples of Customer-Provider TE Network Domain Scenarios

The most typical example of interconnected TE domains that follow a customer-provider relation is an IP/MPLS domain using the services of an optical OTN/WDM network. Note that the interconnected domain can be part of the same organization, but with different administration.

A particular network scenario that has attracted lot of attention from the industry is the IP/MPLS/OTN/WDM over WDM. The customer network is based on multi-layer routers able to set up packet-based TE connections over wavelengths. The provider network is a WDM optical network that provides the switching for the wavelenghts as well as restoration capabilities of the optical channels.

Another example is MPLS over MPLS, where both customer and provider networks are able to set up packet based TE connections. This is the case, for example, of carrier-over-carrier scenarios.

Summing up, there number of applicable scenarios is wide.

2. Terminology

2.1. Customer Domain - Provider Domain Interface

The interface between the customer and the provider domain is typically called "User-to-Network Interface" (UNI). However, the term "UNI" has been used in different contexts and SDOs. As a consequence, the exact definition of UNI and the functionalities included depend on the application. Bellow, as a reference, it is shown a set of the different definitions of UNI.

2.1.1. UNI in IP over Optical Networks

[RFC3717] says: "The client-optical internetwork interface (UNI) represents a service boundary between the client (e.g., IP router) and the optical network. The client and server (optical network) are essentially two different roles: the client role requests a service connection from a server; the server role establishes the connection to fulfill the service request -- provided all relevant admission control conditions are satisfied."

In other words, this definition refers to a signaling protocol between two administrative domains with a customer-provider relationship. It is agnostic to the existence of a data plane client-server relationship and to the side(s) of the boundary where it may happen, if any.

2.1.2. ITU-T Definition of UNI

ITU-T has defined the term UNI in the context of control plane. [G.807] [G.8081] (ITU-T): "User-Network Interface for the control plane (UNI): A bidirectional signaling interface between service requester and service provider control plane entities."

The terms "requester/provider" are used to refer to the relationship.

2.1.3. OIF Definition of UNI

UNI: "The service control interface between a client device and the transport network."

UNI-C: "The logical entity that terminates UNI signalling on the client device side."

UNI-N: "The logical entity that terminates UNI signalling on the transport network side."

The terms "client/transport" and "client/network" are used to refer to the relationship.

2.1.4. Proposed Vocabulary

As listed above, the existing terminology is far from unique. To avoid overloaded concepts, this document proposes to use the "customer/provider" terms.

Unless stated, this document focuses on control protocol exchanges and their uses across administrative boundaries for customer-provider interconnection. Data plane transition and/or client-server relationship may not be aligned with the boundary.

2.1.4.1. Customer network

A Customer network is defined as a network domain able to request a connectivity service to a provider network domain across an administrative boundary.

2.1.4.2. Provider network

A Provider network is defined as a network domain able to deliver connectivity services to a customer network domain across an administrative boundary.

2.1.4.3. Customer-Provider Control Plane Interface

The control plane interface between the customer network domain and the provider network domain convey a set of control functionalities that help to operate such kind of networks. The exact functionalities of this Interface (and then the level of information exchanged) depend on the chosen control model. This document presents a taxonomy with the possible control models.

2.2. Reachability

In graph theory, reachability refers to the ability to get from one vertex to another within a graph. Thus, a vertex can reach another vertex if there exists a sequence of adjacent vertices which starts with the source vertex and ends with the destination vertex.

The document [draft-farrel-interconnected-te-info-exchange-02] provides the definition of what is reachability for client-server networks. [EDITOR's note: Text from draft-farrel-interconnected-te-info-exchange has been borrowed for this first version. Duplicated text will be deleted at later stages]

In an IP network, reachability is the ability to deliver a packet to a specific address or prefix. That is, the existence of an IP path to that address or prefix. TE reachability is the ability to reach a specific address along a TE path.

In the context of Traffic Engineered networks with customer and provider relationships, we can define several types of reachabiity: [draft-farrel-interconnected-te-info-exchange-02]

2.2.1. Unqualified Reachability

Two customer domain nodes are said to be reachable if, either there exists at least one path through the customer domain that connects both nodes, or, in the case that there is no path exclusively through the customer domain network, there exists al least one path connecting nodes of customer and provider domain by which both customer nodes can be connected.

In the case of basic reachability, it is only known that it is possible to connect the nodes, but there is no notion of the details of such possible connections, such as, for example, bandwidth available or performance metrics. Also, the exact path to connect both nodes is not known to the client network. Note that, even if two nodes are reachable, there may not be enough resources for a desired TE connection with specific TE constraints.

2.2.2. Qualified Reachability

In this case, on top of the basic reachability, it is known some TE attributes of the possible connection (or connections). Examples of such attributes are: TE metrics, hop count, available bandwidth, delay, SRLG list. Note that this information is specific per connection. Thus, if there are several posible TE paths, there are a set of attributes.

2.2.3. Qualified Reachability with associated potential TE path

In this particular case, on top of the qualified reachability, there exists an associated potential TE path that satisfies the TE connection between two client nodes. Thus, in this case, the customer Network has the information that there exists a TE path that can be set up at any time.

3. Control Models

The control of the networks formed by interconnected domains with a customer-provider relations between them can be done following different models. Each control model defines, on the one hand, the level of information that the domain acting as customer recieves by control plane means about the services given by the domain acting as provider. This information, for example, can vary from a complete lack of information, so the customer domain only knows that it could be possible to reach another point of its domain via the provider network, to a detailed view on the possibilities offered by the provider network. The level of detail of this information will determine which information is exchanged between both networks. On the other hand, the control model will determine what can be requested from the customer domain to the provider domain. As an example, the most basic use is spcecifying just the end-points to connect. Other cases may include the possibility to request a service specifying a set of constraints, like bandwidth, diversity, an optimization criteria, etc.

Which control model to choose depends on several factors. For the network operators, the main concern will be related to the level of trustness and relationship between customer and provider domains. Also, one key factor to take into account is the protocol interoperability. Note that, equipment in the interconnected domains may be from different technologies (but not necessarily) and are likely to use different implementations. The higher the level of functionality included in the control plane, the higher the protocol interoperability requirements, as it will force all implementations to support many functionality. Finally, scalability, that is, the ability of the control plane to provide the same functionality regarding the number of equipment, needs to be taken into account: the amount of information in each option will have different limits in terms on number of interconnected nodes.

3.1. Signaling Only

This first model considers that the sole functionality allowed in the control plane is signaling, that is the ability to request services from customer to provider domain.

In this model, the control plane does not provide a priori hints to the customer domain about the state of the provider domain (e.g., resource availability). This model does not preclude that, by other means like the management plane, the customer domain know what is possible or not. Such management actions are out of the scope of the control plane. Thus, it perfectly feasible that the reachability information is provided either statically or by some management platform.

The most basic case relies on sending a loose ERO from the customer, specifying the edges of the connection.

In a trusted interconnection mode, the signalling allows the customer domain to provide a full ERO, given to client network by external tools.

3.1.1. Signaling with Requirements

The control plane may allow to express complex requests to the provider domain. That is, through the signaling protocol, it is allowed to not only request a connection between two points of the customer domain, but also to include some constraints: e.g., minimum bandwidth, maximum delay, optimization criteria, or request diversity from another service. The policy at the edged of the provider network will determine which constraints are accepted. Note the many of the requirements that can be expressed in the request are similar to what would be asked to a path computation function.

3.1.2. Signaling with Collection

Even though the only protocol enabled is signaling, it may be beneficial for the customer domain to be able to know some updated information of the services that it has requested to the provider. Thus, this case considers the possibility that, through the signaling protocol, the customer domain can receive some information. What information it is allowed to collect will be determined by the policy of the provider domain.

3.2. Signaling and Reachability Model

This second model considers that, in addition to signaling, the customer domain receives some reachability information through a control plane mechanism.

3.2.1. Signalling + Basic Reachability

In this particular case, through control plane mechanisms, the customer domain knows whether it is possible to reach a remote end point. The customer domain should also remain aware of this information if there are failures in the provider domain or if the associated capacity has been filled.

3.2.2. Signalling + Qualified Reachability

The control plane will provide information not only about the possibility to reach a remote end point, but also some TE information of possible connections. For example, the customer domain will know that it is possible to reach another point with some bandwidth or delay. Note that, in this case, such information is sent by control plane mechanisms (not statically configured by managament plane).

3.2.3. Signalling + Qualified Reachability + Potential Services

In addition to the TE information of the possible connections between two points, the control plane will also provide to the customer domain information about potential provider's services which could satisfy given requirements. By control plane procedures, the customer domain can request, with respect to its needs, a service using such potential service and make high level path selection within the provider domain.

3.3. Other Models

3.3.1. Multi-Layer Networks / Multi-Region Networks

MLN/MRN extensions to control protocols have been defined. They are well scoped for client and server data plane domains without administrative boundary between them. This allows MLN nodes to participate in common control protocol instances. There is a full set of mechanisms to operate such networks [Editor's note: add refs to MLN/MRN)]. Typical use cases are switches combining both low- and high-order Sonet/SDH, or both ODUk and wavelengths.

However, MLN/MRN assumes no policy boundary between customer and provider domains. Thus, the level of information exchanged is not restricted, and full interoperability of both the signaling and routing protocols is required.

3.3.2. Management Model

In this particular case, the role of the control plane is limited to operate independently in each of the domains. [Editor's note: Common Control... WG => do we leave it?]

4. Security Considerations

TBD

5. Contributing Authors

6. Acknowledgments

The authors would like to thank Lou Berger for pointing out the direction of the document and Dieter Beler for his review. The authors would like to specially thank all the authors of draft-farrel-interconnected-te-info-exchange-02

7. References

7.1. Normative References

[RFC4208] Swallow, G., Drake, J., Ishimatsu, H. and Y. Rekhter, "Generalized Multiprotocol Label Switching (GMPLS) User-Network Interface (UNI): Resource ReserVation Protocol-Traffic Engineering (RSVP-TE) Support for the Overlay Model", RFC 4208, October 2005.
[RFC3107] Rekhter, Y. and E. Rosen, "Carrying Label Information in BGP-4", RFC 3107, May 2001.
[RFC3717] Rajagopalan, B., Luciani, J. and D. Awduche, "IP over Optical Networks: A Framework", RFC 3717, March 2004.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997.

7.2. Informative References

, "
[draft-farrel-interconnected-te-info-exchange-02]Farrel, A., Drake, J., Bitar, N., Swallow, G., Ceccarelli, D. draft-farrel-interconnected-te-info-exchange-02 Problem Statement and Architecture for Information Exchange Between Interconnected Traffic Engineered Networks", 2014.

Authors' Addresses

Oscar Gonzalez de Dios (editor) Telefonica GCTO Don Ramon de la Cruz 82-84 Madrid, 28045 Spain Phone: +34913128832 EMail: ogondio@tid.es
Julien Meuric (editor) Orange 2 avenue Pierre Marzin Lannion, 22300 France EMail: julien.meuric@orange.com
Daniele Ceccarelli Ericsson Via Calda 5 Genova, Italy Phone: +39 010 600 2512 EMail: daniele.ceccarelli@ericsson.com