Locator/ID Separation Protocol (lisp) Internet Drafts

LISP YANG Model

	draft-ietf-lisp-yang-21.txt
	Date:	15/04/2024
	Authors:	Vina Ermagan, Alberto Rodriguez-Natal, Florin Coras, Carl Moberg, Reshad Rahman, Albert Cabellos-Aparicio, Fabio Maino
	Working Group:	Locator/ID Separation Protocol (lisp)

This document describes a YANG data model to use with the Locator/ID Separation Protocol (LISP). The YANG modules in this document conform to the Network Management Datastore Architecture (NMDA).

LISP Traffic Engineering

	draft-ietf-lisp-te-15.txt
	Date:	22/04/2024
	Authors:	Dino Farinacci, Michael Kowal, Parantap Lahiri
	Working Group:	Locator/ID Separation Protocol (lisp)

This document describes how LISP re-encapsulating tunnels can be used for Traffic Engineering purposes. The mechanisms described in this document require no LISP protocol changes but do introduce a new locator (RLOC) encoding. The Traffic Engineering features provided by these LISP mechanisms can span intra-domain, inter-domain, or combination of both.

LISP Mobile Node

	draft-ietf-lisp-mn-15.txt
	Date:	14/01/2024
	Authors:	Dino Farinacci, Darrel Lewis, David Meyer, Chris White
	Working Group:	Locator/ID Separation Protocol (lisp)

This document describes how a lightweight version of LISP's ITR/ETR functionality can be used to provide seamless mobility to a mobile node. The LISP Mobile Node design described in this document uses standard LISP functionality to provide scalable mobility for LISP mobile nodes.

LISP L2/L3 EID Mobility Using a Unified Control Plane

	draft-ietf-lisp-eid-mobility-13.txt
	Date:	06/11/2023
	Authors:	Marc Portoles-Comeras, Vrushali Ashtaputre, Fabio Maino, Victor Moreno, Dino Farinacci
	Working Group:	Locator/ID Separation Protocol (lisp)

The LISP control plane offers the flexibility to support multiple overlay flavors simultaneously. This document specifies how LISP can be used to provide control-plane support to deploy a unified L2 and L3 overlay solution for End-point Identifier (EID) mobility, as well as analyzing possible deployment options and models.

LISP Predictive RLOCs

	draft-ietf-lisp-predictive-rlocs-14.txt
	Date:	19/02/2024
	Authors:	Dino Farinacci, Padma Pillay-Esnault
	Working Group:	Locator/ID Separation Protocol (lisp)

This specification describes a method to achieve near-zero packet loss when an EID is roaming quickly across RLOCs.

LISP EID Anonymity

	draft-ietf-lisp-eid-anonymity-16.txt
	Date:	19/02/2024
	Authors:	Dino Farinacci, Padma Pillay-Esnault, Wassim Haddad
	Working Group:	Locator/ID Separation Protocol (lisp)

This specification will describe how ephemeral LISP EIDs can be used to create source anonymity. The idea makes use of frequently changing EIDs much like how a credit-card system uses a different credit-card numbers for each transaction.

LISP Control-Plane ECDSA Authentication and Authorization

	draft-ietf-lisp-ecdsa-auth-12.txt
	Date:	19/02/2024
	Authors:	Dino Farinacci, Erik Nordmark
	Working Group:	Locator/ID Separation Protocol (lisp)

This draft describes how LISP control-plane messages can be individually authenticated and authorized without a a priori shared- key configuration. Public-key cryptography is used with no new PKI infrastructure required.

Network-Hexagons:Geolocation Mapping Network Based On H3 and LISP

	draft-ietf-lisp-nexagon-52.txt
	Date:	24/12/2023
	Authors:	Sharon Barkai, Bruno Fernandez-Ruiz, Rotem Tamir, Alberto Rodriguez-Natal, Fabio Maino, Albert Cabellos-Aparicio, Jordi Paillisse, Dino Farinacci
	Working Group:	Locator/ID Separation Protocol (lisp)

This specification describes functionality of LISP Nexagon networks. The network shares a joint vision of any number of producing sources, fleets, drones, and satellite, with any number of consuming clients, maps, GIS, and path planning copilots. Specifically it outlines: - joint-vision tiled enumeration geolocation language channels - addressing change notifications, overlaps, points of view, - freshness, privacy, localization, seamless context-switching, - via stateful driving of stateless models by EID location agents Safety applications of this network are: 1. Safety on-road: blockages & hazards beyond line of sight 2. Safety off-road: traffic-ability and varying risk degrees 3. Safety during disasters: fires, floods, snow, abrupt change The use of LISP enables the network to function securely uninterrupted while vision producers and consumers are constantly moving due to the connectivity-anchoring properties of LISP EIDs. Since EIDs are logical being based on mapping-system, it provides semantic-anchoring as well. Semantic joint vision consolidation uses H3 EID unicast and multicast.

LISP Map Server Reliable Transport

	draft-ietf-lisp-map-server-reliable-transport-04.txt
	Date:	21/04/2024
	Authors:	Balaji Venkatachalapathy, Marc Portoles-Comeras, Darrel Lewis, Isidor Kouvelas, Chris Cassar
	Working Group:	Locator/ID Separation Protocol (lisp)

The communication between LISP ETRs and Map-Servers is based on unreliable UDP message exchange coupled with periodic message transmission in order to maintain soft state. The drawback of periodic messaging is the constant load imposed on both the ETR and the Map-Server. New use cases for LISP have increased the amount of state that needs to be communicated with requirements that are not satisfied by the current mechanism. This document introduces the use of a reliable transport for ETR to Map-Server communication in order to eliminate the periodic messaging overhead, while providing reliability, flow-control and endpoint liveness detection.

LISP Distinguished Name Encoding

	draft-ietf-lisp-name-encoding-06.txt
	Date:	15/04/2024
	Authors:	Dino Farinacci
	Working Group:	Locator/ID Separation Protocol (lisp)

This draft defines how to use the AFI=17 Distinguished Names in LISP.

LISP Geo-Coordinate Use-Cases

	draft-ietf-lisp-geo-04.txt
	Date:	22/04/2024
	Authors:	Dino Farinacci
	Working Group:	Locator/ID Separation Protocol (lisp)

This draft describes how Geo-Coordinates can be used in the LISP Architecture and Protocols. Some use-cases can be geo-fencing and physically locating objects.

LISP Site External Connectivity

	draft-ietf-lisp-site-external-connectivity-00.txt
	Date:	27/03/2024
	Authors:	Prakash Jain, Victor Moreno, Sanjay Hooda
	Working Group:	Locator/ID Separation Protocol (lisp)

This draft defines how to register/retrieve pETR mapping information in LISP when the destination is not registered/known to the local site and its mapping system (e.g. the destination is an internet or external site destination).

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Locator/ID Separation Protocol (lisp)

WG	Name	Locator/ID Separation Protocol
	Acronym	lisp
	Area	Routing Area (rtg)
	State	Active
	Charter	charter-ietf-lisp-05 Approved
	Status update	Show Changed 2019-03-25
	Document dependencies	Document dependencies Loading... Pan and zoom the dependency graph after the layout settles. Show legend Loading...
	Additional resources	Issue tracker, Wiki, Zulip Stream
Personnel	Chairs	Luigi Iannone, Padma Pillay-Esnault
	Area Director	Jim Guichard
	Secretary	Alberto Rodriguez-Natal
Mailing list	Address	lisp@ietf.org
	To subscribe	https://www.ietf.org/mailman/listinfo/lisp
	Archive	https://mailarchive.ietf.org/arch/browse/lisp/
Chat	Room address	https://zulip.ietf.org/#narrow/stream/lisp

Charter for Working Group

LISP supports an overlay routing architecture that decouples the routing locators and endpoint identifiers, thus allowing for efficient aggregation of the routing locator space and providing persistent identifiers in the endpoint space. LISP requires no changes to endpoints or routers that do not directly participate in the LISP deployment. LISP aims for an incrementally deployable protocol, so new features and services can be added easily and quickly to the network using overlays. The LISP WG is chartered to continue work on the LISP protocol, including minor extensions for which the working group has consensus on deeming them necessary for the use cases identified by the working group as main LISP applications. Such use cases have to be documented in an applicability document providing rationale for the work done.

The working group will work on the following items:

Moving to Standard Track: The core specifications of LISP have been published as “Standard Track” ([RFC9300], [RFC9301]). The WG will continue the work of moving select specifications to “Standard Track” (e.g., LISP Canonical Address Format [RFC8060], LISP Multicast [RFC6831][RFC8378], etc).
Map Server Reliable Transport: LISP control plane messages are transported over UDP, however, in some cases, the use of a reliable transport protocol (such as TCP) is a better fit, since it actually helps reduce periodic signaling.
YANG Models: The management of LISP protocol and deployments including data models, OAM, as well as allowing for programmable management interfaces.
LISP for Traffic Engineering: Specifics on how to do traffic engineering on LISP deployments could be useful. For instance, encode in a mapping not only the routing locators associated to EIDs, but also an ordered set of re-encapsulating tunnel routers (RTRs) used to specify a path.
NAT-Traversal: LISP protocol extensions to support a NAT-traversal solution in deployments where LISP tunnel endpoints are separated from by a NAT (e.g., LISP mobile node). The LISP WG will collaborate with the TSVWG working on NAT-Traversal.
Privacy and Security: The WG will work on EID anonymity, VPN segmentation leveraging the Instance ID, and traffic anonymization. The reuse of existing mechanisms will be prioritized.
LISP External Connectivity: [RFC6832] defines the Proxy ETR element, to be used to connect LISP sites with non-LISP sites. However, LISP deployments could benefit from more advanced interworking, for instance by defining mechanisms to discover such external connectivity.
Mobility: Some LISP deployment scenarios include endpoints that move across different LISP xTRs and/or LISP xTRs that are themselves mobile. Support needs to be provided to achieve seamless connectivity.
LISP Applicability: LISP has proved to be a very flexible protocol that can be used in various use cases not considered during its design phase. [RFC7215], while remaining a good source of information, covers one single use case, which is no longer the main LISP application scenario. The LISP WG will document LISP deployments for the most recent and relevant use cases, so as to update and complement [RFC7215] as needed.

Milestones

Date	Milestone	Associated documents
Nov 2026	Wrap-Up or recharter
Mar 2026	Submit LISP Applicability document(s) to the IESG for consideration (LISP Applicability) [INFORMATIONAL]
Nov 2025	Submit LISP Multicast document(s) to the IESG for consideration [STANDARDS TRACK]
Jul 2025	Submit LISP Mobility document(s) to the IESG for consideration (Mobility) [EXPERIMENTAL]
Mar 2025	Submit LISP External Connectivity document(s) to the IESG for consideration (LISP External Connectivity) [EXPERIMENTAL]
Mar 2025	Submit LISP Privacy and Security document(s) to the IESG for consideration (Privacy and Security) [EXPERIMENTAL]
Nov 2024	Submit LISP LCAF bis document to the IESG for consideration [STANDARDS TRACK]
Nov 2024	Submit LISP DDT bis document to the IESG for consideration [STANDARDS TRACK]
Nov 2024	Submit LISP NAT Traversal document to the IESG for consideration (NAT Traversal) [STANDARDS TRACK]
Mar 2024	Submit LISP Geo-Coordinates document to the IESG for consideration (Mobility) [EXPERIMENTAL]
Mar 2024	Submit LISP Traffic Engineering document to the IESG for consideration (Extension) [EXPERIMENTAL]
Mar 2024	Submit LISP YANG model document to the IESG for consideration (YANG Models) [EXPERIMENTAL]
Mar 2024	Submit LISP Reliable Transport document to the IESG for consideration (Map Server Reliable Transport) [STANDARDS TRACK]
Nov 2023	Submit LISP Name Encoding document to the IESG for consideration (Extension) [EXPERIMENTAL]