L2SM Working Group B. Wen
Internet-Draft Comcast
Intended status: Standards Track G. Fioccola, Ed.
Expires: March 22, 2018 Telecom Italia
C. Xie
China Telecom
L. Jalil
Verizon
September 18, 2017
A YANG Data Model for L2VPN Service Delivery
draft-ietf-l2sm-l2vpn-service-model-03
Abstract
This document defines a YANG data model that can be used to configure
a Layer 2 Provider Provisioned VPN service.
This model is intended to be instantiated at management system to
deliver the overall service. This model is not a configuration model
to be used directly on network elements, but provides an abstracted
view of the Layer 2 VPN service configuration components. It is up
to a management system to take this as an input and generate specific
configurations models to configure the different network elements to
deliver the service. How configuration of network elements is done
is out of scope of the document.
The data model in this document includes support for point-to-point
Virtual Private Wire Services (VPWS) and multipoint Virtual Private
LAN services (VPLS) that use Pseudowires signaled using the Label
Distribution Protocol (LDP) and the Border Gateway Protocol (BGP) as
described in RFC4761 and RFC6624.
Requirements Language
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].
Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF). Note that other groups may also distribute
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working documents as Internet-Drafts. The list of current Internet-
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This Internet-Draft will expire on March 22, 2018.
Copyright Notice
Copyright (c) 2017 IETF Trust and the persons identified as the
document authors. All rights reserved.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 4
1.1. Terminology . . . . . . . . . . . . . . . . . . . . . . . 5
1.2. Tree diagram . . . . . . . . . . . . . . . . . . . . . . 5
2. Definitions . . . . . . . . . . . . . . . . . . . . . . . . . 6
3. The Layer 2 VPN Service Model . . . . . . . . . . . . . . . . 7
3.1. Applicability of the Layer 2 VPN Service Model . . . . . 8
3.2. Layer 2 VPN Service Types . . . . . . . . . . . . . . . . 8
3.3. Layer 2 VPN Physical Network Topology . . . . . . . . . . 10
3.4. Layer 2 VPN Ethernet Virtual Circuit Construct . . . . . 11
4. Service Data Model Usage . . . . . . . . . . . . . . . . . . 14
5. Design of the Data Model . . . . . . . . . . . . . . . . . . 16
5.1. Features and Augmentation . . . . . . . . . . . . . . . . 27
5.2. VPN Service Overview . . . . . . . . . . . . . . . . . . 28
5.2.1. Customer Information . . . . . . . . . . . . . . . . 29
5.2.2. VPN Service Type . . . . . . . . . . . . . . . . . . 29
5.2.2.1. EVC . . . . . . . . . . . . . . . . . . . . . . . 30
5.2.2.2. OVC . . . . . . . . . . . . . . . . . . . . . . . 30
5.2.3. VPN Service Topology . . . . . . . . . . . . . . . . 31
5.2.3.1. Route Target Allocation . . . . . . . . . . . . . 31
5.2.3.2. Any-to-Any . . . . . . . . . . . . . . . . . . . 31
5.2.3.3. Hub and Spoke . . . . . . . . . . . . . . . . . . 32
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5.2.4. Cloud Access . . . . . . . . . . . . . . . . . . . . 32
5.2.5. Metro Ethernet Network Partition . . . . . . . . . . 34
5.2.6. Extranet VPNs . . . . . . . . . . . . . . . . . . . . 35
5.2.7. CVLAN ID To SVC MAP . . . . . . . . . . . . . . . . . 37
5.2.8. Service Level MAC Limit . . . . . . . . . . . . . . . 37
5.2.9. Service Protection . . . . . . . . . . . . . . . . . 38
5.2.10. Multicast Service . . . . . . . . . . . . . . . . . . 38
5.3. Site Overview . . . . . . . . . . . . . . . . . . . . . . 39
5.3.1. Devices and Locations . . . . . . . . . . . . . . . . 41
5.3.2. Signaling Option . . . . . . . . . . . . . . . . . . 42
5.3.2.1. BGP L2VPN . . . . . . . . . . . . . . . . . . . . 42
5.3.2.2. BGP EVPN . . . . . . . . . . . . . . . . . . . . 43
5.3.2.3. LDP Pseudowires . . . . . . . . . . . . . . . . . 43
5.3.2.4. PWE Encapsulation Type . . . . . . . . . . . . . 44
5.3.2.5. PWE MTU . . . . . . . . . . . . . . . . . . . . . 44
5.3.2.6. Control Word . . . . . . . . . . . . . . . . . . 44
5.3.2.7. L2TP Pseudowires . . . . . . . . . . . . . . . . 45
5.3.3. Load Balance Option . . . . . . . . . . . . . . . . . 45
5.3.4. Site Network Accesses . . . . . . . . . . . . . . . . 46
5.3.4.1. Bearer . . . . . . . . . . . . . . . . . . . . . 47
5.3.4.2. Connection . . . . . . . . . . . . . . . . . . . 47
5.4. Site Role . . . . . . . . . . . . . . . . . . . . . . . . 50
5.5. Site Belonging to Multiple VPNs . . . . . . . . . . . . . 50
5.5.1. Site VPN Flavor . . . . . . . . . . . . . . . . . . . 50
5.5.1.1. Single VPN Attachment: site-vpn-flavor-single . . 51
5.5.1.2. MultiVPN Attachment: site-vpn-flavor-multi . . . 51
5.5.1.3. ENNI: site-vpn-flavor-enni . . . . . . . . . . . 52
5.5.1.4. E2E: site-vpn-flavor-e2e . . . . . . . . . . . . 53
5.5.2. Attaching a Site to a VPN . . . . . . . . . . . . . . 53
5.5.2.1. Referencing a VPN . . . . . . . . . . . . . . . . 53
5.5.2.2. VPN Policy . . . . . . . . . . . . . . . . . . . 54
5.6. Deciding Where to Connect the Site . . . . . . . . . . . 57
5.6.1. Constraint: Device . . . . . . . . . . . . . . . . . 58
5.6.2. Constraint/Parameter: Site Location . . . . . . . . . 58
5.6.3. Constraint/Parameter: Access Type . . . . . . . . . . 60
5.6.4. Constraint: Access Diversity . . . . . . . . . . . . 60
5.7. Route Distinguisher and Network Instance Allocation . . . 62
5.8. Site Network Access Availability . . . . . . . . . . . . 63
5.9. SVC MTU . . . . . . . . . . . . . . . . . . . . . . . . . 64
5.10. Service . . . . . . . . . . . . . . . . . . . . . . . . . 64
5.10.1. Bandwidth . . . . . . . . . . . . . . . . . . . . . 64
5.10.2. QoS . . . . . . . . . . . . . . . . . . . . . . . . 65
5.10.2.1. QoS Classification . . . . . . . . . . . . . . . 65
5.10.2.2. QoS Profile . . . . . . . . . . . . . . . . . . 66
5.10.3. Multicast . . . . . . . . . . . . . . . . . . . . . 67
5.11. Site Management . . . . . . . . . . . . . . . . . . . . . 68
5.12. Security . . . . . . . . . . . . . . . . . . . . . . . . 69
5.12.1. MAC Loop Protection . . . . . . . . . . . . . . . . 69
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5.12.2. MAC Address Limit . . . . . . . . . . . . . . . . . 69
5.13. Ethernet Service OAM . . . . . . . . . . . . . . . . . . 69
5.14. External ID References . . . . . . . . . . . . . . . . . 70
5.15. Defining NNIs and Inter-AS support . . . . . . . . . . . 71
5.15.1. Defining an NNI with the Option A Flavor . . . . . . 72
5.15.2. Defining an NNI with the Option B Flavor . . . . . . 75
5.15.3. Defining an NNI with the Option C Flavor . . . . . . 78
5.16. Applicability of L2SM model in Inter-Provider and Inter-
Domain Orchestration . . . . . . . . . . . . . . . . . . 79
6. Interaction with Other YANG Modules . . . . . . . . . . . . . 82
7. Service Model Usage Example . . . . . . . . . . . . . . . . . 83
8. YANG Module . . . . . . . . . . . . . . . . . . . . . . . . . 88
9. Security Considerations . . . . . . . . . . . . . . . . . . . 168
10. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 169
11. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 169
12. References . . . . . . . . . . . . . . . . . . . . . . . . . 169
12.1. Normative References . . . . . . . . . . . . . . . . . . 169
12.2. Informative References . . . . . . . . . . . . . . . . . 171
Appendix A. Changes Log . . . . . . . . . . . . . . . . . . . . 172
Appendix B. Open Issues . . . . . . . . . . . . . . . . . . . . 174
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 174
1. Introduction
This document defines a YANG data model for Layer 2 VPN (L2VPN)
service configuration. This model is intended to be instantiated at
management system to allow a user (a customer or an application) to
request the service from a service provider. This model is not a
configuration model to be used directly on network elements, but
provides an abstracted view of the L2VPN service configuration
components. It is up to a management system to take this as an input
and generate specific configurations models to configure the
different network elements to deliver the service. How configuration
of network elements is done is out of scope of the document.
The data model in this document includes support for point-to-point
Virtual Private Wire Services (VPWS) and multipoint Virtual Private
LAN services (VPLS) that use Pseudowires signaled using the Label
Distribution Protocol (LDP) and the Border Gateway Protocol (BGP) as
described in [RFC4761] and [RFC6624].
Further discussion of the way that services are modeled in YANG and
of the relationship between "customer service models" like the one
described in this document and configuration models can be found in
[I-D.ietf-opsawg-service-model-explained]. Section 4 and Section 6
also provide more information of how this service model could be used
and how it fits into the overall modeling architecture.
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1.1. Terminology
The following terms are defined in [RFC6241] and are not redefined
here:
o client
o configuration data
o server
o state data
The following terms are defined in [RFC6020] and are not redefined
here:
o augment
o data model
o data node
The terminology for describing YANG data models is found in
[RFC6020].
1.2. Tree diagram
A simplified graphical representation of the data model is presented
in Section 5.
The meaning of the symbols in these diagrams is as follows:
o Brackets "[" and "]" enclose list keys.
o Curly braces "{" and "}" contain names of optional features that
make the corresponding node conditional.
o Abbreviations before data node names: "rw" means configuration
(read-write), and "ro" state data (read-only).
o Symbols after data node names: "?" means an optional node and "*"
denotes a "list" or "leaf-list".
o Parentheses enclose choice and case nodes, and case nodes are also
marked with a colon (":").
o Ellipsis ("...") stands for contents of subtrees that are not
shown.
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2. Definitions
This document uses the following terms:
Service Provider (SP): The organization (usually a commercial
undertaking) responsible for operating the network that offers VPN
services to clients and customers.
Customer Edge (CE) Device: Equipment that is dedicated to a
particular customer and is directly connected to one or more PE
devices via attachment circuits. A CE is usually located at the
customer premises, and is usually dedicated to a single VPN,
although it may support multiple VPNs if each one has separate
attachment circuits. The CE devices can be routers, bridges,
switches, or hosts.
Provider Edge (PE) Device: Equipment managed by the SP that can
support multiple VPNs for different customers, and is directly
connected to one or more CE devices via attachment circuits. A PE
is usually located at an SP point of presence (PoP) and is managed
by the SP.
Virtual Private LAN Service (VPLS): A VPLS is a provider service
that emulates the full functionality of a traditional Local Area
Network (LAN). A VPLS makes it possible to interconnect several
LAN segments over a packet switched network (PSN) and makes the
remote LAN segments behave as one single LAN.
Virtual Private Wire Service (VPWS): A VPWS is a point-to-point
circuit (i.e., link) connecting two CE devices. The link is
established as a logical through a packet switched network. The
CE in the customer network is connected to a PE in the provider
network via an Attachment Circuit (AC): the AC is either a
physical or a logical circuit. A VPWS differs from a VPLS in that
the VPLS is point-to-multipoint, while the VPWS is point-to-point.
In some implementations, a set of VPWSs is used to create a multi-
site L2VPN network.
Pseudowire(PW): A pseudowire is an emulation of a native service
over a packet switched network (PSN). The native service may be
ATM, frame relay, Ethernet, low-rate TDM, or SONET/SDH, while the
PSN may be MPLS, IP (either IPv4 or IPv6), or L2TPv3.
MAC-VRF: A Virtual Routing and Forwarding table for Media Access
Control (MAC) addresses on a PE. It is sometime also referred to
VSI.
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UNI: The physical demarcation point between the responsibility of
Customer and the responsibility of Provider.
ENNI: a reference point representing the boundary between two
Operator Networks that are operated as separate administrative
domains.
Ethernet Virtual Connection(EVC): An EVC is an association of two or
more UNIs that limits the exchange of Service Frames to UNIs in
the Ethernet Virtual Connection (EVC).
Operator Virtual Connection(OVC): An OVC is the association of UNIs
and ENNIs or two ENNIs within one administrative domain.
This document uses the following abbreviations:
BSS: Business Support System
B-U-M: Broadcast-UnknownUnicast-Multicast
CoS: Class of Service
LAG: Link Aggregation Group
LLDP: Link Level Discovery Protocol
OAM: Operations, Administration, and Maintenance
OSS: Operations Support System
PDU: Protocol Data Unit
QoS: Quality of Service
VSI: Virtual Switching Instance
UNI: User to Network Interface
ENNI: External Network to Network Interface
3. The Layer 2 VPN Service Model
A Layer 2 VPN service is a collection of sites that are authorized to
exchange traffic between each other over a shared infrastructure of a
common technology. This Layer 2 VPN service model (L2SM) provides a
common understanding of how the corresponding Layer 2 VPN service is
to be deployed over the shared infrastructure.
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This document presents the L2SM using the YANG data modeling language
[RFC6020] as a formal language that is both human-readable and
parsable by software for use with protocols such as NETCONF [RFC6241]
and RESTCONF [RFC8040].
This service model is limited to VPWS and VPLS based VPNs as
described in [RFC4761] and [RFC6624], EVPN as described in [RFC7432]
and EVC service.
3.1. Applicability of the Layer 2 VPN Service Model
The L2SM defined in this document applies to VPW Service, VPLS
service,EVPN service and Ethernet virtual circuit Services(e.g.,
E-Line and E-LAN service).
Over the past decade, The MEF Forum (MEF) has published a series of
technical specifications of Ethernet virtual circuit service
attributes and implementation agreements between providers. Many
Ethernet VPN service providers worldwide have adopted these MEF
standards and developed backoffice tools accordingly. IETF also
works on extending L2VPN Framework [RFC4664] to support those
services in the MPLS network.
Rather than introducing a new set of terminologies, the L2SM will
align with existing MEF attributes when it's applicable to Ethernet
Virtual Circuit Service. Therefore, service providers can easily
integrate any new application that leverages the L2SM data using(for
example, a Service Orchestrator), with existing BSS/OSS toolsets.
Service providers also have the option to generate L2SM data for
current L2VPN customer circuits already deployed in the network.
3.2. Layer 2 VPN Service Types
From technology perspective, a set of basic L2VPN service types
include:
o Point-to-point Virtual Private Wire Services (VPWS);
o PWE3 (Pseudo-Wire Emulation Edge to Edge) Services that use LDP-
signaled Pseudowires;
o Multipoint Virtual Private LAN services (VPLS) that use LDP-
signaled Pseudowires;
o Multipoint Virtual Private LAN services (VPLS) that use a Border
Gateway Protocol (BGP) control plane as described in RFC4761 and
RFC6624;
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o Ethernet VPNs specified in RFC 7432;
o EVC Service
An EVC circuit can also be port-based, in which case any service
frames received from a subscriber within the contractual bandwidth
will be delivered to the corresponding remote site, regardless of the
customer VLAN value (C-tag) of the incoming frame. When multiple
service frames are received from a subscriber and each service frame
has different C-tag, all C-tags have to be mapped to one Ethernet
Service(i.e., All to One bundling). The service frames can also be
native Ethernet frames without a C-tag. In this scenario, only one
Ethernet Virtual Circuit (EVC) is allowed on a single provider to
subscriber link.
Contrary to the above use case, incoming customer service frames may
be split into multiple EVCs based on pre-arrangement between the
service provider and customer. Typically, C-tag of the incoming
frames will serve as the service delimiter for EVC multiplexing over
the same provider to subscriber interconnection.
Combining the port based attribute and service-multiplexing attribute
with the connection type (point-to-point or multipoint-to-
multipoint), an Ethernet Virtual Circuit may fall into one of the
following service types:
o E-Line services: Point-to-Point Layer 2 connections.
EPL: In its simplest form, a port-based Ethernet Private Line
(EPL) service provides a high degree of transparency delivering
all customer service frames between local and remote UNIs using
multiple C-tags to one EVC bundling or All-to-One Bundling [MEF
6.1]. All unicast/broadcast/multicast packets are delivered
unconditionally over the EVC. No service multiplexing is
allowed on an EPL UNI. Note that The UNI interface connecting
provider edge and customer edge devices is called an Attachment
Circuit (AC) and can be a physical or virtual link.
EVPL: On the other hand, a VLAN based Ethernet Virtual Private
Line (EVPL) service supports multiplexing more than one point-
to-point, or even other virtual private services, on the same
UNI. Ingress service frames are conditionally transmitted
through one of the EVCs based upon pre-agreed C-tag to EVC
mapping. EVPL supports multiple C-tags to one EVC bundling.
o E-LAN services: Multipoint-to-Multipoint Layer 2 connections.
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EP-LAN: An Ethernet Private LAN Service (EP-LAN) transparently
connects multiple subscriber sites together with All-to-One
Bundling. No service multiplexing is allowed on an EP-LAN UNI.
EVP-LAN: Some subscribers may desire more sophisticated control
of data access between multiple sites. An Ethernet Virtual
Private LAN Service (EVP-LAN) allows multiple EVCs to be
connected to from one or more of the UNIs. Services frame
disposition is based on C-tag to EVC mapping. EVP-LAN supports
multiple C-tags bundled to one EVC.
3.3. Layer 2 VPN Physical Network Topology
Figure 1 depicts a typical service provider's physical network
topology. Most service providers have deployed an IP, MPLS, or
Segment Routing (SR) multi-service core infrastructure. A L2VPN
provides end-to-end L2 connectivity over this multi-service core
infrastructure between two or more locations of Customers or a
collection of sites. Attachment Circuit are placed between CE
devices and PE Devices that backhaul service frames from the customer
over the access network to the Provider Network or remote Site. The
demarcation point (i.e.,UNI) between customer and service provider
can be either placed between C and Customer Edge Device or between
Customer Edge Device and Provider Edge Device. The actual bearer,
connection, network access type between CE and PE will be discussed
in the L2SM model.
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Site A Site B
--- ---- ---
| | | | | |
| C +---+ CE | | C |
| | | | --------- | |
--- ----\ ( ) /---
\ ---- ( ) ---- ---- /
\| | ( ) | | | |/
| PE +---+ IP/MPLS/SR +---+ PE +---+ CE |
/| | ( Network ) | | | |\
/ ---- ( ) ---- ---- \
--- ----/ ( ) \---
| | | | ----+---- | |
| C +---+ CE | | | C |
| | | | --+-- | |
--- ---- | PE | ---
--+--
| Site C
--+--
| CE |
--+--
|
--+--
| C |
-----
Figure 1: Reference Network for the Use of the L2VPN Service Model
From the customer perspective, however, all the customer edge devices
are connected over a simulated LAN environment as shown in Figure 2.
Broadcast and multicast packets are sent to all participants in the
same bridge domain.
CE---+----+---+---CE
| | |
| | |
| | |
CE---+ CE +---CE
Figure 2: Customer View of the L2VPN
3.4. Layer 2 VPN Ethernet Virtual Circuit Construct
The base model of L2VPN EVC is shown in Figure 3.
Customer edge network device (CE) connects to the service provider's
PE equipment. The demarcation point between customer and service
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provider devices is referred as the User Network Interface (UNI).
The UNI interface connecting PE and CE devices can be a physical or
virtual port. For clarification, this is called the UNI-C on the
customer side and UNI-N on the provider side.
The service provider is obligated to deliver the original service
frame from local UNI-C across the network to the remote UNI-C. All
Ethernet and IP header information, include (but not limit to) source
and destination MAC addresses, EtherType, VLAN (C-tag), Class-of-
Service marking (802.1p or DSCP), etc.
Incoming service frames are first examined at UNI-C based on C-tag,
Class-of-Services identifier, EtherType value. Conforming packets
are then metered against the contractual service bandwidth.
Conforming packets will be delivered to the remote UNI via the
Ethernet Virtual Circuit (EVC), which spans between UNI-C and UNI-C.
When both CEs are located in the same provider's network, a single
operator maintains the EVC. In this case, the EVC consists of only
one Operator Virtual Circuit (OVC).
Typically, the CE device at customer premises is a layer 2 Ethernet
switch. A service provider may choose to impose an outer VLAN tag
(S-tag) into the received subscriber traffic following 802.1ad Q-in-Q
standard, especially when Layer 2 aggregation devices exist between
CE and PE.
The uplink from PE to PE is referred as an Internal Network-to-
Network Interface (I-NNI). When 802.1ad Q-in-Q is implemented,
Ethernet frames from CE to PE are double tagged with both provider
and subscriber VLANs (S-tag, C-tag).
Most service providers have deployed MPLS or SR multi-service core
infrastructure. Ingress service frames will be mapped to either
Ethernet Pseudowire (PWE) or VxLAN tunnel PE-to-PE. The details of
these tunneling mechanism are at the provider's discretion and not
part of the L2SM.
The service provider may also choose a Seamless MPLS approach to
expand the PWE or VxLAN tunnel between UNI-N to UNI-N.
The service provider may leverage multi-protocol BGP to auto-discover
and signal the PWE or VxLAN tunnel end points.
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EVC
:<---------------------------------->:
: :
: :
: OVC (Optional) :
:<---------------------------------->:
: :
: :
: PW / VXLAN :
: :<-------------------------->: :
: : : :
: : : :
: : -------- : :
: : ( ) : :
--- ---- ---- ( ) ---- ---- ---
| | | | | | ( ) | | | | | |
| C +---+ CE +---+ PE +---+ IP/MPLS/SR +---+ PE +---+ CE +---+ C |
| | | | | | ( Network ) | | | | | |
--- ---- ---- ( ) ---- ---- ---
^ ^ : ( ) : :
: : : -------- : :
UNI-C UNI-N : :
: : : :
:<----->:<------>:<-------------------------->:<------>:<---->:
802.3 802.1Q IP/MPLS/SR Domain 802.1Q 802.3
q-in-q q-in-q
Figure 3: Architectural Model for EVC over a Single Network
Nevertheless, the remote site may be outside of the provider's
service territory. In this case, the provider may partner with the
operator of another metro network to provide service to the off-net
location as shown in Figure 4.
The first provider owns the customer relationship, thus the end-to-
end EVC. The EVC is comprised of two or more OVCs. The EVC is
partially composed of an OVC from local UNI-C to the inter- provider
interface. The provider will purchase an Ethernet Access (E-Access)
OVC from the second operator to deliver packet to the remote UNI-C.
The inter-connect between the two operators edge gateway (EG) devices
is defined as the External Network-to-Network Interface (E-NNI).
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EVC
:<----------------------------------------------->:
: :
: :
: OVC (Optional) :
:<--------------------->: :
: : :
: : :
: PW / VXLAN : :
: :<------------------>: :
: : : :
: : : :
: : ----- : ----- :
: : ( ) : ( ) :
- -- -- ( IP/ ) ---- ---- ( IP/ ) -- -- -
|C+-+CE+-+PE+--+ MPLS/ +--+Edge+--+Edge+--+ MPLS/ +--+PE+-+CE+-+C|
- -- -- ( SR ) |G/W | |G/W | ( SR ) -- -- -
^ ^ : ( ) ---- ---- ( ) ^
: : : ----- ^ ^ ----- :
UNI-C UNI-N
: ENNI :
: : :
: : : Remote
:<--->:<->:<------------------>: <->: Customer
802.3 802.1Q IP/MPLS/SR 802.1ah Site
q-in-q Domain q-in-q
Figure 4: Architectural Model for EVC over Multiple Networks
4. Service Data Model Usage
The L2VPN service model provides an abstracted interface to request,
configure, and manage the components of a L2VPN service. The model
is used by a customer who purchases connectivity and other services
from an SP to communicate with that SP.
A typical usage for this model is to be an input to an orchestration
layer that is responsible for translating it into configuration
commands for the network elements that deliver/enable the service.
The network elements may be routers, but also servers (like AAA) that
are necessary within the network.
The configuration of network elements may be done using the Command
Line Interface (CLI), or any other configuration (or "southbound")
interface such as NETCONF [RFC6241] in combination with device-
specific and protocol-specific YANG models.
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This way of using the service model is illustrated in Figure 5 and
described in more detail in
[I-D.ietf-opsawg-service-model-explained]. The usage of this service
model is not limited to this example: it can be used by any component
of the management system, but not directly by network elements.
The usage and structure of this model should be compared to the Layer
3 VPN service model defined in [RFC8049].
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----------------------------
| Customer Service Requester |
----------------------------
|
L2VPN |
Service |
Model |
|
-----------------------
| Service Orchestration |
-----------------------
|
| Service +-------------+
| Delivery +------>| Application |
| Model | | BSS/OSS |
| V +-------------+
-----------------------
| Network Orchestration |
-----------------------
| |
+----------------+ |
| Config manager | |
+----------------+ | Device
| | Models
| |
--------------------------------------------
Network
+++++++
+ AAA +
+++++++
++++++++ Bearer ++++++++ ++++++++ ++++++++
+ CE A + ----------- + PE A + + PE B + ---- + CE B +
++++++++ Connection ++++++++ ++++++++ ++++++++
Site A Site B
Figure 5: Reference Architecture for the Use of the L2VPN Service
Model
5. Design of the Data Model
The L2SM model is structured in a way that allows the provider to
list multiple circuits of various service types for the same
customer.
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The YANG module is divided in two main containers: vpn-services, and
sites. The vpn-svc container under vpn-services defines global
parameters for the VPN service for a specific customer.
A site contains at least one network access (i.e., site network
accesses providing access to the sites defined in Section 5.3.4) and
there may be multiple network accesses in case of multihoming. The
site to network access attachment is done through a bearer with a
Layer 2 connection on top. The bearer refers to properties of the
attachment that are below layer 2 while the connection refers to
layer 2 protocol oriented properties. The bearer may be allocated
dynamically by the service provider and the customer may provide some
constraints or parameters to drive the placement.
Authorization of traffic exchange is done through what we call a VPN
policy or VPN topology defining routing exchange rules between sites.
An end to end Multi-segment connectivity can be realized using
combination of Per Site connectivity and OVC at different segments.
The figure below describe the overall structure of the YANG module:
module: ietf-l2vpn-svc
+--rw l2vpn-svc
+--rw vpn-services
| +--rw vpn-svc* [vpn-id]
| +--rw vpn-id svc-id
| +--rw vpn-type? identityref
| +--rw customer-account-number? uint32
| +--rw customer-name? string
| +--rw evc {evc}?
| | +--rw enabled? boolean
| | +--rw evc-type? identityref
| | +--ro number-of-pe? uint32
| | +--ro number-of-site? uint32
| | +--rw uni-list {uni-list}?
| | +--rw uni-list* [uni-site-id]
| | +--rw uni-site-id string
| | +--rw off-net? boolean
| | +--rw service-multiplexing? boolean
| | +--rw ce-vlan-preservation? boolean
| | +--rw ce-vlan-cos-perservation? boolean
| +--rw ovc {ovc}?
| | +--rw ovc-list* [ovc-id]
| | +--rw ovc-id svc-id
| | +--rw off-net? boolean
| | +--rw svlan-cos-preservation? boolean
| | +--rw svlan-id-preservation? boolean
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| | +--rw svlan-id-ethernet-tag? string
| | +--rw ovc-endpoint? string
| +--rw svc-topo? identityref
| +--rw cloud-accesses {cloud-access}?
| | +--rw cloud-access* [cloud-identifier]
| | +--rw cloud-identifier string
| | +--rw (list-flavor)?
| | | +--:(permit-any)
| | | | +--rw permit-any? empty
| | | +--:(deny-any-except)
| | | | +--rw permit-site* -> /l2vpn-svc/sites/site/site-id
| | | +--:(permit-any-except)
| | | +--rw deny-site* -> /l2vpn-svc/sites/site/site-id
| | +--rw authorized-sites
| | | +--rw authorized-site* [site-id]
| | | +--rw site-id -> /l2vpn-svc/sites/site/site-id
| | +--rw denied-sites
| | +--rw denied-site* [site-id]
| | +--rw site-id -> /l2vpn-svc/sites/site/site-id
| +--rw metro-networks
| | +--rw metro-network* [id]
| | +--rw id string
| | +--rw inter-mkt-service? boolean
| | +--rw intra-mkt* [mkt-name]
| | +--rw mkt-name string
| | +--rw ovc-id? -> /l2vpn-svc/vpn-services/vpn-svc/ovc/ovc-list/ovc-id
| | +--rw site-id? -> /l2vpn-svc/sites/site/site-id
| +--rw global-l2cp-control {L2CP-control}?
| | +--rw stp-rstp-mstp? control-mode
| | +--rw pause? control-mode
| | +--rw lldp? boolean
| +--rw service-level-mac-limit
| | +--rw service-level-mac-limit? uint16
| | +--rw action? identityref
| +--rw service-protection
| | +--rw protection-mode? identityref
| +--rw cvlan-id-to-svc-map* [svc-id type]
| | +--rw svc-id -> /l2vpn-svc/vpn-services/vpn-svc/vpn-id
| | +--rw type identityref
| | +--rw cvlan-id* [vid]
| | +--rw vid identityref
| +--rw multicast {multicast}?
| | +--rw enabled? boolean
| | +--rw customer-tree-flavors
| | | +--rw tree-flavor* identityref
| | +--rw traffic-type? identityref
| | +--rw group-port-mapping? identityref
| +--rw extranet-vpns {extranet-vpn}?
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| +--rw extranet-vpn* [vpn-id]
| +--rw vpn-id svc-id
| +--rw local-sites-role? identityref
+--rw sites
+--rw site* [site-id site-type]
+--rw site-id string
+--rw site-type identityref
+--rw device
| +--rw devices* [device-id]
| +--rw device-id string
| +--rw location? -> /l2vpn-svc/sites/site/locations/location/location-id
| +--rw management
| +--rw address? inet:ip-address
| +--rw management-transport? identityref
+--rw locations
| +--rw location* [location-id]
| +--rw location-id string
| +--rw address? string
| +--rw zip-code? string
| +--rw state? string
| +--rw city? string
| +--rw country-code? string
+--rw management
| +--rw type? identityref
+--rw site-diversity {site-diversity}?
| +--rw groups
| +--rw group* [group-id]
| +--rw group-id string
+--rw vpn-policies
| +--rw vpn-policy* [vpn-policy-id]
| +--rw vpn-policy-id string
| +--rw entries* [id]
| +--rw id string
| +--rw filters
| | +--rw filter* [type]
| | +--rw type identityref
| | +--rw lan-tag* uint32 {lan-tag}?
| | +--rw ipv4-lan-prefix* inet:ipv4-prefix {ipv4}?
| | +--rw ipv6-lan-prefix* inet:ipv6-prefix {ipv6}?
| +--rw vpn* [vpn-id]
| +--rw vpn-id -> /l2vpn-svc/vpn-services/vpn-svc/vpn-id
| +--rw site-role? identityref
+--rw signaling-options {signaling-options}?
| +--rw signaling-options* [type]
| +--rw type identityref
| +--rw bgp-l2vpn
| | +--rw vpn-id? -> /l2vpn-svc/vpn-services/vpn-svc/vpn-id
| | +--rw type? identityref
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| | +--rw pwe-encapsulation-type? identityref
| | +--rw pwe-mtu
| | | +--rw allow-mtu-mismatch? boolean
| | +--rw address-family? identityref
| +--rw mp-bgp-evpn
| | +--rw vpn-id? -> /l2vpn-svc/vpn-services/vpn-svc/vpn-id
| | +--rw type? identityref
| | +--rw address-family? identityref
| | +--rw mac-learning-mode? identityref
| | +--rw arp-suppress? boolean
| +--rw t-ldp-pwe
| | +--rw type? identityref
| | +--rw pwe-encapsulation-type? identityref
| | +--rw pwe-mtu
| | | +--rw allow-mtu-mismatch? boolean
| | +--rw pe-eg-list* [service-ip-addr vc-id]
| | | +--rw service-ip-addr inet:ip-address
| | | +--rw vc-id string
| | | +--rw peer-id? string
| | | +--rw remote-peer-id? string
| | | +--rw pw-priority? uint32
| | +--rw control-word? boolean
| | +--rw qinq
| | +--rw s-tag? uint32
| | +--rw c-tag? uint32
| +--rw l2tp-pw
| +--rw encapsulation-type? identityref
| +--rw control-word? boolean
+--rw load-balance-options
| +--rw enable? boolean
| +--rw load-balance-method? identityref
+--rw service
| +--rw qos {qos}?
| +--rw qos-classification-policy
| | +--rw rule* [id]
| | +--rw id uint16
| | +--rw (match-type)?
| | | +--:(match-flow)
| | | | +--rw match-flow
| | | | +--rw dscp? inet:dscp
| | | | +--rw dot1p? uint8
| | | | +--rw pcp? uint8
| | | | +--rw src-mac? yang:mac-address
| | | | +--rw dst-mac? yang:mac-address
| | | | +--rw composite-id
| | | | | +--rw endpoint-id? string
| | | | | +--rw cos-label? identityref
| | | | | +--rw pcp? uint8
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| | | | | +--rw dscp? inet:dscp
| | | | +--rw color-type? identityref
| | | | +--rw target-sites* svc-id
| | | +--:(match-phy-port)
| | | +--rw match-phy-port? uint16
| | +--rw target-class-id? string
| +--rw qos-profile
| +--rw (qos-profile)?
| +--:(standard)
| | +--rw profile? string
| +--:(custom)
| +--rw classes {qos-custom}?
| +--rw class* [class-id]
| +--rw class-id string
| +--rw direction? identityref
| +--rw policing? identityref
| +--rw byte-offset? uint16
| +--rw rate-limit? uint8
| +--rw discard-percentage? uint8
| +--rw frame-delay
| | +--rw (flavor)?
| | +--:(lowest)
| | | +--rw use-low-del? empty
| | +--:(boundary)
| | +--rw delay-bound? uint16
| +--rw frame-jitter
| | +--rw (flavor)?
| | +--:(lowest)
| | | +--rw use-low-jit? empty
| | +--:(boundary)
| | +--rw delay-bound? uint32
| +--rw frame-loss
| | +--rw fr-loss-rate? decimal64
| +--rw bandwidth
| +--rw guaranteed-bw-percent? uint8
| +--rw end-to-end? empty
+--rw broadcast-unknown-unicast-multicast
| +--rw multicast-site-type? enumeration
| +--rw multicast-gp-address-mapping* [id]
| | +--rw id uint16
| | +--rw vlan-id? uint32
| | +--rw mac-gp-address? yang:mac-address
| | +--rw port-lag-number? uint32
| +--rw bum-overall-rate? uint32
| +--rw bum-rate-per-type* [type]
| +--rw type identityref
| +--rw rate? uint32
+--rw security
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| +--rw mac-loop-prevention
| | +--rw frequency? uint32
| | +--rw protection-type? identityref
| | +--rw number-retries? uint32
| +--rw access-control-list
| | +--rw mac* [mac-address]
| | +--rw mac-address yang:mac-address
| +--rw mac-addr-limit
| +--rw exceeding-option? uint32
+--ro actual-site-start? yang:date-and-time
+--ro actual-site-stop? yang:date-and-time
+--rw site-network-accesses
+--rw site-network-accesse* [network-access-id]
+--rw network-access-id string
+--rw remote-carrier-name? string
+--rw access-diversity {site-diversity}?
| +--rw groups
| | +--rw fate-sharing-group-size? uint16
| | +--rw group* [group-id]
| | +--rw group-id string
| +--rw constraints
| +--rw constraint* [constraint-type]
| +--rw constraint-type identityref
| +--rw target
| +--rw (target-flavor)?
| +--:(id)
| | +--rw group* [group-id]
| | +--rw group-id string
| +--:(all-accesses)
| | +--rw all-other-accesses? empty
| +--:(all-groups)
| +--rw all-other-groups? empty
+--rw bearer
| +--rw requested-type {requested-type}?
| | +--rw requested-type? string
| | +--rw strict? boolean
| +--rw always-on? boolean {always-on}?
| +--rw bearer-reference? string {bearer-reference}?
+--rw connection
| +--rw encapsulation-type? identityref
| +--rw eth-inf-type* identityref
| +--rw dot1q-interface
| | +--rw l2-access-type? identityref
| | +--rw dot1q {dot1q}?
| | | +--rw physical-inf? string
| | | +--rw c-vlan-id? uint32
| | +--rw qinq {qinq}?
| | | +--rw s-vlan-id? uint32
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| | | +--rw c-vlan-id? uint32
| | +--rw qinany {qinany}?
| | | +--rw s-vlan-id? uint32
| | +--rw vxlan {vxlan}?
| | +--rw vni-id? uint32
| | +--rw peer-mode? identityref
| | +--rw peer-list* [peer-ip]
| | +--rw peer-ip inet:ip-address
| +--rw phy-interface
| | +--rw port-number? uint32
| | +--rw port-speed? uint32
| | +--rw mode? neg-mode
| | +--rw phy-mtu? uint32
| | +--rw flow-control? string
| | +--rw physical-if? string
| | +--rw circuit-id? string
| | +--rw lldp? boolean
| | +--rw oam-802.3ah-link {oam-3ah}?
| | | +--rw enable? boolean
| | +--rw uni-loop-prevention? boolean
| +--rw lag-interface {lag-interface}?
| | +--rw lag-interface* [lag-interface-number]
| | +--rw lag-interface-number uint32
| | +--rw lacp
| | +--rw lacp-state? boolean
| | +--rw lacp-mode? boolean
| | +--rw lacp-speed? boolean
| | +--rw mini-link? uint32
| | +--rw system-priority? uint16
| | +--rw micro-bfd {micro-bfd}?
| | | +--rw micro-bfd-on-off? enumeration
| | | +--rw bfd-interval? uint32
| | | +--rw bfd-hold-timer? uint32
| | +--rw bfd {bfd}?
| | | +--rw bfd-enabled? boolean
| | | +--rw (holdtime)?
| | | +--:(profile)
| | | | +--rw profile-name? string
| | | +--:(fixed)
| | | +--rw fixed-value? uint32
| | +--rw member-link-list
| | | +--rw member-link* [name]
| | | +--rw name string
| | | +--rw port-speed? uint32
| | | +--rw mode? neg-mode
| | | +--rw mtu? uint32
| | | +--rw oam-802.3ah-link {oam-3ah}?
| | | +--rw enable? boolean
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| | +--rw flow-control? string
| | +--rw lldp? boolean
| +--rw l2cp-control {L2CP-control}?
| +--rw stp-rstp-mstp? control-mode
| +--rw pause? control-mode
| +--rw lacp-lamp? control-mode
| +--rw link-oam? control-mode
| +--rw esmc? control-mode
| +--rw l2cp-802.1x? control-mode
| +--rw e-lmi? control-mode
| +--rw lldp? boolean
| +--rw ptp-peer-delay? control-mode
| +--rw garp-mrp? control-mode
| +--rw provider-bridge-group? control-mode
| +--rw provider-bridge-mvrp? control-mode
+--rw svc-mtu? uint32
+--rw availability
| +--rw access-priority? uint32
| +--rw (redundancy-mode)?
| +--:(single-active)
| | +--rw single-active? boolean
| +--:(all-active)
| +--rw all-active? boolean
+--rw vpn-attachment
| +--rw device-id? string
| +--rw management
| | +--rw address-family? identityref
| | +--rw address? inet:ip-address
| +--rw (attachment-flavor)
| +--:(vpn-flavor)
| | +--rw vpn-flavor* [vpn-id]
| | +--rw vpn-id -> /l2vpn-svc/vpn-services/vpn-svc/vpn-id
| | +--rw site-role? identityref
| +--:(vpn-policy-id)
| +--rw vpn-policy-id? -> /l2vpn-svc/sites/site/vpn-policies/vpn-policy/vpn-policy-id
+--rw service
| +--rw svc-input-bandwidth {input-bw}?
| | +--rw input-bandwidth* [type]
| | +--rw type identityref
| | +--rw cos-id? uint8
| | +--rw vpn-id? svc-id
| | +--rw cir? uint64
| | +--rw cbs? uint64
| | +--rw eir? uint64
| | +--rw ebs? uint64
| | +--rw pir? uint32
| | +--rw pbs? uint32
| +--rw svc-output-bandwidth {output-bw}?
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| | +--rw output-bandwidth* [type]
| | +--rw type identityref
| | +--rw cos-id? uint8
| | +--rw vpn-id? svc-id
| | +--rw cir? uint32
| | +--rw cbs? uint32
| | +--rw eir? uint32
| | +--rw ebs? uint32
| | +--rw pir? uint32
| | +--rw pbs? uint32
| +--rw qos {qos}?
| +--rw qos-classification-policy
| | +--rw rule* [id]
| | +--rw id uint16
| | +--rw (match-type)?
| | | +--:(match-flow)
| | | | +--rw match-flow
| | | | +--rw dscp? inet:dscp
| | | | +--rw dot1p? uint8
| | | | +--rw pcp? uint8
| | | | +--rw src-mac? yang:mac-address
| | | | +--rw dst-mac? yang:mac-address
| | | | +--rw composite-id
| | | | | +--rw endpoint-id? string
| | | | | +--rw cos-label? identityref
| | | | | +--rw pcp? uint8
| | | | | +--rw dscp? inet:dscp
| | | | +--rw color-type? identityref
| | | | +--rw target-sites* svc-id
| | | +--:(match-phy-port)
| | | +--rw match-phy-port? uint16
| | +--rw target-class-id? string
| +--rw qos-profile
| +--rw (qos-profile)?
| +--:(standard)
| | +--rw profile? string
| +--:(custom)
| +--rw classes {qos-custom}?
| +--rw class* [class-id]
| +--rw class-id string
| +--rw direction? identityref
| +--rw policing? identityref
| +--rw byte-offset? uint16
| +--rw rate-limit? uint8
| +--rw discard-percentage? uint8
| +--rw frame-delay
| | +--rw (flavor)?
| | +--:(lowest)
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| | | +--rw use-low-del? empty
| | +--:(boundary)
| | +--rw delay-bound? uint16
| +--rw frame-jitter
| | +--rw (flavor)?
| | +--:(lowest)
| | | +--rw use-low-jit? empty
| | +--:(boundary)
| | +--rw delay-bound? uint32
| +--rw frame-loss
| | +--rw fr-loss-rate? decimal64
| +--rw bandwidth
| +--rw guaranteed-bw-percent? uint8
| +--rw end-to-end? empty
+--rw broadcast-unknown-unicast-multicast
| +--rw multicast-site-type? enumeration
| +--rw multicast-gp-address-mapping* [id]
| | +--rw id uint16
| | +--rw vlan-id? uint32
| | +--rw mac-gp-address? yang:mac-address
| | +--rw port-lag-number? uint32
| +--rw bum-overall-rate? uint32
| +--rw bum-rate-per-type* [type]
| +--rw type identityref
| +--rw rate? uint32
+--rw ethernet-service-oam
| +--rw md-name? string
| +--rw md-level? uint8
| +--rw cfm-802.1-ag
| | +--rw n2-uni-c* [maid]
| | | +--rw maid string
| | | +--rw mep-id? uint32
| | | +--rw mep-level? uint32
| | | +--rw mep-up-down? enumeration
| | | +--rw remote-mep-id? uint32
| | | +--rw cos-for-cfm-pdus? uint32
| | | +--rw ccm-interval? uint32
| | | +--rw ccm-holdtime? uint32
| | | +--rw alarm-priority-defect? identityref
| | | +--rw ccm-p-bits-pri? ccm-priority-type
| | +--rw n2-uni-n* [maid]
| | +--rw maid string
| | +--rw mep-id? uint32
| | +--rw mep-level? uint32
| | +--rw mep-up-down? enumeration
| | +--rw remote-mep-id? uint32
| | +--rw cos-for-cfm-pdus? uint32
| | +--rw ccm-interval? uint32
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| | +--rw ccm-holdtime? uint32
| | +--rw alarm-priority-defect? identityref
| | +--rw ccm-p-bits-pri? ccm-priority-type
| +--rw y-1731* [maid]
| +--rw maid string
| +--rw mep-id? uint32
| +--rw type? identityref
| +--rw remote-mep-id? uint32
| +--rw message-period? uint32
| +--rw measurement-interval? uint32
| +--rw cos? uint32
| +--rw loss-measurement? boolean
| +--rw synthethic-loss-measurement? boolean
| +--rw delay-measurement
| | +--rw enable-dm? boolean
| | +--rw two-way? boolean
| +--rw frame-size? uint32
| +--rw session-type? enumeration
+--rw security
+--rw mac-loop-prevention
| +--rw frequency? uint32
| +--rw protection-type? identityref
| +--rw number-retries? uint32
+--rw access-control-list
| +--rw mac* [mac-address]
| +--rw mac-address yang:mac-address
+--rw mac-addr-limit
+--rw exceeding-option? uint32
Figure 6
5.1. Features and Augmentation
The model defined in this document implements many features that
allow implementations to be modular. As an example, the layer 2
protocols parameters (Section 5.3.3.2) proposed to the customer may
also be enabled through features. This model also proposes some
features for options that are more advanced, such as support for
extranet VPNs (Section 5.2.6), site diversity (Section 5.6), and QoS
(Section 5.10.2).
In addition, as for any YANG model, this service model can be
augmented to implement new behaviors or specific features. For
example, this model proposes VXLAN [RFC7348] for Ethernet packet
Encapsulation; if VXLAN Encapsulation do not fulfill all
requirements, new options can be added through augmentation.
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5.2. VPN Service Overview
A vpn-service list item contains generic informations about the VPN
service. The vpn-id of the vpn-service refers to an internal
reference for this VPN service. This identifier is purely internal
to the organization responsible for the VPN service.
A vpn-service is composed of some characteristics:
Customer information: Used to identify the customer.
VPN Type (vpn-type): Used to indicate VPN service Type. The
identifier is a string allowing to any encoding for the local
administration of the VPN service.
Ethernet Connection Service Type (evc-type): used to identify
supported Ethernet Connection Service Types in case of EVC service
being offered to the customer.
Cloud Access (cloud-access): All sites in the L2VPN MUST be
authorized to access to the cloud.The cloud-access container
provides parameters for authorization rules. A cloud identifier
is used to reference the target service. This identifier is local
to each administration.
Service Topology (svc-topo): Used to identify the type of VPN
service topology is required for configuration.
Metro Network Partition: Used by service provide to divide the
network into several administrative domains.
Load Balance (load-balance-option): Intended to capture the load-
balance agreement between the subscriber and provider.
CVLAN ID To EVC MAP: Contains the list of customer vlans to the
service mapping in a free-form format. In most cases, this will
be the VLAN access-list for the inner 802.1q tags.
Service Level MAC Limit: Contains the subscriber MAC address limit
and exceeding action information.
Service Protection (svc-protection): Capture the desired service
protection agreement between subscriber and provider.
Multicast Service (multicast): rovide multicast support for L2VPN.
Extranet VPN (extranet-vpns): Allow a particular VPN needs access to
resources located in another VPN.
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5.2.1. Customer Information
The customer information contains two essential information to
identify the subscriber.
"customer-account-number" is an internal alphanumerical number
assigned by the service provider to identify the subscriber. It MUST
be unique within the service provider's OSS/BSS system. The actual
format depends on the system tool the provider uses. "customer-name"
is in a more readable form and refers to a more-explicit reference to
the customer. Both identifiers are purely internal to the
organization responsible for the VPN service.
5.2.2. VPN Service Type
The "svc-type" defines service type for provider provisioned L2VPNs.
The current version of the model supports ten flavors:
o Point-to-point Virtual Private Wire Services (VPWS);
o PWE3 (Pseudo-Wire Emulation Edge to Edge) that use LDP-signaled
Pseudowires;
o Multipoint Virtual Private LAN services (VPLS) that use LDP-
signaled Pseudowires;
o Multipoint Virtual Private LAN services (VPLS) that use a Border
Gateway Protocol (BGP) control plane as described in RFC4761 and
RFC6624;
o Ethernet VPNs specified in RFC 7432;
o Ethernet Private Line (EPL) Service with PW core;
o Ethernet Virtual Private Line (EVPL) Service with PW core;
o Ethernet Private LAN (EP-LAN)Service with VPLS core;
o Ethernet Virtual Private LAN (EVP-LAN)Service with VPLS core
Other L2VPN Service Type could be included by augmentation. Note
that EPL service and EVPL service are E-Line service or point to
point EVC service while EP-LAN service and EVP-LAN service are E-LAN
service or multiple point to multipoint EVC service.
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5.2.2.1. EVC
The "evc" container contains "enable" leafand "uni-list" container.
If EVC service for Provider provision L2VPN is required, the
"enabled" leaf MUST be set to true in the "evc" container. "uni-list"
will specify the UNI list associated with this EVC service.
In addition, "evc-type","number of PEs" and "number of sites" can be
specified under the "evc" container.The "evc-type" defines three EVC
service types: Point-to-Point,Multipoint-to-Multipoint, Rooted-
Multipoint. New Ethernet Connection service types can be added by
augmentation in the future. "number of PEs" and "number of sites"
describes the number of PEs and number of sites along with EVC
connection.
E-Line and E-LAN providers shall have an EVC-ID assigned to the UNI-
to-UNI circuit.EVC-ID value will be set to the same VPN-id value
under vpn-service list.
5.2.2.2. OVC
The "ovc-list" under "ovc" container defines a list of "ovc-id"
parameter associated with "evc". The "off-net" leaf MUST be set to
true if one of external interface of "ovc" is UNI and this UNI can
not be reachable by the customer or local site.
For E-Access service as an OVC-based service, the "off-net" leaf MUST
be marked false(i.e., on-net is enabled), and The E-Access service
provider will assign an "ovc-id" for the circuit between UNI and
E-NNI.
If the service is E-Line or E-LAN with remote UNIs, there will be
one, and only one, on-net "ovc-id" and a list of off-net "ovc-id"
objects for the remote UNIs.
Service providers have the option of inserting an outer VLAN tag (the
S-tag) into the service frames from the customer to improve service
scalability and customer VLAN transparency.
The "svlan-id-ethernet-tag" is either the S-tag inserted at a UNI or
the outer tag of ingress packets at an E-NNI. This parameter is
included in the L2SM model to facilitate other management system to
generate proper configuration for the network elements.
Ideally, all external interfaces (UNI and E-NNI) associated with a
given service will have the same S-tag assigned. However, this may
not always be the case. Traffic with all attachments using different
S-tags will need to be "normalized" to a single service S-tag. (One
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example of this is a multipoint service that involves multiple off-
net OVCs terminating on the same E-NNI. Each of these off-net OVCs
will have a distinct S-tag which can be different from the S-tag used
in the on-net part of the service.)
S-VLAN ID Preservation and S-VLAN CoS Preservation apply between two
ENNIs connected by an OVC. These two attributes do NOT affect ENNI
to UNI frame exchange. Preservation means that the value of S-VLAN
ID and/or S-VLAN CoS at one ENNI must be equal to the value at a
different ENNI connected by the OVC. The purpose of the optional
"svlan-id-ethernet-tag" leaf is to identify the service-wide
"normalized S-tag".If optional "svlan-id-perservation" leaf is set to
true, the "svlan-id-ethernet-tag" leaf MUST be configured.
5.2.3. VPN Service Topology
The type of VPN service topology can be used for configuration if
needed. The module currently supports: any-to-any, hub and spoke
(where hubs can exchange traffic). New topologies could be added by
augmentation. By default, the any-to-any VPN service topology is
used.
5.2.3.1. Route Target Allocation
A Layer 2 PE-based VPN (such as VPLS based VPN or EVPN that uses BGP
as signaling protocol ) can be built using route targets (RTs) as
described in [RFC4364][RFC7432]. The management system is expected
to automatically allocate a set of RTs upon receiving a VPN service
creation request. How the management system allocates RTs is out of
scope for this document, but multiple ways could be envisaged, as
described in the section 6.2.1.1 of [RFC8049].
5.2.3.2. Any-to-Any
+------------------------------------------------------------+
| VPN1_Site1 ------ PE1 PE2 ------ VPN1_Site2 |
| |
| VPN1_Site3 ------ PE3 PE4 ------ VPN1_Site4 |
+------------------------------------------------------------+
Any-to-Any VPN Service Topology
In the any-to-any VPN service topology, all VPN sites can communicate
with each other without any restrictions. The management system that
receives an any-to-any L2VPN service request through this model is
expected to assign and then configure the VFI/VSI/EVI and RTs on the
appropriate PEs. In the any-to-any case, a single RT is generally
required, and every VFI/VSI/EVI imports and exports this RT.
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5.2.3.3. Hub and Spoke
+-------------------------------------------------------------+
| Hub_Site1 ------ PE1 PE2 ------ Spoke_Site1 |
| +----------------------------------+
| |
| +----------------------------------+
| Hub_Site2 ------ PE3 PE4 ------ Spoke_Site2 |
+-------------------------------------------------------------+
Hub-and-Spoke VPN Service Topology
In the Hub-and-Spoke VPN service topology, all Spoke sites can
communicate only with Hub sites but not with each other, and Hubs can
also communicate with each other. The management system that owns an
any-to-any L2 VPN service request through this model is expected to
assign and then configure the VFI/VSI/EVI and RTs on the appropriate
PEs. In the Hub-and-Spoke case, two RTs are generally required (one
RT for Hub routes and one RT for Spoke routes). A Hub VFI/VSI/EVI
that connects Hub sites will export Hub routes with the Hub RT and
will import Spoke routes through the Spoke RT. It will also import
the Hub RT to allow Hub-to-Hub communication. A Spoke VFI/VSI/EVI
that connects Spoke sites will export Spoke routes with the Spoke RT
and will import Hub routes through the Hub RT.
5.2.4. Cloud Access
This model provides cloud access configuration through the cloud-
access container. The usage of cloud-access is targeted for public
cloud and Internet Access. The cloud-access container provides
parameters for authorization rules.
Private cloud access may be addressed through the site contianer as
described in Section 5.3 with the use consistent with sites of type
E-NNI.
A cloud identifier is used to reference the target service. This
identifier is local to each administration.
By default, all sites in the IP VPN MUST be authorized to access the
cloud. If restrictions are required, a user MAY configure the
"permit-site" or "deny-site" leaf-list. The permit-site leaf-list
defines the list of sites authorized for cloud access. The deny-site
leaf-list defines the list of sites denied for cloud access. The
model supports both "deny-any-except" and "permit-any-except"
authorization.
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How the restrictions will be configured on network elements is out of
scope for this document.
L2VPN
++++++++++++++++++++++++++++++++ ++++++++++++
+ Site 3 + --- + Cloud 1 +
+ Site 1 + ++++++++++++
+ +
+ Site 2 + --- ++++++++++++
+ + + Internet +
+ Site 4 + ++++++++++++
++++++++++++++++++++++++++++++++
|
+++++++++++
+ Cloud 2 +
+++++++++++
In the example above, we configure the global VPN to access the
Internet by creating a cloud-access pointing to the cloud identifier
for the Internet service. No authorized sites will be configured, as
all sites are required to access the Internet.
123456487
INTERNET
If Site 1 and Site 2 require access to Cloud 1, a new cloud-access
pointing to the cloud identifier of Cloud 1 will be created. The
permit-site leaf-list will be filled with a reference to Site 1 and
Site 2.
123456487
Cloud1
site1
site2
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If all sites except Site 1 require access to Cloud 2, a new cloud-
access pointing to the cloud identifier of Cloud 2 will be created.
The deny-site leaf-list will be filled with a reference to Site 1.
123456487
Cloud2
site1
5.2.5. Metro Ethernet Network Partition
Some service providers may divide their Metro Ethernet network into
multiple administrative domains. And a EVC service may span across
multiple such administrative domains belonging to the same service
provider and be concatenated by one or multiple OVC segments. Each
administrative domain has corresponding OVC segment. The optional
"metro-networks" container is intended be used by these multi-domain
providers to differentiate intra-market versus inter-market services.
When the "inter-mkt-service" leaf is marked TRUE, multiple associated
"metro-mkt-id"s will be listed. Otherwise, the service is intra-
domain and only one "metro-mkt-id" is allowed. In addition, "ovc-
id""site-id" can be used to describe OVC and Site associated with the
specific "metro-mkt-id".
| |
UNI | ENNI ENNI UNI|
+-----------+ | -------- | -------- | -------- |+-----------+
| | | / \ | / \ | / \ || |
| New York | || Acccess |||Transport ||| Service ||| Paris |
| Site | || Provider ||| Provider ||| Provider ||| Site |
| | || #1 ||| #2 ||| #3 ||| |
+-----------+ | \ / | \ / | \ / |+-----------+
| -------- | -------- | -------- |
| | EVC | |
|<------------------------------------>|
| | | |
| OVC1 | OVC2 | OVC3 |
|<---------->|<---------->|<---------->|
| | | |
In the example below, New York Site want to connect Paris Site across
3 adminstrative domains, with OVC in each domain:
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12456487
UNI-Paris
UNI-NewYork
ovc1
ovc2
ovc3
1
TRUE
Access-Provider#1
ovc1
Transport-Provider#2
ovc2
Service-Provider#1
ovc3
5.2.6. Extranet VPNs
There are some cases where a particular VPN needs access to resources
(servers, hosts, etc.) that are external. Those resources may be
located in another VPN.
+-----------+ +-----------+
/ \ / \
Site A -- | VPN A | --- | VPN B | --- Site B
\ / \ / (Shared
+-----------+ +-----------+ resources)
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In the figure above, VPN B has some resources on Site B that need to
be available to some customers/partners. VPN A must be able to
access those VPN B resources.
Such a VPN connection scenario can be achieved via a VPN policy as
defined in Section 5.5.2.2. But there are some simple cases where a
particular VPN (VPN A) needs access to all resources in another VPN
(VPN B). The model provides an easy way to set up this connection
using the "extranet-vpns" container.
The extranet-vpns container defines a list of VPNs a particular VPN
wants to access. The extranet-vpns container must be used on
customer VPNs accessing extranet resources in another VPN. In the
figure above, in order to provide VPN A with access to VPN B, the
extranet-vpns container needs to be configured under VPN A with an
entry corresponding to VPN B. There is no service configuration
requirement on VPN B.
Readers should note that even if there is no configuration
requirement on VPN B, if VPN A lists VPN B as an extranet, all sites
in VPN B will gain access to all sites in VPN A.
The "site-role" leaf defines the role of the local VPN sites in the
target extranet VPN service topology. Site roles are defined in
Section 5.4.
In the example below, VPN A accesses VPN B resources through an
extranet connection. A Spoke role is required for VPN A sites, as
sites from VPN A must not be able to communicate with each other
through the extranet VPN connection.
VPNB
hub-spoke
VPNA
any-to-any
VPNB
spoke-role
This model does not define how the extranet configuration will be
achieved.
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Any VPN interconnection scenario that is more complex (e.g., only
certain parts of sites on VPN A accessing only certain parts of sites
on VPN B) needs to be achieved using a VPN attachment as defined in
Section 5.5.2, and especially a VPN policy as defined in
Section 5.5.2.2.
5.2.7. CVLAN ID To SVC MAP
When more than one service is multiplexed onto the same interface,
ingress service frames are conditionally transmitted through one of
VPN services based upon pre-arranged customer VLAN to SVC mapping.
Multiple customer VLANs can be bundled across the same SVC.The
bundling type will determine how a set of CLAN is bundled into one
VPN service.
"cvlan-id-to-svc-map", when applicable, contains the list of customer
vlans that are mapped to the same service. In most cases, this will
be the VLAN access-list for the inner 802.1q tag (the C-tag).
An EVC can be set to preserve the CE-VLAN ID and CE-VLAN CoS from
ingress to egress. This is required when the customer is using the
VLAN header information between its locations. CE-VLAN ID
Preservation and CE-VLAN CoS Preservation apply between two UNIs
connected by EVC. Preservation means that the value of CE-VLAN ID
and/or CE-VLAN CoS at one UNI must be equal to the value at a
different UNI connected by the same EVC.
If All-to-One bundling is Enabled (i.e., bundling type is set to all-
to-one bundling), then preservation applies to all Ingress service
frames. If All-to-One bundling is Disabled , then preservation
applies to tagged Ingress service frames having CE-VLAN ID.
5.2.8. Service Level MAC Limit
When multiple services are provided on the same network element, the
MAC address table (and the Routing Information Base space for MAC-
routes in the case of EVPN) is a shared common resource. Service
providers may impose a maximum number of MAC addresses learned from
the customer for a single service instance, and may specify the
action when the upper limit is exceeded: drop the packet, flood the
packet, or simply send a warning log message.
For point-to-point services, if MAC learning is disabled then the MAC
address limit is not necessary.
The optional "service-level-mac-limit" container contains the
customer MAC address limit and information to describe the action
when the limit is exceeded.
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5.2.9. Service Protection
The optional "service-protection" container is used to capture the
desired service protection agreement between customer and provider.
Sometimes the customer may desire end-to-end protection at the
service level for applications with high availability requirements.
There are two protection schemes to offer redundant services:
o 1+1 protection: In this scheme, the primary circuit will be
protected by a backup circuit, typically meeting certain diverse
path/fiber/site/node criteria. Both primary and protection
circuits are provisioned to be in the active forwarding state.
The customer may choose to send the same service frames across
both circuits simultaneously.
o 1:1 protection: In this scheme, a backup circuit to the primary
circuit is provisioned. Depending on the implementation
agreement, the protection circuits may either always be in active
forwarding state, or may only become active when a faulty state is
detected on the primary circuit.
5.2.10. Multicast Service
Multicast in L2VPNs is described in [RFC5501][RFC7117].
If multicast support is required for an L2VPN, some global multicast
parameters are required as input for the service request. When a CE
sends (1) Broadcast, (2) Multicast, or (3) Unknown destination
unicast, replication occurs at ingress PE, therefore three traffic
type is supported.
Users of this model will need to provide the flavors of trees that
will be used by customers within the L2VPN (customer tree). The
proposed model supports bidirectional, shared, and source-based trees
(and can be augmented). Multiple flavors of trees can be supported
simultaneously.
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Operator network
______________
/ \
| |
(SSM tree) |
Recv -- Site2 ------- PE2 |
| PE1 --- Site1 --- Source1
| | \
| | -- Source2
| |
(ASM tree) |
Recv -- Site3 ------- PE3 |
| |
(SSM tree) |
Recv -- Site4 ------- PE4 |
| / |
Recv -- Site5 -------- |
(ASM tree) |
| |
\_______________/
Group to port mappings can be created using the "rp-group-mappings"
leaf. Two group to port mapping method are supported:
o Static configuration of multicast Ethernet addresses and ports/
interfaces.
o Multicast control protocol based on Layer-2 technology that
signals mappings of multicast addresses to ports/interfaces, such
as Generic Attribute Registration Protocol / GARP Multicast
Registration Protocol (GARP/GMRP) [802.1D].
5.3. Site Overview
A site represents a connection of a customer office to one or more
VPN services.
+-------------+
/ \
+------------------+ +-----| VPN1 |
| | | \ /
| New York Office |------ (site) -----+ +-------------+
| | | +-------------+
+------------------+ | / \
+-----| VPN2 |
\ /
+-------------+
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The "site" container is used for the provider to store information of
detailed implementation arrangements made with either the customer or
peer operators at each inter-connect location.
We are restricting the L2SM to exterior interfaces only, so all
internal interfaces and the underlying topology are outside the scope
of L2SM.
Typically, the following characteristics of a site interface handoff
need to be documented as part of the service design:
Unique identifier (site-id): An arbitrary string to uniquely
identify the site within the overall network infrastructure. The
format of site-id is determined by the local administration of the
VPN service.
Site Type (site-type): Defines the way the VPN multiplexing is done.
Device (device): The customer can request one or more customer
premise equipments from the service provider for a particular
site.
Management (management): Defines the model of management of the
site, for example: type, management-transport, address.
Location (location): The site location information to allow easy
retrieval of data on which are the nearest available resources.
Site diversity (site-diversity): Presents some parameters to support
site diversity.
Signaling Options(signaling-options): Defines which protocol or
signaling must be activated between the customer and the provider.
Load balancing (load-balance-options): Defines the load-balancing
agreement information between the customer and provider.
Site Network Accesses (site-network-accesses): Defines the list of
ports to the sites and their properties: especially bearer,
connection and service parameters.
A site-network-access represents an Ethernet logical connection of a
site. A site may have multiple site-network-accesses.
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+------------------+ Site
| |-----------------------------------
| |****** (site-network-access#1) ******
| New York Office |
| |****** (site-network-access#2) ******
| |-----------------------------------
+------------------+
Multiple site-network-accesses are used, for instance, in the case of
multihoming. Some other meshing cases may also include multiple
site-network-accesses.
The site configuration is viewed as a global entity; we assume that
it is mostly the management system's role to split the parameters
between the different elements within the network. For example, in
the case of the site-network-access configuration, the management
system needs to split the overall parameters between the PE
configuration and the CE configuration.
5.3.1. Devices and Locations
The information in the "location" sub-container under a "site"and
"device" container allows easy retrieval of data about which are the
nearest available facilities and can be used for access topology
planning. It may also be used by other network orchestration
component to choose the targeted upstream PE and downstream CE.
Location is expressed in terms of postal information.
A site may be composed of multiple locations. All the locations will
need to be configured as part of the "locations" container and list.
A typical example of a multi-location site is a headquarters office
in a city composed of multiple buildings. Those buildings may be
located in different parts of the city and may be linked by intra-
city fibers (customer metropolitan area network). In such a case,
when connecting to a VPN service, the customer may ask for
multihoming based on its distributed locations.
New York Site
+------------------+ Site
| +--------------+ |-----------------------------------
| | Manhattan | |****** (site-network-access#1) ******
| +--------------+ |
| +--------------+ |
| | Brooklyn | |****** (site-network-access#2) ******
| +--------------+ |
| |-----------------------------------
+------------------+
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A customer may also request some premises equipment entities (CEs)
from the SP via the "devices" container. Requesting a CE implies a
provider-managed or co-managed model. A particular device must be
ordered to a particular already-configured location. This would help
the SP send the device to the appropriate postal address. In a
multi-location site, a customer may, for example, request a CE for
each location on the site where multihoming must be implemented. In
the figure above, one device may be requested for the Manhattan
location and one other for the Brooklyn location.
By using devices and locations, the user can influence the
multihoming scenario he wants to implement: single CE, dual CE, etc.
5.3.2. Signaling Option
The "signaling-option" container captures service-wide attributes of
the L2VPN instance.
Although topology discovery or network device configuration is
purposely out of scope for the L2SM model, certain VPN parameters for
discovery are listed here. The information can then be passed to
other elements in the whole automation eco-system (such as the
configuration engine) which will handle the actual service
provisioning function.
[RFC6074] describes the provisioning, auto-Discovery, and signaling
in L2VPNs. It specifies a number of L2VPN provisioning models, and
further specifies the semantic structure of the endpoint identifiers
required by each model, as well as the distribution of these
identifiers by the discovery process, and then specifies how the
endpoint identifiers are carried in the signaling protocols (e.g.
LDP and L2TPv3).
The "signaling-option" list uses the "type" as the index. The "type"
leaf is for the signaling protocol: BGP- L2VPN, BGP-EVPN, T-LDP or
L2TP.
5.3.2.1. BGP L2VPN
[RFC4761] and [RFC6624] describe the mechanism to auto-discover L2VPN
VPLS/VPWS end points (CE-ID or VE-ID) and signal the label base and
offset at the same time to allow remote PE to derive the VPN label to
be used when sending packets to the advertising router.
In addition [RFC6624] makes interesting considerations about the
L2VPN Scaling scheme and the separation of Administrative
Responsibilities between Customer and Service Provider.
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Due to the way auto-discovery operates, PEs that have at least one
attachment circuit associated with a particular VPN service do not
need to be specified explicitly.
In the L2SM model, the target community (or communities) is also not
specified since the management system allocates the route target upon
receiving VPN creation request.
The "type" leaf under "mp-bgp-l2vpn" is an identityref to specify
"vpws" or "vpls" sub-types.
5.3.2.2. BGP EVPN
Defined in [RFC7432], EVPN is an L2VPN technology based upon BGP MAC
routing. It provides similar functionality to BGP VPWS/VPLS with
improvement around redundancy, multicast optimization, provisioning,
and simplicity.
Due to the way auto-discovery operates, PEs that have at least one
attachment circuit associated with a particular VPN service do not
need to be specified explicitly.
In the L2SM model, the target community (or communities) is also not
specified since the management system allocates the route target upon
receiving VPN creation request.
The "type" leaf under "mp-bgp-evpn" is an identityref to specify
"vpws" or "vpls" sub-types.
5.3.2.3. LDP Pseudowires
[RFC4762] specifies the method of using targeted LDP sessions between
PEs to exchange VC label information. This requires a configured
full mesh of targeted LDP sessions between all PEs.
As multiple attachment circuits may terminate on a single PE, this
PE-to-PE mesh is not a per-site attribute. All PEs related to the
L2VPN service will be listed in the "t-ldp-pwe" with associated "vc-
id".
The "type" leaf under "mp-bgp-evpn" is an identityref to specify
"vpws" ,"vpls", "h-vpls"sub-types. In case of "h-vpls", "qinq" leaf
must be specified.
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5.3.2.4. PWE Encapsulation Type
Based on [RFC4448], there are two types of Ethernet services: "Port-
to-Port Ethernet PW emulation" and "VLAN-to-VLAN Ethernet PW
emulation", commonly referred to as Type 5 and Type 4 respectively.
This concept applies to both BGP L2VPN VPWS/VPLS and T-LDP signaled
PWE implementations.
The "pwe-encapsulation-type" has two types: "ethernet" and "ethernet-
vlan". If "signaling-option" is "mp-bgp-l2vpn" or "t-ldp-pwe", then
"pwe-encapsulation-type" must be set one of "ethernet" and "ethernet-
vlan" .
5.3.2.5. PWE MTU
During the signaling process of a BGP-L2VPN or T-LDP pseudowire, the
pwe-mtu value is exchanged and must match at both ends. By default,
the pwe-mtu is derived from physical interface MTU of the attachment
circuit minus the EoMPLS transport header. In some cases, however,
the physical interface on both ends of the circuit might not have
identical MTU settings. For example, due to 802.1ad q-in-q
operation, an I-NNI will need an extra four bytes to accommodate the
S-tag. The inter-carrier E-NNI link may also have a different MTU
size than the internal network interfaces.
[RFC4448] requires the same MTU size on physical interfaces at both
ends of the pseudowire. In actual implementations, many router
vendors have provided a knob to explicitly specify the pwe-mtu, which
can then be decoupled from the physical interface MTU.
When there is a mismatch between the physical interface MTU and
configured pwe-mtu, the "allow-mtu-mismatch" leaf in the "pwe-mtu"
contained enables definition of the required behavior.
5.3.2.6. Control Word
A control word is an optional 4-byte field located between the MPLS
label stack and the Layer 2 payload in the pseudowire packet. It
plays a crucial role in Any Transport over MPLS (AToM). The 32-bit
field carries generic and Layer 2 payload-specific information,
including a C-bit which indicates whether the control word will
present in the Ethernet over MPLS (EoMPLS) packets. If the C-bit is
set to 1, the advertising PE expects the control word to be present
in every pseudowire packet on the pseudowire that is being signaled.
If the C-bit is set to 0, no control word is expected to be present.
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Whether to include control word in the pseudowire packets MUST match
on PEs at both ends of the pseudowire and it is non-negotiable during
the signaling process.
The use of a control-word applies to pseduowires signaled using
either BGP L2VPN VPWS/VPLS or T-LDP. It is a routing-instance level
configuration parameter in many cases.
The optional "control-word" leaf is a Boolean field in the L2SM model
for the provider to explicitly specify whether the control-word will
be signaled for the service instance.
5.3.2.7. L2TP Pseudowires
In the L2VPN framework , a LAC is a Provider Edge (PE) device. In
the LAC-LAC reference model, a LAC serves as a cross-connect between
attachment circuits and L2TP sessions. Each L2TP session acts as an
emulated circuit, also known as pseudowire. A pseudowire is used to
bind two attachment circuits together. For different L2VPN
applications, different types of attachment circuits are defined.
The "encapsulation-type" has one type,i.e.,l2tp type.
The optional "control-word" leaf is a Boolean field in the L2SM model
for the provider to explicitly specify whether the control-word will
be signaled for the service instance.
5.3.3. Load Balance Option
As the subscribers start to deploy more 10G or 100G Ethernet
equipment in their network, the demand for high bandwidth Ethernet
connectivity services increases. These high bandwidth service
requests also pose challenges on capacity planning and service
delivery in the provider's network, especially when the contractual
bandwidth is at, or close to, the speed of physical links of the
service provider's core network. Because of the encapsulation
overhead, the provider cannot deliver the throughput in the service
level agreement over a single link. Although there may be bundled
aggregation links between core network elements, or Equal Cost
Multiple Paths (ECMP) in the network, an Ethernet-over-MPLS (EoMPLS)
PWE or VxLAN circuit is still considered with a single data flow to a
router or switch which uses the normal IP five-tuples in the hashing
algorithm.
Without burdening the core routers with additional processing of deep
inspection into the payload, the service provider now has the option
of inserting a flow or entropy label into the EoMPLS frames, or using
different source UDP ports in case of VxLAN/EVPN, at ingress PE to
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facility load-balancing on the subsequent nodes along the path. The
ingress PE is in a unique position to see the actual unencapsulated
service frames and identify data flows based on the original Ethernet
and IP header.
On the other hand, not all Layer 2 Ethernet VPNs are suited for load-
balancing across diverse ECMP paths. For example, a Layer 2 Ethernet
service transported over a single RSVP signaled Label Switched Path
will not take multiple ECMP routes. Or if the subscriber is
concerned about latency/jitter, then diverse path load-balancing can
be undesirable.
The optional "load-balance-option" container is used to capture the
load-balancing agreement between the subscriber and the provider. If
the "load-balance" Boolean leaf is marked TRUE, then one of the
following load-balance methods can be selected: "fat-pw", "entropy-
label", or "vxlan-source-udp-port". FAT pseudowires are used to
load-balance traffic in the core when equal cost multipaths are used.
The MPLS labels add an additional label to the stack, called the flow
label, which contains the flow information of a VC.
5.3.4. Site Network Accesses
The L2SM includes a set of essential physical interface properties
and Ethernet layer characteristics in the "site-network-accesses"
container. Some of these are critical implementation arrangements
that require consent from both customer and provider.
As mentioned earlier, a site may be multihomed. Each logical network
access for a site is defined in the "site-network-accesses"
container. The site-network-access parameter defines how the site is
connected on the network and is split into three main classes of
parameters:
o bearer: defines requirements of the attachment (below Layer 2).
o connection: defines Layer 2 protocol parameters of the attachment.
o availability: defines the site's availability policy. The
availability parameters are defined in Section 5.2.8.
The site-network-access has a specific type (site-network-access-
type). This document defines two types:
o point-to-point: describes a point-to-point connection between the
SP and the customer.
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o multipoint: describes a multipoint connection between the SP and
the customer.
The type of site-network-access may have an impact on the parameters
offered to the customer, e.g., an SP may not offer encryption for
multipoint accesses. It is up to the provider to decide what
parameter is supported for point-to-point and/or multipoint accesses;
which is out of scope for this document. Some containers proposed in
the model may require extensions in order to work properly for
multipoint accesses.
5.3.4.1. Bearer
The "bearer" container defines the requirements for the site
attachment to the provider network that are below Layer 3.
The bearer parameters will help to determine the access media to be
used.
5.3.4.2. Connection
The "connection" container defines the layer 2 protocol parameters of
The attachment(e.g.,vlan-id or circuit-id) and provides connectivity
between customer Ethernet switches. Depending on the management
mode, it refers to PE-CE- LAN segment addressing or CE-to-customer-
LAN segment addressing. In any case, it describes the responsibility
boundary between the provider and the customer. For a customer-
managed site, it refers to the PE- CE LAN Segment connection. For a
provider-managed site, it refers to the CE-to-LAN Segment connection.
"encapsulation-type" is for user to select between Ethernet
encapsulation (port-based) or Ethernet VLAN encapsulation (VLAN-
based). All allowed Ethernet interface types of service frames can
be listed under "ether-inf-type", e.g., Dot1q interface, physical
interface, LAG interface
Corresponding to "ether-inf-type",the connection container also
presents three sets of link attributes: dot1q interface,physical
interface or optional LAG interface attributes. These parameters are
essential for the connection between customer and provider edge
devices to establish properly. The connection container also defines
L2CP attribute to allow control plane protocol interaction between
the CE devices and PE device.
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5.3.4.2.1. Dot1q Interface
A VLAN can be configured for VLAN tagged traffic.If the dot1q service
is enabled on a logical unit on the connection at the interface,
"encapsulation-type ","eth-inf-type" should be specified as Ethernet
VLAN ecapsulation(VLAN-based) and Dot1q interface respectively.
In addition, "l2-access-type" should be specified under "dot1q"
container to determines how VLAN tagging needs to be done.The current
model proposed 5 ways to perform VLAN tagging:
o dot1q: Service providers encapsulate packets between CE and PE
with one or a set of customer VLAN IDs C-VLANs)
o qinq: service providers encapsulate packets that enter the
service-provider network with multiple customer VLAN IDs (C-VLANs)
and a single VLAN tag with a single service provider VLAN
(S-VLAN).
o qinany: service providers encapsulate packets that enter the
service-provider network with unknown C-VLAN and a single VLAN tag
with a single service provider VLAN (S-VLAN).
o vxlan: service providers encapsulate packets that enter the
service-provider network with VNI and peer list.
The overall S-tag for the Ethernet circuit and C-tag to SVC mapping,
if applicable, has been placed in the service container. For qinq an
qinany options, the S-tag under "qinq" and "qinany" should match the
S-tag in the service container in most cases, however, vlan
translation is required for the S-tag in certain deployment at the
external facing interface or upstream PEs to "normalize" the outer
VLAN tag to the service S-tag into the network and translate back to
the site's S-tag in the opposite direction. One example of this is
with a Layer 2 aggregation switch along the path: the S-tag for the
SVC has been previously assigned to another service thus can not be
used by this attachment circuit.
5.3.4.2.2. Physical Interface
For each physical interface (phy-interface), there are basic
configuration parameters like port number and speed, interface MTU,
auto-negotiation and flow-control settings, etc. In addition, the
customer and provider may decide to enable advanced features, such as
LLDP, 802.3AH link OAM, MAC loop detection/ prevention at a UNI,
based on mutual agreement.If Loop avoidance is required, the
attribute "uni-loop-prevention" must be set to TRUE.
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5.3.4.2.3. LAG Interface
Sometimes, the customer may require multiple physical links bundled
together to form a single, logical, point-to-point LAG connection to
the service provider. Typically, LACP (Link Aggregation Control
Protocol) is used to dynamically manage adding or deleting member
links of the aggregate group. In general, LAG allows for increased
service bandwidth beyond the speed of a single physical link while
providing graceful degradation as failure occurs, thus increased
availability.
In the L2SM, there is a set of attributes under "LAG-interface"
related to link aggregation functionality. The customer and provider
first need to decide on whether LACP PDU will be exchanged between
the edge device by specifying the "LACP-state" to "On" or "Off". If
LACP is to be enabled, then both parties need to further specify
whether it will be running in active versus passive mode, plus the
time interval and priority level of the LACP PDU. The customer and
provider can also determine the minimum aggregate bandwidth for a LAG
to be considered valid path by specifying the optional "mini-link"
attribute. To enable fast detection of faulty links, micro-bfd runs
independent UDP sessions to monitor the status of each member link.
Customer and provider should consent to the BFD hello interval and
hold time.
Each member link will be listed under the LAG interface with basic
physical link properties. Certain attributes like flow-control,
encapsulation type, allowed ingress Ethertype and LLDP settings are
at the LAG level.
5.3.4.2.4. L2CP Control
Customer and Service provider should make pre-arrangement on whether
to allow control plane protocol interaction between the CE devices
and PE device. To provide seamless operation with multicast data
transport, the transparent operation of Ethernet control protocols
(e.g., Spanning Tree Protocol [802.1D]) can be employed by customers.
To support efficient dynamic transport, Ethernet multicast control
frames (e.g., GARP/GMRP [802.1D]) can be used between CE and PE.
However, solutions MUST NOT assume all CEs are always running such
protocols (typically in the case where a CE is a router and is not
aware of Layer-2 details).
To facilitate interoperability between different Multiple System
Operators (MSOs), interaction between the edge device of each
administrative domain can be either allowed or keep each
Administrative domain control plane separate on a per-protocol basis.
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the MEF has provided normative guidance on Layer 2 Control Protocol
(L2CP) processing requirements for each service type.
The destination MAC addresses of these L2CP PDUs fall within two
reserved blocks specified by the IEEE 802.1 Working Group. Packet
with destination MAC in these multicast ranges have special
forwarding rules.
o Bridge Block of Protocols: 01-80-C2-00-00-00 through
01-80-C2-00-00-0F
o MRP Block of Protocols: 01-80-C2-00-00-20 through
01-80-C2-00-00-2F
Layer 2 protocol tunneling allows service providers to pass
subscriber Layer 2 control PDUs across the network without being
interpreted and processed by intermediate network devices. These
L2CP PDUs are transparently encapsulated across the MPLS-enabled core
network in Q-in-Q fashion.
The "L2CP-control" container contains the list of commonly used L2CP
protocols and parameters. The service provider can specify DISCARD,
PEER, or TUNNEL mode actions for each individual protocol.
In addition, "provider-bridge-group" and "provider-bridge-mvrp"
addresses are also listed in the L2CP container.
5.4. Site Role
A VPN has a particular service topology, as described in
Section 5.1.3. As a consequence, each site belonging to a VPN is
assigned with a particular role in this topology. The site-role leaf
defines the role of the site in a particular VPN topology.
In the any-to-any VPN service topology, all sites MUST have the same
role, which will be "any-to-any-role".
In the Hub-and-Spoke VPN service topology or the Hub and Spoke
disjoint VPN service topology, sites MUST have a Hub role or a Spoke
role.
5.5. Site Belonging to Multiple VPNs
5.5.1. Site VPN Flavor
A site may be part of one or multiple VPNs. The "site-type" defines
the way the VPN multiplexing is done. There are three possible types
of external facing connections associated with an Ethernet VPN
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service and a site. Therefore the current version of the model
supports three flavors:
o site-vpn-flavor-single: The site belongs to only one VPN.
o site-vpn-flavor-multi: The site belongs to multiple VPNs, and all
the logical accesses of the sites belong to the same set of VPNs.
o site-vpn-flavor-enni: The site represents an ENNI where two
Ethernet service providers inter-connect with each other.
o site-vpn-flavor-e2e: The site represents end to end mult-segment
connection.
5.5.1.1. Single VPN Attachment: site-vpn-flavor-single
The figure below describes a single VPN attachment. The site
connects to only one VPN.
+--------+
+------------------+ Site / \
| |-----------------------------| |
| |***(site-network-access#1)***| VPN1 |
| New York Office | | |
| |***(site-network-access#2)***| |
| |-----------------------------| |
+------------------+ \ /
+--------+
5.5.1.2. MultiVPN Attachment: site-vpn-flavor-multi
The figure below describes a site connected to multiple VPNs.
+---------+
+---/----+ \
+------------------+ Site / | \ |
| |--------------------------------- | |VPN B|
| |***(site-network-access#1)******* | | |
| New York Office | | | | |
| |***(site-network-access#2)******* \ | /
| |-----------------------------| VPN A+-----|---+
+------------------+ \ /
+--------+
In the example above, the New York office is multihomed. Both
logical accesses are using the same VPN attachment rules, and both
are connected to VPN A and VPN B.
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Reaching VPN A or VPN B from the New York office will be done via
destination-based routing. Having the same destination reachable
from the two VPNs may cause routing troubles. The customer
administration's role in this case would be to ensure the appropriate
mapping of its prefixes in each VPN.
5.5.1.3. ENNI: site-vpn-flavor-enni
A External Network-to-Network Interface (ENNI) scenario may be
modeled using the sites container. It is helpful for the SP to
indicate that the requested VPN connection is not a regular site but
rather is an ENNI, as specific default device configuration
parameters may be applied in the case of ENNIs (e.g., ACLs, routing
policies).
SP A SP B
------------------- -------------------
/ \ / \
| | | |
| ++++++++ Inter-AS link ++++++++ |
| + +_______________+ + |
| + (VSI1)---(VPN1)----(VSI1) + |
| + ASBR + + ASBR + |
| + (VSI2)---(VPN2)----(VSI2) + |
| + +_______________+ + |
| ++++++++ ++++++++ |
| | | |
| | | |
| | | |
| ++++++++ Inter-AS link ++++++++ |
| + +_______________+ + |
| + (VSI1)---(VPN1)----(VSI1) + |
| + ASBR + + ASBR + |
| + (VSI2)---(VPN2)----(VSI2) + |
| + +_______________+ + |
| ++++++++ ++++++++ |
| | | |
| | | |
\ / \ /
------------------- -------------------
The figure above describes an option A ENNI scenario that can be
modeled using the sites container. In order to connect its customer
VPNs (VPN1 and VPN2) in SP B, SP A may request the creation of some
site-network-accesses to SP B. The site-vpn-flavor-enni will be used
to inform SP B that this is an ENNI and not a regular customer site.
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5.5.1.4. E2E: site-vpn-flavor-e2e
A end to end multi-segment VPN connection to be constructed out of
several connectivity segments may be modeled using EVC and OVC
container. It is helpful for the SP to indicate the requested VPN
connection is not a regular site but rather is an end to end VPN
connectivity, as specific default device configuration parameters may
be applied in case of site-vpn-flavor-e2e (e.g., QoS configuration).
In order to establish connection between Site 1 in SP A and Site 2 in
SP B spanning across multi-domains, SP A may request the creation of
end to end connectivity to SP B. The site-vpn-flavor-e2e will be
used to inform that this is an end to end connectivity setup and not
a regular customer site.
5.5.2. Attaching a Site to a VPN
Due to the multiple site-vpn flavors, the attachment of a site to an
L2VPN is done at the site-network-access (logical access) level
through the "vpn-attachment" container. The vpn-attachment container
is mandatory. The model provides two ways to attach a site to a VPN:
o By referencing the target VPN directly.
o By referencing a VPN policy for attachments that are more complex.
A choice is implemented to allow the user to choose the flavor that
provides the best fit.
5.5.2.1. Referencing a VPN
Referencing a vpn-id provides an easy way to attach a particular
logical access to a VPN. This is the best way in the case of a
single VPN attachment. When referencing a vpn-id, the site-role
setting must be added to express the role of the site in the target
VPN service topology.
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SITE1
LA1
VPNA
spoke-role
LA2
VPNB
spoke-role
The example above describes a multiVPN case where a site (SITE1) has
two logical accesses (LA1 and LA2), attached to both VPNA and VPNB.
5.5.2.2. VPN Policy
The "vpn-policy" list helps express a multiVPN scenario where a
logical access belongs to multiple VPNs.
As a site can belong to multiple VPNs, the vpn-policy list may be
composed of multiple entries. A filter can be applied to specify
that only some LANs of the site should be part of a particular VPN.
Each time a site (or LAN) is attached to a VPN, the user must
precisely describe its role (site-role) within the target VPN service
topology.
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+--------------------------------------------------------------+
| Site1 ------ PE7 |
+-------------------------+ [VPN2] |
| |
+-------------------------+ |
| Site2 ------ PE3 PE4 ------ Site3 |
+----------------------------------+ |
| |
+------------------------------------------------------------+ |
| Site4 ------ PE5 | PE6 ------ Site5 | |
| | |
| [VPN3] | |
+------------------------------------------------------------+ |
| |
+---------------------------+
In the example above, Site5 is part of two VPNs: VPN3 and VPN2. It
will play a Hub role in VPN2 and an any-to-any role in VPN3. We can
express such a multiVPN scenario as follows:
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Site5
POLICY1
ENTRY1
VPN2
hub-role
ENTRY2
VPN3
any-to-any-role
LA1
POLICY1
Now, if a more-granular VPN attachment is necessary, filtering can be
used. For example, if LAN1 from Site5 must be attached to VPN2 as a
Hub and LAN2 must be attached to VPN3, the following configuration
can be used:
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Site5
POLICY1
ENTRY1
LAN1
VPN2
hub-role
ENTRY2
LAN2
VPN3
any-to-any-role
LA1
POLICY1
5.6. Deciding Where to Connect the Site
The management system will have to determine where to connect each
site-network-access of a particular site to the provider network
(e.g., PE, aggregation switch).
The current model proposes parameters and constraints that can
influence the meshing of the site-network-access.
The management system should honor any customer constraints. If a
constraint is too strict and cannot be fulfilled, the management
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system must not provision the site and should provide relevant
information to the user. How the information is provided is out of
scope for this document. Whether or not to relax the constraint
would then be left up to the user.
Parameters are just hints for the management system for service
placement.
In addition to parameters and constraints, the management system's
decision MAY be based on any other internal constraints that are left
up to the SP: least load, distance, etc.
5.6.1. Constraint: Device
In the case of provider management or co-management, one or more
devices have been ordered by the customer. The customer may force a
particular site-network-access to be connected on a particular device
that he ordered.
New York Site
+------------------+ Site
| +--------------+ |-----------------------------------
| | Manhattan | |
| | CE1********* (site-network-access#1) ******
| +--------------+ |
| +--------------+ |
| | Brooklyn CE2********* (site-network-access#2) ******
| +--------------+ |
| |-----------------------------------
+------------------+
In the figure above, site-network-access#1 is associated with CE1 in
the service request. The SP must ensure the provisioning of this
connection.
5.6.2. Constraint/Parameter: Site Location
The location information provided in this model MAY be used by a
management system to determine the target PE to mesh the site (SP
side). A particular location must be associated with each site
network access when configuring it. The SP MUST honor the
termination of the access on the location associated with the site
network access (customer side). The "country-code" in the site
location should be expressed as an ISO ALPHA-2 code.
The site-network-access location is determined by the "location-
flavor". In the case of a provider-managed or co-managed site, the
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user is expected to configure a "device-reference" (device case) that
will bind the site-network-access to a particular device that the
customer ordered. As each device is already associated with a
particular location, in such a case the location information is
retrieved from the device location. In the case of a customer-
managed site, the user is expected to configure a "location-
reference" (location case); this provides a reference to an existing
configured location and will help with placement.
POP#1 (New York)
+---------+
| PE1 |
Site #1 ---... | PE2 |
(Atlantic City) | PE3 |
+---------+
POP#2 (Washington)
+---------+
| PE4 |
| PE5 |
| PE6 |
+---------+
POP#3 (Philadelphia)
+---------+
| PE7 |
Site #2 CE#1---... | PE8 |
(Reston) | PE9 |
+---------+
In the example above, Site #1 is a customer-managed site with a
location L1, while Site #2 is a provider-managed site for which a CE
(CE#1) was ordered. Site #2 is configured with L2 as its location.
When configuring a site-network-access for Site #1, the user will
need to reference location L1 so that the management system will know
that the access will need to terminate on this location. Then, for
distance reasons, this management system may mesh Site #1 on a PE in
the Philadelphia POP. It may also take into account resources
available on PEs to determine the exact target PE (e.g., least
loaded). For Site #2, the user is expected to configure the site-
network-access with a device-reference to CE#1 so that the management
system will know that the access must terminate on the location of
CE#1 and must be connected to CE#1. For placement of the SP side of
the access connection, in the case of the nearest PE used, it may
mesh Site #2 on the Washington POP.
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5.6.3. Constraint/Parameter: Access Type
The management system needs to elect the access media to connect the
site to the customer (for example, xDSL, leased line, Ethernet
backhaul). The customer may provide some parameters/constraints that
will provide hints to the management system.
The bearer container information SHOULD be the first piece of
information considered when making this decision:
o The "requested-type" parameter provides information about the
media type that the customer would like to use. If the "strict"
leaf is equal to "true", this MUST be considered a strict
constraint so that the management system cannot connect the site
with another media type. If the "strict" leaf is equal to "false"
(default) and if the requested media type cannot be fulfilled, the
management system can select another media type. The supported
media types SHOULD be communicated by the SP to the customer via a
mechanism that is out of scope for this document.
o The "always-on" leaf defines a strict constraint: if set to true,
the management system MUST elect a media type that is "always-on"
(e.g., this means no dial access type).
o The "bearer-reference" parameter is used in cases where the
customer has already ordered a network connection to the SP apart
from the L2VPN site and wants to reuse this connection. The
string used is an internal reference from the SP and describes the
already-available connection. This is also a strict requirement
that cannot be relaxed. How the reference is given to the
customer is out of scope for this document, but as a pure example,
when the customer ordered the bearer (through a process that is
out of scope for this model), the SP may have provided the bearer
reference that can be used for provisioning services on top.
Any other internal parameters from the SP can also be used. The
management system MAY use other parameters, such as the requested
"svc-input-bandwidth" and "svc-output-bandwidth", to help decide
which access type to use.
5.6.4. Constraint: Access Diversity
Each site-network-access may have one or more constraints that would
drive the placement of the access. By default, the model assumes
that there are no constraints, but allocation of a unique bearer per
site-network-access is expected.
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In order to help with the different placement scenarios, a site-
network-access may be tagged using one or multiple group identifiers.
The group identifier is a string, so it can accommodate both explicit
naming of a group of sites (e.g., "multihomed-set1") and the use of a
numbered identifier (e.g., 12345678). The meaning of each group-id
is local to each customer administrator, and the management system
MUST ensure that different customers can use the same group-ids. One
or more group-ids can also be defined at the site level; as a
consequence, all site-network-accesses under the site MUST inherit
the group-ids of the site they belong to. When, in addition to the
site group-ids some group-ids are defined at the site-network-access
level, the management system MUST consider the union of all groups
(site level and site network access level) for this particular site-
network-access.
For an already-configured site-network-access, each constraint MUST
be expressed against a targeted set of site-network-accesses. This
site-network-access MUST never be taken into account in the targeted
set -- for example, "My site-network-access S must not be connected
on the same POP as the site-network-accesses that are part of Group
10." The set of site-network-accesses against which the constraint
is evaluated can be expressed as a list of groups, "all-other-
accesses", or "all-other-groups". The all-other-accesses option
means that the current site-network-access constraint MUST be
evaluated against all the other site-network-accesses belonging to
the current site. The all-other-groups option means that the
constraint MUST be evaluated against all groups that the current
site-network-access does not belong to.
The current model proposes multiple constraint-types:
o pe-diverse: The current site-network-access MUST NOT be connected
to the same PE as the targeted site-network-accesses.
o pop-diverse: The current site-network-access MUST NOT be connected
to the same POP as the targeted site-network-accesses.
o linecard-diverse: The current site-network-access MUST NOT be
connected to the same linecard as the targeted site-network-
accesses.
o bearer-diverse: The current site-network-access MUST NOT use
common bearer components compared to bearers used by the targeted
site-network-accesses. "bearer-diverse" provides some level of
diversity at the access level. As an example, two bearer-diverse
site-network-accesses must not use the same DSLAM, BAS, or Layer 2
switch.
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o same-pe: The current site-network-access MUST be connected to the
same PE as the targeted site-network-accesses.
o same-bearer: The current site-network-access MUST be connected
using the same bearer as the targeted site-network-accesses.
These constraint-types can be extended through augmentation. Each
constraint is expressed as "The site-network-access S must be
(e.g., pe-diverse, pop-diverse) from these
site-network-accesses."
The group-id used to target some site-network-accesses may be the
same as the one used by the current site-network-access. This eases
the configuration of scenarios where a group of site-network-access
points has a constraint between the access points in the group.
5.7. Route Distinguisher and Network Instance Allocation
The route distinguisher (RD) is a critical parameter of BGP-based
L2VPNs as described in [RFC4364] that provides the ability to
distinguish common addressing plans in different VPNs. As for route
targets (RTs), a management system is expected to allocate a VSI or
MAC-VRF on the target PE and an RD for this VSI or MAC-VRF.This RD
MUST be unique across all MAC-VRFs on the target PE.
If a VSI already exists on the target PE and the VSI fulfills the
connectivity constraints for the site, there is no need to recreate
another VSI, and the site MAY be meshed within this existing VSI.
How the management system checks that an existing VSI fulfills the
connectivity constraints for a site is out of scope for this
document.
If no such VSI exists on the target PE, the management system has to
initiate the creation of a new VSI or MAC-VRF on the target PE and
has to allocate a new RD for this new VSI or MAC-VRF.
The management system MAY apply a per-VPN or per-VSI allocation
policy for the RD, depending on the SP's policy. In a per-VPN
allocation policy, all VSIs (dispatched on multiple PEs) within a VPN
will share the same RD value. In a per-VSI model, all VSIs or MAC-
VRF should always have a unique RD value. Some other allocation
policies are also possible, and this document does not restrict the
allocation policies to be used.
The allocation of RDs MAY be done in the same way as RTs. The
examples provided in Section 5.2.3.1 could be reused in this
scenario.
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Note that an SP MAY configure a target PE for an automated allocation
of RDs. In this case, there will be no need for any backend system
to allocate an RD value.
5.8. Site Network Access Availability
A site may be multihomed, meaning that it has multiple site-network-
access points. Placement constraints defined in previous sections
will help ensure physical diversity.
When the site-network-accesses are placed on the network, a customer
may want to use a particular routing policy on those accesses. The
"site-network-access/availability" container defines parameters for
site redundancy. The "access-priority" leaf defines a preference for
a particular access. This preference is used to model load-balancing
or primary/backup scenarios. The higher the access-priority value,
the higher the preference will be. The "redundancy mode" attribute
is defined for an multi-homing site and used to model single-active
and active/active scenarios. It allows for multiple active paths in
forwarding state and for load-balancing options.
The figure below describes how the access-priority attribute can be
used.
Hub#1 LAN (Primary/backup) Hub#2 LAN (Load-sharing)
| |
| access-priority 1 access-priority 1 |
|--- CE1 ------- PE1 PE3 --------- CE3 --- |
| |
| |
|--- CE2 ------- PE2 PE4 --------- CE4 --- |
| access-priority 2 access-priority 1 |
PE5
|
|
|
CE5
|
Spoke#1 site (Single-homed)
In the figure above, Hub#2 requires load-sharing, so all the site-
network-accesses must use the same access-priority value. On the
other hand, as Hub#1 requires a primary site-network-access and a
backup site-network-access, a higher access-priority setting will be
configured on the primary site-network-access.
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Scenarios that are more complex can be modeled. Let's consider a Hub
site with five accesses to the network (A1,A2,A3,A4,A5). The
customer wants to load-share its traffic on A1,A2 in the nominal
situation. If A1 and A2 fail, the customer wants to load-share its
traffic on A3 and A4; finally, if A1 to A4 are down, he wants to use
A5. We can model this easily by configuring the following access-
priority values: A1=100, A2=100, A3=50, A4=50, A5=10.
The access-priority scenario has some limitations. An access-
priority scenario like the previous one with five accesses but with
the constraint of having traffic load-shared between A3 and A4 in the
case where A1 OR A2 is down is not achievable. But the authors
believe that using the access-priority attribute will cover most of
the deployment use cases and that the model can still be extended via
augmentation to support additional use cases.
5.9. SVC MTU
The maximum MTU of subscriber service frames can be derived from the
physical interface MTU by default, or specified under the "svc-mtu"
leaf if it is different than the default number.
5.10. Service
The "service" container defines service parameters associated with
the site.
5.10.1. Bandwidth
The service bandwidth refers to the bandwidth requirement between CE
and PE. The requested bandwidth is expressed as svc-input-bandwidth
and svc-output-bandwidth. Input/output direction is using customer
site as reference: input bandwidth means download bandwidth for the
site, and output bandwidth means upload bandwidth for the site.
The service bandwidth is only configurable at the site-network-access
level (i.e., for the site network access associated with the site).
Using a different input and output bandwidth will allow service
provider to know if a customer allows for asymmetric bandwidth access
like ADSL. It can also be used to set a rate-limit in a different
way for upload and download on symmetric bandwidth access.
The svc-input-bandwidth or svc-output-bandwidth has specific type.
This document defines four types:
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o bw-per-access Bandwidth is per connection or site network access,
providing rate enforcement for all service frames at the interface
that are associated with a particular network access.
o bw-per-cos Bandwidth is per cos ,providing rate enforcement for
all service frames for a given class of service with specific cos-
id.
o bw-per-svc bandwidth is per site, providing rate enforcement for
all service frames that are associated with a particular vpn-id.
o opaque bandwidth is the total bandwidth that is not associated
with any particular cos-id, vpn-id or site network access id.
The svc-input-bandwidth or svc-output-bandwidth must include a "cos-
id" parameter if the 'type' is set as 'bw-per-cos'. The cos-id can
be assigned based on dot1p value in C-tag, or DSCP in IP header.
Ingress service frames are metered against the bandwidth profile
based on the cos- identifier.
The svc-input-bandwidth or svc-output-bandwidth must be associated
specific "site-network-access- id" parameter if the 'type' is set as
'bw-per-access'. Multiple input/output-bandwidth per-cos-id can be
associated with the same Site Network access.
The svc-input-bandwidth or svc-output-bandwidth must include specific
"vpn-id" parameter if the 'type' is set as 'bw-per-svc'. Multiple
input/output-bandwidth per-cos-id can be associated with the same
Ethernet VPN service.
5.10.2. QoS
The model defines QoS parameters as an abstraction:
o qos-classification-policy: Defines a set of ordered rules to
classify customer traffic.
o qos-profile: Provides a QoS scheduling profile to be applied.
5.10.2.1. QoS Classification
QoS classification rules are handled by qos-classification-policy.
The qos-classification-policy is an ordered list of rules that match
a flow or application and set the appropriate target class of service
(target-class-id). The user can define the match using physical port
reference or a more specific flow definition (based layer 2 source
and destination MAC address, cos,dscp,cos-id, color-id etc.). A
"color-id" will be assigned to a service frame to identify its QoS
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profile conformance. A service frame is "green" if it is conformant
with "committed" rate of the bandwidth profile. A Service Frame is
"yellow" if it is exceeding the "committed" rate but conformant with
the "excess" rate of the bandwidth profile. Finally, a service frame
is "red" if it is conformant with neither the "committed" nor
"excess" rates of the bandwidth profile.
When a flow definition is used, the user can use a target-sites leaf-
list to identify the destination of a flow rather than using
destination addresses. A rule that does not have a match statement
is considered as a match-all rule. A service provider may implement
a default terminal classification rule if the customer does not
provide it. It will be up to the service provider to determine its
default target class.
5.10.2.2. QoS Profile
User can choose between standard profile provided by the operator or
a custom profile. The qos-profile defines the traffic scheduling
policy to be used by the service provider.
A custom qos-profile is defined as a list of class of services and
associated properties. The properties are:
o direction: Used to specify the direction which qos profile is
applied to. Our proposed model supports "Site-to-WAN" direction,
"WAN-to-Site"direction and "both" direction. By default, "both"
direction is used. In case of "both" direction, the provider
should ensure scheduling according to the requested policy in both
traffic directions (SP to customer and customer to SP). As an
example, a device-scheduling policy may be implemented on both the
PE side and the CE side of the WAN link. In case of "WAN-to-Site"
direction, the provider should ensure scheduling from the SP
network to the customer site. As an example, a device- scheduling
policy may be implemented only on the PE side of the WAN link
towards the customer.
o byte-offset: The optional "byte-offset" indicates how many bytes
in the service frame header are excluded from rate enforcement.
o rate-limit: Used to rate-limit the class of service. The value is
expressed as a percentage of the global service bandwidth. When
the qos-profile is implemented at CE side the svc-output-bandwidth
is taken into account as reference. When it is implemented at PE
side, the svc-input-bandwidth is used.
o frame-delay: Used to define the latency constraint of the class.
The latency constraint can be expressed as the lowest possible
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latency or a latency boundary expressed in milliseconds. How this
latency constraint will be fulfilled is up to the service provider
implementation: a strict priority queueing may be used on the
access and in the core network, and/or a low latency routing may
be created for this traffic class.
o frame-jitter: Used to define the jitter constraint of the class.
The jitter constraint can be expressed as the lowest possible
jitter or a jitter boundary expressed in microseconds. How this
jitter constraint will be fulfilled is up to the service provider
implementation: a strict priority queueing may be used on the
access and in the core network, and/or a jitter-aware routing may
be created for this traffic class.
o bandwidth: used to define a guaranteed amount of bandwidth for the
class of service. It is expressed as a percentage. The
"guaranteed-bw-percent" parameter uses available bandwidth as a
reference. The available bandwidth should not fall below
Committed Information Rate(CIR) defined under svc-input-bandwidth
or svc-output-bandwidth. When the qos-profile container is
implemented on the CE side, svc-output-bandwidth is taken into
account as a reference. When it is implemented on the PE side,
svc-input-bandwidth is used. By default, the bandwidth
reservation is only guaranteed at the access level. The user can
use the "end-to-end" leaf to request an end-to-end bandwidth
reservation, including across the MPLS transport network. (In
other words, the SP will activate something in the MPLS core to
ensure that the bandwidth request from the customer will be
fulfilled by the MPLS core as well.) How this is done (e.g., RSVP
reservation, controller reservation) is out of scope for this
document.
Some constraints may not be offered by an SP; in this case, a
deviation should be advertised. In addition, due to network
conditions, some constraints may not be completely fulfilled by the
SP; in this case, the SP should advise the customer about the
limitations. How this communication is done is out of scope for this
document.
5.10.3. Multicast
The "broadcast-unknowunicast-multicast" container defines the type of
site in the customer multicast service topology: source, receiver, or
both. These parameters will help the management system optimize the
multicast service.
Multiple multicast group to port mappings can be created using the
"multicast-gp-address-mapping" list. The "multicast-gp-address-
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mapping" defines multicast group address and port lag number. Those
parameters will help the SP select the appropriate association
between interface and multicast group to fulfill the customer service
requirement.
A whole Layer-2 multicast frame (whether for data or control) SHOULD
NOT be altered from a CE to CE(s) EXCEPT for the VLAN ID field,
ensuring that it is transparently transported. If VLAN IDs are
assigned by the SP, they can be altered.
For point-to-point services, the provider only needs to deliver a
single copy of each service frame to the remote PE, regardless
whether the destination MAC address of the incoming frame is unicast,
multicast or broadcast. Therefore, all service frames should be
delivered unconditionally.
B-U-M (Broadcast-UnknownUnicast-Multicast) frame forwarding in
multipoint-to-multipoint services, on the other hand, involves both
local flooding to other attachment circuits on the same PE and remote
replication to all other PEs, thus consumes additional resources and
core bandwidth. Special B-U-M frame disposition rules can be
implemented at external facing interfaces (UNI or E-NNI) to rate-
limit the B-U-M frames, in term of number of packets per second or
bits per second.
The threshold can apply to all B-U-M traffic, or one for each
category.
5.11. Site Management
The "management" sub-container is intended for site management
options, depending on the device ownership and security access
control. The followings are three common management models:
CE Provider Managed: The provider has the sole ownership of the CE
device. Only the provider has access to the CE. The
responsibility boundary between SP and customer is between CE and
customer network. This is the most common use case.
CE Customer Managed: The customer has the sole ownership of the CE
device. Only the customer has access to the CE. In this model,
the responsibility boundary between SP and customer is between PE
and CE.
CE Co-managed: The provider has ownership of the CE device and
responsible for managing the CE. However, the provider grants the
customer access to the CE for some configuration/monitoring
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purposes. In this co-managed mode, the responsibility boundary is
the same as for the provider-managed model.
The selected management mode is specified under the "type" leaf. The
"address" leaf stores CE device management IP information. And the
"management-transport" leaf is used to identify the transport
protocol for management traffic: IPv4 or IPv6. Additional security
options may be derived based on the particular management model
selected.
5.12. Security
5.12.1. MAC Loop Protection
MAC address flapping between different physical ports typically
indicates a bridge loop condition in the customer network.
Misleading entries in the MAC cache table can cause service frames to
circulate around the network indefinitely and saturate the links
throughout the provider's network, affecting other services in the
same network. In case of EVPN, it also introduces massive BGP
updates and control plane instability.
The service provider may opt to implement a switching loop prevention
mechanism at the external facing interfaces for multipoint-to-
multipoint services by imposing a MAC address move threshold.
The MAC move rate and prevention-type options are listed in the "mac-
loop-prevention" container.
5.12.2. MAC Address Limit
The service provider may choose to impose a per-attachment circuit
"mac-addr-limit" in addition to the service-level MAC limit, and
specify the behavior when the limit is exceeded accordingly.
5.13. Ethernet Service OAM
The advent of Ethernet as a wide-area network technology brings
additional requirements of end-to-end service monitoring and fault
management in the SP network, particularly in the area of service
availability and Mean Time To Repair (MTTR). Ethernet Service OAM in
the L2SM model refers to the combined protocol suites of IEEE 802.1ag
([IEEE-802-1ag]) and ITU-T Y.1731 ([ITU-T-Y-1731]).
Generally speaking, Ethernet Service OAM enables service providers to
perform service continuity check, fault-isolation, and packet delay/
jitter measurement at per customer per site network access
granularity. The information collected from Ethernet Service OAM
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data sets is complementary to other higher layer IP/MPLS OSS tools to
ensure the required service level agreements (SLAs) can be meet.
The 802.1ag Connectivity Fault Management (CFM) functional model is
structured with hierarchical maintenance domains (MDs), each assigned
with a unique maintenance level. Higher level MDs can be nested over
lower level MDs. However, the MDs cannot intersect. The scope of
each MD can be solely within a customer network, solely within the SP
network, interact between the customer-to-provider or provider-to-
provider edge equipment, or tunnel over another SP network.
Depending on the use case scenario, one or more maintenance end
points (MEPs) can be placed on the external facing interface, sending
CFM PDUs towards the core network (UP MEP) or downstream link (DOWN
MEP).
The "cfm-802.1-ag" sub-container under "site-network-access"
currently presents two types of CFM maintenance association (MA): UP
MEP for UNI-N to UNI-N Maintenance Association (MA) and DOWN MEP for
UNI-N to UNI-C MA. For each MA, the user can define the maintenance
domain ID (MAID), MEP level, MEP direction, remote MEP ID, CoS level
of the CFM PDUs, Continuity Check Message (CCM) interval and hold
time, alarm priority defect, CCM priority-type, etc.
ITU-T Y.1731 Performance Monitoring (PM) provides essential network
telemetry information that includes the measurement of Ethernet
service frame delay, frame delay variation, frame loss, and frame
throughput. The delay/jitter measurement can be either one-way or
two-way. Typically, a Y.1731 PM probe sends a small amount of
synthetic frames along with service frames to measure the SLA
parameters.
The "y-1731" sub-container under "site-network-access" contains a set
of parameters for use to define the PM probe information, including
MAID, local and remote MEP-ID, PM PDU type, message period and
measurement interval, CoS level of the PM PDUs, loss measurement by
synthetic or service frame options, one-way or two-way delay
measurement, PM frame size, and session type.
5.14. External ID References
The service model sometimes refers to external information through
identifiers. As an example, to order a cloud-access to a particular
cloud service provider (CSP), the model uses an identifier to refer
to the targeted CSP. If a customer is directly using this service
model as an API (through REST or NETCONF, for example) to order a
particular service, the SP should provide a list of authorized
identifiers. In the case of cloud-access, the SP will provide the
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associated identifiers for each available CSP. The same applies to
other identifiers, such as std-qos-profile.
How an SP provides the meanings of those identifiers to the customer
is out of scope for this document.
5.15. Defining NNIs and Inter-AS support
An autonomous system (AS) is a single network or group of networks
that is controlled by a common system administration group and that
uses a single, clearly defined routing protocol. In some cases, VPNs
need to span different ASes in different geographic areas or span
different SPs. The connection between ASes is established by the SPs
and is seamless to the customer. Examples include:
o A partnership between SPs (e.g., carrier, cloud) to extend their
VPN service seamlessly.
o An internal administrative boundary within a single SP (e.g.,
backhaul versus core versus data center).
NNIs (network-to-network interfaces) have to be defined to extend the
VPNs across multiple ASes. [RFC4761] defines multiple flavors of VPN
NNI implementations. Each implementation has pros and cons; this
topic is outside the scope of this document. For example, in an
Inter-AS option A, autonomous system border router (ASBR) peers are
connected by multiple interfaces with at least one of those
interfaces spanning the two ASes while being present in the same VPN.
In order for these ASBRs to signal label blocks, they associate each
interface with a Virtual Switching (VSI) instance and a Border
Gateway Protocol (BGP) session. As a result, traffic between the
back-to-back VPLS is Ethernet. In this scenario, the VPNs are
isolated from each other, and because the traffic is ethernet, QoS
mechanisms that operate on Ethernet traffic can be applied to achieve
customer service level agreements (SLAs).
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-------- -------------- -----------
/ \ / \ / \
| Cloud | | | | |
| Provider |-----NNI-----| |----NNI---| Data Center |
| #1 | | | | |
\ / | | \ /
-------- | | -----------
| |
-------- | My network | -----------
/ \ | | / \
| Cloud | | | | |
| Provider |-----NNI-----| |---NNI---| L2VPN |
| #2 | | | | Partner |
\ / | | | |
-------- | | | |
\ / | |
-------------- \ /
| -----------
|
NNI
|
|
-------------------
/ \
| |
| |
| |
| L2VPN Partner |
| |
\ /
-------------------
The figure above describes an SP network called "My network" that has
several NNIs. This network uses NNIs to:
o increase its footprint by relying on L2VPN partners.
o connect its own data center services to the customer L2VPN.
o enable the customer to access its private resources located in a
private cloud owned by some CSPs.
5.15.1. Defining an NNI with the Option A Flavor
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AS A AS B
------------------- -------------------
/ \ / \
| | | |
| ++++++++ Inter-AS link ++++++++ |
| + +_______________+ + |
| + (VSI1)---(VPN1)----(VSI1) + |
| + ASBR + + ASBR + |
| + (VSI2)---(VPN2)----(VSI2) + |
| + +_______________+ + |
| ++++++++ ++++++++ |
| | | |
| | | |
| | | |
| ++++++++ Inter-AS link ++++++++ |
| + +_______________+ + |
| + (VSI1)---(VPN1)----(VSI1) + |
| + ASBR + + ASBR + |
| + (VSI2)---(VPN2)----(VSI2) + |
| + +_______________+ + |
| ++++++++ ++++++++ |
| | | |
| | | |
\ / \ /
------------------- -------------------
In option A, the two ASes are connected to each other with physical
links on ASBRs. For resiliency purposes, there may be multiple
physical connections between the ASes. A VPN connection -- physical
or logical (on top of physical) -- is created for each VPN that needs
to cross the AS boundary, thus providing a back-to-back VPLS model.
From a service model's perspective, this VPN connection can be seen
as a site. Let's say that AS B wants to extend some VPN connections
for VPN C on AS A. The administrator of AS B can use this service
model to order a site on AS A. All connection scenarios could be
realized using the features of the current model. As an example, the
figure above shows two physical connections that have logical
connections per VPN overlaid on them. This could be seen as a
multiVPN scenario. Also, the administrator of AS B will be able to
choose the appropriate routing protocol (e.g., E-BGP) to dynamically
exchange routes between ASes.
This document assumes that the option A NNI flavor SHOULD reuse the
existing VPN site modeling.
Example: a customer wants its CSP A to attach its virtual network N
to an existing L2VPN (VPN1) that he has from L2VPN SP B.
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CSP A L2VPN SP B
----------------- -------------------
/ \ / \
| | | | |
| VM --| ++++++++ NNI ++++++++ |--- VPN1
| | + +_________+ + | Site#1
| |--------(VSI1)---(VPN1)--(VSI1)+ |
| | + ASBR + + ASBR + |
| | + +_________+ + |
| | ++++++++ ++++++++ |
| VM --| | | |--- VPN1
| |Virtual | | | Site#2
| |Network | | |
| VM --| | | |--- VPN1
| | | | | Site#3
\ / \ /
----------------- -------------------
|
|
VPN1
Site#4
To create the VPN connectivity, the CSP or the customer may use the
L2VPN service model that SP B exposes. We could consider that, as
the NNI is shared, the physical connection (bearer) between CSP A and
SP B already exists. CSP A may request through a service model the
creation of a new site with a single site-network-access (single-
homing is used in the figure). As a placement constraint, CSP A may
use the existing bearer reference it has from SP A to force the
placement of the VPN NNI on the existing link. The XML below
illustrates a possible configuration request to SP B:
CSP_A_attachment
NY
US
site-vpn-flavor-nni
bgp-l2vpn
12456487
kompella
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CSP_A_VN1
17
dot1q
opaque
450000000
20000000
1000000000
200000000
350000000
10000000
800000000
200000000
12456487
spoke-role
customer-managed
The case described above is different from a scenario using the
cloud-accesses container, as the cloud-access provides a public cloud
access while this example enables access to private resources located
in a CSP network.
5.15.2. Defining an NNI with the Option B Flavor
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AS A AS B
------------------- -------------------
/ \ / \
| | | |
| ++++++++ Inter-AS link ++++++++ |
| + +_______________+ + |
| + + + + |
| + ASBR +<---MP-BGP---->+ ASBR + |
| + + + + |
| + +_______________+ + |
| ++++++++ ++++++++ |
| | | |
| | | |
| | | |
| ++++++++ Inter-AS link ++++++++ |
| + +_______________+ + |
| + + + + |
| + ASBR +<---MP-BGP---->+ ASBR + |
| + + + + |
| + +_______________+ + |
| ++++++++ ++++++++ |
| | | |
| | | |
\ / \ /
------------------- -------------------
In option B, the two ASes are connected to each other with physical
links on ASBRs. For resiliency purposes, there may be multiple
physical connections between the ASes. The VPN "connection" between
ASes is done by exchanging VPN routes through MP-BGP [RFC4761].
There are multiple flavors of implementations of such an NNI. For
example:
1. The NNI is internal to the provider and is situated between a
backbone and a data center. There is enough trust between the
domains to not filter the VPN routes. So, all the VPN routes are
exchanged. RT filtering may be implemented to save some
unnecessary route states.
2. The NNI is used between providers that agreed to exchange VPN
routes for specific RTs only. Each provider is authorized to use
the RT values from the other provider.
3. The NNI is used between providers that agreed to exchange VPN
routes for specific RTs only. Each provider has its own RT
scheme. So, a customer spanning the two networks will have
different RTs in each network for a particular VPN.
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Case 1 does not require any service modeling, as the protocol enables
the dynamic exchange of necessary VPN routes.
Case 2 requires that an RT-filtering policy on ASBRs be maintained.
From a service modeling point of view, it is necessary to agree on
the list of RTs to authorize.
In Case 3, both ASes need to agree on the VPN RT to exchange, as well
as how to map a VPN RT from AS A to the corresponding RT in AS B (and
vice versa).
Those modelings are currently out of scope for this document.
CSP A L3VPN SP B
----------------- ------------------
/ \ / \
| | | | |
| VM --| ++++++++ NNI ++++++++ |--- VPN1
| | + +__________+ + | Site#1
| |-------+ + + + |
| | + ASBR +<-MP-BGP->+ ASBR + |
| | + +__________+ + |
| | ++++++++ ++++++++ |
| VM --| | | |--- VPN1
| |Virtual | | | Site#2
| |Network | | |
| VM --| | | |--- VPN1
| | | | | Site#3
\ / | |
----------------- | |
\ /
------------------
|
|
VPN1
Site#4
The example above describes an NNI connection between CSP A and SP
network B. Both SPs do not trust themselves and use a different RT
allocation policy. So, in terms of implementation, the customer VPN
has a different RT in each network (RT A in CSP A and RT B in SP
network B). In order to connect the customer virtual network in CSP
A to the customer IP VPN (VPN1) in SP network B, CSP A should request
that SP network B open the customer VPN on the NNI (accept the
appropriate RT). Who does the RT translation depends on the
agreement between the two SPs: SP B may permit CSP A to request VPN
(RT) translation.
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5.15.3. Defining an NNI with the Option C Flavor
AS A AS B
------------------- -------------------
/ \ / \
| | | |
| | | |
| | | |
| ++++++++ Multihop E-BGP ++++++++ |
| + + + + |
| + + + + |
| + RGW +<----MP-BGP---->+ RGW + |
| + + + + |
| + + + + |
| ++++++++ ++++++++ |
| | | |
| | | |
| | | |
| | | |
| | | |
| ++++++++ Inter-AS link ++++++++ |
| + +_______________+ + |
| + + + + |
| + ASBR + + ASBR + |
| + + + + |
| + +_______________+ + |
| ++++++++ ++++++++ |
| | | |
| | | |
| | | |
| ++++++++ Inter-AS link ++++++++ |
| + +_______________+ + |
| + + + + |
| + ASBR + + ASBR + |
| + + + + |
| + +_______________+ + |
| ++++++++ ++++++++ |
| | | |
| | | |
\ / \ /
------------------- -------------------
From a VPN service's perspective, the option C NNI is very similar to
option B, as an MP-BGP session is used to exchange VPN routes between
the ASes. The difference is that the forwarding plane and the
control plane are on different nodes, so the MP-BGP session is
multihop between routing gateway (RGW) nodes. From a VPN service's
point of view, modeling options B and C will be identical.
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5.16. Applicability of L2SM model in Inter-Provider and Inter-Domain
Orchestration
In the case where the ASes belong to different providers, one might
imagine that providers would like to have fewer signaling sessions
crossing the AS boundary and that the entities that terminate the
sessions could be restricted to a smaller set of devices. Two
approach can be taken:
(a) Inter-provider control connections to run only between the two
border routers
(b) Allow an end-to-end, multi-segment connectivity to be
constructed out of several connectivity segments, without
maintaining an end-to-end control connection.
Inter-provider control connection described in (a) can be realized
using techniques of section 5.15(i.e., defining NNI). Multi-segment
connectivity described in (b) can produce an inter-AS solution that
more closely resembles option (b) in [RFC4364]. It may be realized
using stitching of Per Site connectivity and OVC at different
segments, e.g., end to end connectivity between site_1 and Site 3
spans across multiple domains(i.e., Metro networks described in
section 5.2.5.) and can be constructed by stitching network access
connectivity within site_1 with OVC1, OVC3, OVC4 and network access
connectivity within site3 (See the following figure). The assumption
is service orchestration layer in figure 5 should have visibility of
the complete abstract topology and resource availability. This may
rely on network planning to achieve that. The XML below illustrates
a possible configuration request to SP:
12456487
Site1-UNI
Site2-UNI
Site3-UNI
Site4-UNI
ovc1
ovc2
ovc3
ovc4
ovc5
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ovc6
ovc7
1
TRUE
Metro-Network#1
ovc1
Metro-Network#2
ovc3
Metro-network#3
ovc4
2
TRUE
Metro-Network#1
ovc2
Metro-Network#2
ovc5
Metro-network#3
ovc6
Metro-network#4
ovc7
Note that OVC can also be regarded as network access connectivity
within a site and can be created as a normal site using L2SM service
model.
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---------- ---------- ----------
| | | | | |
+--+ +---+ +---+ +--+
Site_1|PE|==OVC1==| |==OVC3==| |==OVC4==|PE|Site_3
+--+ +---+ | | +--+
| | | | | | ----------
| | | | | | | |
+--+ +---+ | | +---+ +--+
Site_2|PE|==OVC2==| |==OVC5==| |==OVC6==| |==OVC7==|PE|Site_4
+--+ +---+ +---+ +---+ +--+
| | | | | | | |
---------- ---------- ---------- ----------
In this figure, we use EBGP redistribution of L2VPN NLRI from AS to
neighboring AS. First, the PE routers use Internal BGP (IBGP) to
redistribute L2VPN NLRI either to an ASBR, or to a route reflector of
which an ASBR is a client. The ASBR then uses EBGP to redistribute
those L2VPN NLRI to an ASBR in another AS, which in turn distributes
them to the PE routers in that AS, or perhaps to another ASBR which
in turn distributes them, and so on.
In this case, a PE can learn the address of an ASBR through which it
could reach another PE to which it wishes to establish a
connectivity. That is, a local PE will receive a BGP advertisement
containing L2VPN NLRI corresponding to an L2VPN instance in which the
local PE has some attached members. The BGP next-hop for that L2VPN
NLRI will be an ASBR of the local AS. Then, rather than building a
control connection all the way to the remote PE, it builds one only
to the ASBR. A connectivity segment can now be established from the
PE to the ASBR. The ASBR in turn can establish a connectivity to the
ASBR of the next AS, and stitching that connectivity to the
connectivity from the PE as described in Section 3.5.4 and [RFC6073].
Repeating the process at each ASBR leads to a sequence of
connectivity segments that, when stitching together, connect the two
PEs.
Note that in the approach just described, the local PE may never
learn the IP address of the remote PE. It learns the L2VPN NLRI
advertised by the remote PE, which need not contain the remote PE
address, and it learns the IP address of the ASBR that is the BGP
next hop for that NLRI.
When this approach is used for VPLS, or for full-mesh VPWS, it leads
to a full mesh of connectivity among the PEs, but it does not require
a full mesh of control connections (LDP or L2TPv3 sessions).
Instead, the control connections within a single AS run among all the
PEs of that AS and the ASBRs of the AS. A single control connection
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between the ASBRs of adjacent ASes can be used to support however
many AS-to-AS connectivity segments are needed.
6. Interaction with Other YANG Modules
As expressed in Section 4, this service module is not intended to
configure the network element, but is instantiated in a management
system.
The management system might follow modular design and comprise at
least two different components:
a. The component instantiating the service model (let's call it the
service component)
b. The component responsible for network element configuration
(let's call it the configuration component)
In some cases, when a split is needed between the behavior and
functions that a customer requests and the technology that the
network operator has available to deliver the service
[I-D.ietf-opsawg-service-model-explained], a new component can be
separated out of the service component (let's call it the control
component). This component is responsible for network-centric
operation and is aware of many features such as topology, technology,
and operator policy. As an optional component, it can use the
service model as input and is not required at all if the control
component delegates its control operations to the configuration
component.
In Section 7 we provide some example of translation of service
provisioning requests to router configuration lines as an
illustration. In the NETCONF/YANG ecosystem, it is expected that
NETCONF and YANG will be used between the configuration component and
network elements to configure the requested service on those
elements.
In this framework, it is expected that YANG models will be used for
configuring service components on network elements. There will be a
strong relationship between the abstracted view provided by this
service model and the detailed configuration view that will be
provided by specific configuration models for network elements such
as those defined in [I-D.ietf-bess-l2vpn-yang] and
[I-D.ietf-bess-evpn-yang]. Service components needing configuration
on network elements in support of the service model defined in this
document include:
o Network Instance definition including VPN policy expression.
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o Physical interface.
o Ethernet layer (VLAN ID).
o QoS: classification, profiles, etc.
o Signaling Options: support of configuration of all protocols
listed in the document, as well as vpn policies associated with
these protocols.
o Ethernet Service OAM Support.
7. Service Model Usage Example
As explained in Section 4, this service model is intended to be
instantiated at a management layer and is not intended to be used
directly on network elements. The management system serves as a
central point of configuration of the overall service.
This section provides an example on how a management system can use
this model to configure an L2VPN service on network elements.
The example is for of a VPN service for 3 sites using point-to-point
EVC and a Hub and Spoke VPN service topology as shown in Figure 7.
Loadbalancing is not considered in this case.
UNI Site1
............
: : E-Line using P2P EVC
:Spoke Site:-----PE1--------------------------+
: : | UNI Site3
:..........: | ............
| : :
PE3-----: Hub Site :
UNI Site2 | : :
............ | :..........:
: : E-Line using P2P EVC |
:Spoke Site:-----PE2--------------------------+
: :
:..........:
Figure 7: Reference Network for Simple Example
The following XML describes the overall simplified service
configuration of this VPN.
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12456487
evpl
UNI1
UNI3
hub-spoke
12456488
evpl
UNI2
UNI3
hub-spoke
When receiving the request for provisioning the VPN service, the
management system will internally (or through communication with
another OSS component) allocates VPN route-targets. In this specific
case two Route Targets (RTs) will be allocated (100:1 for Hubs and
100:2 for Spokes). The output below describes the configuration of
Spoke UNI Site1.
Spoke_Site1
NY
US
bgp-l2vpn
12456487
kompella
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Spoke_UNI-Site1
20
17
dot1q
opaque
450000000
20000000
1000000000
200000000
350000000
10000000
800000000
200000000
TUNNEL
TRUE
12456487
spoke-role
provider-managed
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When receiving the request for provisioning Spoke1 site, the
management system MUST allocate network resources for this site. It
MUST first determine the target network elements to provision the
access, and especially the PE router (and may be an aggregation
switch). As described in Section 5.3.1, the management system SHOULD
use the location information and SHOULD use the access-diversity
constraint to find the appropriate PE. In this case, we consider
Spoke1 requires PE diversity with Hub and that management system
allocate PEs based on lowest distance. Based on the location
information, the management system finds the available PEs in the
nearest area of the customer and picks one that fits the access-
diversity constraint.
When the PE is chosen, the management system needs to allocate
interface resources on the node. One interface is selected from the
PE available pool. The management system can start provisioning the
PE node by using any mean (Netconf, CLI, ...). The management system
will check if a VFI is already present that fits the needs. If not,
it will provision the VFI: Route Distinguisher will come from
internal allocation policy model, route-targets are coming from the
vpn-policy configuration of the site (management system allocated
some RTs for the VPN). As the site is a Spoke site (site-role), the
management system knows which RT must be imported and exported. As
the site is provider managed, some management route-targets may also
be added (100:5000). Standard provider VPN policies MAY also be
added in the configuration.
Example of generated PE configuration:
l2vpn vfi context one
vpn id 12456487
autodiscovery bgp signaling bgp
ve id 1001 <----identify the PE routers within the VPLS domain
ve range 50 <---- VE size
route-distinguisher 100:3123234324
route-target import 100:1
route-target import 100:5000 <---- Standard SP configuration
route-target export 100:2 for provider managed CE
!
When the VFI has been provisioned, the management system can start
configuring the access on the PE using the allocated interface
information. The tag or VLAN (e.g., service instance tag)is chosen
by the management system. One tag will be picked from an allocated
subnet for the PE, another will be used for the CE configuration.
LACP protocols will also be configured between PE and CE and due to
provider managed model, the choice is up to service provider. This
choice is independent of the LACP protocol chosen by customer.
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Example of generated PE configuration:
!
bridge-domain 1
member Ethernet0/0 service-instance 100
member vfi one
!
l2 router-id 10.100.1.1
!
interface Ethernet0/0
no ip address
service instance 100 ethernet
encapsulation dot1q 100
!
!
router bgp 1
bgp log-neighbor-changes
neighbor 10.100.1.4 remote-as 1
neighbor 10.100.1.4 update-source Loopback0
!
address-family l2vpn vpls
neighbor 10.100.1.4 activate
neighbor 10.100.1.4 send-community extended
neighbor 10.100.1.4 suppress-signaling-protocol ldp
exit-address-family
!
interface vlan 100 <-- Associating the Attachment
no ip address Circuit with the VSI at the PE
xconnect vfi PE1-VPLS-A
!
vlan 100
state active
As the CE router is not reachable at this stage, the management
system can produce a complete CE configuration that can be uploaded
to the node by manual operation before sending the CE to customer
premise. The CE configuration will be built as for the PE. Based on
the CE type (vendor/model) allocated to the customer and bearer
information, the management system knows which interface must be
configured on the CE. PE-CE link configuration is expected to be
handled automatically using the service provider OSS as both
resources are managed internally. CE to LAN interface parameters
like dot1Q tag are derived from the ethernet-connection taking into
account how management system distributes dot1Q tag between PE and CE
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within subnet. This will allow to produce a plug'n'play
configuration for the CE.
Example of generated CE configuration:
interface Ethernet0/1
switchport trunk allowed vlan none
switchport mode trunk
service instance 100 ethernet
encapsulation default
l2protocol forward cdp
xconnect 1.1.1.1 100 encapsulation mpls
!
8. YANG Module
file "ietf-l2vpn-svc@2017-08-25.yang"
module ietf-l2vpn-svc {
yang-version 1.1;
namespace "urn:ietf:params:xml:ns:yang:ietf-l2vpn-svc";
prefix l2vpn-svc;
import ietf-inet-types {
prefix inet;
}
import ietf-yang-types {
prefix yang;
}
import iana-if-type {
prefix ianaift;
}
organization
"IETF L2SM Working Group.";
contact
"WG List: l2sm@ietf.org
Editor: giuseppe.fioccola@telecomitalia.it";
description
"The YANG module defines a generic service configuration
model for Layer 2 VPN services common across all of the
vendor implementations.";
revision 2017-08-25{
description
"Initial revision -03 version";
reference
"draft-ietf-l2sm-l2vpn-service-model-03.txt
A YANG Data Model for L2VPN Service Delivery.";
}
/* Features */
feature multicast{
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description
"Enables multicast capabilities in a VPN.";
}
feature extranet-vpn{
description
"Enable the Support of Extranet VPN.";
}
feature L2CP-control {
description
"Enable the Support of L2CP control.";
}
feature input-bw {
description
"Enable the suppport of Input Bandwidth in a VPN.";
}
feature output-bw {
description
"Enable the support of Output Bandwidth in a VPN";
}
feature uni-list {
description
"Enable the support of UNI list in a VPN.";
}
feature evc {
description
"Enable the support of EVC in a VPN.";
}
feature ovc {
description
"Enable the support of OVC in a VPN.";
}
feature cloud-access {
description
"Allow VPN to connect to a Cloud Service
provider.";
}
feature oam-3ah {
description
"Enables the support of OAM 802.3ah.";
}
feature micro-bfd {
description
"Enables the support of Micro-BFD.";
}
feature bfd {
description
"Enables the support of BFD.";
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}
feature signaling-options {
description
"Enable the support of signaling option.";
}
feature site-diversity {
description
"Enables the support of site diversity constraints in a VPN.";
}
feature encryption {
description
"Enables support of encryption.";
}
feature always-on {
description
"Enables support for always-on access
constraint.";
}
feature requested-type {
description
"Enables support for requested-type access
constraint.";
}
feature bearer-reference {
description
"Enables support for bearer-reference access
constraint.";
}
feature qos {
description
"Enables support of Class of Services.";
}
feature qos-custom {
description
"Enables support of custom qos profile.";
}
feature lag-interface{
description
"Enable lag-interface.";
}
feature vlan {
description
"Enable the support of VLAN.";
}
feature dot1q{
description
"Enable the support of Dot1Q.";
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}
feature qinq {
description
"Enable the support of QinQ.";
}
feature qinany{
description
"Enable the support of QinAny.";
}
feature vxlan {
description
"Enable the support of VxLAN.";
}
feature ipv4 {
description
"Enables IPv4 support in a VPN.";
}
feature ipv6 {
description
"Enables IPv6 support in a VPN.";
}
feature lan-tag {
description
"Enables LAN Tag support in a VPN.";
}
/* Typedefs */
typedef svc-id {
type string;
description
"Defines a type of service component identifier.";
}
typedef ccm-priority-type {
type uint8 {
range "0..7";
}
description
"A 3 bit priority value to be used in the VLAN tag,
if present in the transmitted frame.";
}
typedef control-mode {
type enumeration {
enum peer {
description
"Peer mode";
}
enum tunnel {
description
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"Tunnel mode";
}
enum discard {
description
"Discard mode";
}
}
description
"Defining a type of the control mode on L2CP protocols.";
}
typedef neg-mode {
type enumeration {
enum full-duplex {
description
"Defining Full duplex mode";
}
enum auto-neg {
description
"Defining Auto negotiation mode";
}
}
description
"Defining a type of the negotiation mode";
}
/* Identities */
identity multicast-tree-type {
description
"Base identity for multicast tree type.";
}
identity ssm-tree-type {
base multicast-tree-type;
description
"Identity for SSM tree type.";
}
identity asm-tree-type {
base multicast-tree-type;
description
"Identity for ASM tree type.";
}
identity bidir-tree-type {
base multicast-tree-type;
description
"Identity for bidirectional tree type.";
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}
identity mapping-type{
description
"Identity mapping-type";
}
identity static-mapping{
base mapping-type;
description
"Identity for static mapping, i.e.,attach the interface
to the Multicast group as static member";
}
identity dynamic-mapping{
base mapping-type;
description
"Identity for dynamic mapping, i.e.,interface was added
to the Multicast group as a result of snooping";
}
identity tf-type{
description
"Identity traffic-type";
}
identity multicast-traffic {
base tf-type;
description
"Identity for multicast traffic";
}
identity broadcast-traffic {
base tf-type;
description
"Identity for broadcast traffic";
}
identity unknown-unicast-traffic {
base tf-type;
description
"Identity for unknown unicast traffic";
}
identity pwe-encapsulation-type{
description
"Identity pwe-encapsulation-type";
}
identity ethernet-over-mpls {
base pwe-encapsulation-type;
description
"Identity for ethernet over mpls";
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}
identity ethernet-tagged-mpls {
base pwe-encapsulation-type;
description
"Identity for ethernet tagged over mpls";
}
identity l2tp-pw-type {
description
"Identity for L2TP PW type";
}
identity encapsulation-type {
description
"Identity for encapsulation type";
}
identity ethernet-type {
base encapsulation-type;
description
"Identity for encapsulation type";
}
identity vlan-type {
base encapsulation-type;
description
"Identity for encapsulation type";
}
identity protection-mode {
description
"Identity of protection mode";
}
identity oneplusone{
base protection-mode;
description
"In this scheme, the primary circuitEVC or OVC will be
protected by a backup circuitEVC or OVC, typically meeting certain
diverse path/fiber/site/node criteria. Both primary and
protection circuits are provisioned to be in the active forwarding
state. The subscriber may choose to send the same service frames
across both circuits simultaneously.";
}
identity one2one{
base protection-mode;
description
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"In this scheme, a backup circuit to the primary
circuit is provisioned. Depending on the implementation
agreement, the protection circuits may either always be in active
forwarding state, or may only become active when a faulty state is
detected on the primary circuit.";
}
identity eth-inf-type {
description
"Identity of Ethernet Interface Type";
}
identity phy-inf {
base eth-inf-type;
description
"Identity of Physical Interface type";
}
identity lag-inf {
base eth-inf-type;
description
"Identity of LAG Interface type";
}
identity bw-type {
description
"Identity of bandwidth";
}
identity bw-per-cos {
base bw-type;
description
"Bandwidth is per cos";
}
identity bw-per-evc-ovc {
base bw-type;
description
"Bandwidth is per evc or per ovc";
}
identity bw-per-port {
base bw-type;
description
"Bandwidth is per site network access";
}
identity opaque {
base bw-type;
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description
"Opaque";
}
identity site-type {
description
"Identity of site type.";
}
identity uni {
base site-type;
description
"Identity of User Network Interface ";
}
identity enni {
base site-type;
description
"Identity of External Network to Network Interface";
}
identity service-type {
description
"Identity of service type.";
}
identity vpws {
base service-type;
description
" point-to-point Virtual Private Wire Services(VPWS) type.";
}
identity pwe3 {
base service-type;
description
" Pseudo-Wire Emulation Edge to
Edge(PWE3)Service type. .";
}
identity evpn {
base service-type;
description
"Ethernet VPN Service Type,
Ethernet VPNs are specified in RFC 7432";
}
identity vpls-ldp {
base service-type;
description
"LDP based multipoint Virtual Private LAN services (VPLS) Service Type.
This VPLS uses LDP-signaled Pseudowires";
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}
identity vpls-bgp {
base service-type;
description
"BGP based multipoint Virtual Private LAN services (VPLS) Service Type.
This VPLS uses a Border Gateway Protocol (BGP) control plane as
described in RFC4761 and RFC6624. ";
}
identity epl {
base service-type;
description
"Ethernet Private Line (EPL) Service Type. ";
}
identity evpl {
base service-type;
description
"Ethernet Virtual Private Line (EVPL) Service Type. ";
}
identity ep-lan {
base service-type;
description
" Ethernet Private LAN (EP-LAN)Service Type. ";
}
identity evp-lan {
base service-type;
description
" Ethernet Virtual Private LAN (EVP-LAN)Service Type. ";
}
identity bundling-type {
description
"Bundling type.";
}
identity bundling {
base bundling-type;
description
"Identity for bundling";
}
identity all2one-Bundling {
base bundling-type;
description
"Identity for all to one bundling";
}
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identity color-id {
description
"Identity of color id";
}
identity color-id-evc {
base color-id;
description
"Identity of color id base on EVC";
}
identity color-id-evc-cvlan {
base color-id;
description
"Identity of color id base on EVC and CVLAN ";
}
identity cos-id {
description
"Identity of class of service id";
}
identity cos-id-evc {
base cos-id;
description
"Identity of cos id based on EVC";
}
identity cos-id-evc-pcp {
base cos-id;
description
"Identity of cos id based on EVC and PCP";
}
identity cos-id-evc-dscp {
base cos-id;
description
"Identity of cos id based on EVC and DSCP";
}
identity cos-id-ovc-ep {
base cos-id;
description
"Identity of cos id based on OVC EP";
}
identity color-type {
description
"Identity of color types";
}
identity green {
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base color-type;
description
"Identity of green type";
}
identity yellow {
base color-type;
description
"Identity of yellow type";
}
identity red {
base color-type;
description
"Identity of red type";
}
identity perf-tier-opt {
description
"Identity of performance tier option.";
}
identity metro {
base perf-tier-opt;
description
"Identity of metro";
}
identity regional {
base perf-tier-opt;
description
"Identity of regional";
}
identity continental {
base perf-tier-opt;
description
"Identity of continental";
}
identity global {
base perf-tier-opt;
description
"Identity of global";
}
identity policing {
description
"Identity of policing type";
}
identity one-rate-two-color {
base policing;
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description
"Identity of one-rate, two-color (1R2C)";
}
identity two-rate-three-color {
base policing;
description
"Identity of two-rate, three-color (2R3C)";
}
identity bum-type {
description
"Identity of BUM type";
}
identity broadcast {
base bum-type;
description
"Identity of broadcast";
}
identity unicast {
base bum-type;
description
"Identity of unicast";
}
identity multicast {
base bum-type;
description
"Identity of multicast";
}
identity loop-prevention-type{
description
"Identity of loop prevention";
}
identity shut {
base loop-prevention-type;
description
"Identity of shut protection";
}
identity trap {
base loop-prevention-type;
description
"Identity of trap protection";
}
identity lacp-state {
description
"Identity of LACP state";
}
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identity lacp-on {
base lacp-state;
description
"Identity of LCAP on";
}
identity lacp-off {
base lacp-state;
description
"Identity of LACP off";
}
identity lacp-mode {
description
"Identity of LACP mode";
}
identity lacp-passive {
base lacp-mode;
description
"Identity of LACP passive";
}
identity lacp-active {
base lacp-mode;
description
"Identity of LACP active";
}
identity lacp-speed {
description
"Identity of LACP speed";
}
identity lacp-fast {
base lacp-speed;
description
"Identity of LACP fast";
}
identity lacp-slow {
base lacp-speed;
description
"Identity of LACP slow";
}
identity vpn-signaling-type {
description
"Identity of VPN signaling types";
}
identity bgp-l2vpn {
base vpn-signaling-type;
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description
"Identity of bgp-l2vpn";
}
identity mp-bgp-evpn {
base vpn-signaling-type;
description
"Identity of mp-bgp-evpn";
}
identity t-ldp-pwe3{
base vpn-signaling-type;
description
"Identity of t-ldp-pwe.";
}
identity l2tp-pw {
base vpn-signaling-type;
description
"Identity of l2tp-pw.";
}
identity t-ldp-pwe-type{
description
"Identity for t-ldp-pwe-type.";
}
identity vpws-type {
base t-ldp-pwe-type;
description
"Identity for VPWS";
}
identity vpls-type{
base t-ldp-pwe-type;
description
"Identity for vpls";
}
identity h-vpls{
base t-ldp-pwe-type;
description
"Identity for h-vpls";
}
identity l2vpn-type {
description
"Layer 2 VPN types";
}
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identity kompella {
base l2vpn-type;
description
"Use BGP as signaling protocol.";
}
identity martini {
base l2vpn-type;
description
"Use LDP as signaling protocol";
}
identity both {
base l2vpn-type;
description
"LDP based Signaling and BGP based Auto Discovery";
}
identity evpn-type {
description
"Ethernet VPN types";
}
identity pbb {
base evpn-type;
description
" Provider Backbone Bridging-EVPN";
}
identity management {
description
"Base identity for site management scheme.";
}
identity co-managed {
base management;
description
"Base identity for co-managed site.";
}
identity customer-managed {
base management;
description
"Base identity for customer managed site.";
}
identity provider-managed {
base management;
description
"Base identity for provider managed site.";
}
identity address-family {
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description
"Base identity for an address family.";
}
identity ipv4 {
base address-family;
description
"Identity for IPv4 address family.";
}
identity ipv6 {
base address-family;
description
"Identity for IPv6 address family.";
}
identity vpn-topology {
description
"Base identity for VPN topology.";
}
identity any-to-any {
base vpn-topology;
description
"Identity for any to any VPN topology.";
}
identity hub-spoke {
base vpn-topology;
description
"Identity for Hub'n'Spoke VPN topology.";
}
identity hub-spoke-disjoint {
base vpn-topology;
description
"Identity for Hub'n'Spoke VPN topology
where Hubs cannot talk between each other.";
}
identity site-role {
description
"Base identity for site type.";
}
identity any-to-any-role {
base site-role;
description
"Site in an any to any IPVPN.";
}
identity spoke-role {
base site-role;
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description
"Spoke Site in a Hub & Spoke IPVPN.";
}
identity hub-role {
base site-role;
description
"Hub Site in a Hub & Spoke IPVPN.";
}
identity pm-type {
description
"Performance monitor type";
}
identity loss {
base pm-type;
description
"Loss measurement";
}
identity delay {
base pm-type;
description
"Delay measurement";
}
identity fault-alarm-defect-type {
description
"Indicating the alarm priority defect";
}
identity remote-rdi {
base fault-alarm-defect-type;
description
"Indicates the aggregate health of the remote MEPs.";
}
identity remote-mac-error {
base fault-alarm-defect-type;
description
"Indicates that one or more of the remote MEPs is
reporting a failure in its Port Status TLV or
Interface Status TLV.";
}
identity remote-invalid-ccm {
base fault-alarm-defect-type;
description
"Indicates that at least one of the Remote MEP
state machines is not receiving valid CCMs
from its remote MEP.";
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}
identity invalid-ccm {
base fault-alarm-defect-type;
description
"Indicates that one or more invalid CCMs has been
received and that 3.5 times that CCMs transmission
interval has not yet expired.";
}
identity cross-connect-ccm {
base fault-alarm-defect-type;
description
"Indicates that one or more cross connect CCMs has been
received and that 3.5 times of at least one of those
CCMs transmission interval has not yet expired.";
}
identity data-svc-frame-delivery {
description
"Delivery types";
}
identity discard {
base data-svc-frame-delivery;
description
"Service Frames are discarded.";
}
identity unconditional {
base data-svc-frame-delivery;
description
"Service Frames are unconditionally";
}
identity conditional {
base data-svc-frame-delivery;
description
"Service Frame are conditionally
delivered to the destination UNI.";
}
identity evc-type {
description
"Service topology Type";
}
identity point-to-point {
base evc-type;
description
"Point to Point.";
}
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identity multipoint-to-multipoint {
base evc-type;
description
"Multipoint to Multipoint.";
}
identity rooted-multipoint {
base evc-type;
description
"Rooted Multipoint.";
}
identity placement-diversity {
description
"Base identity for site placement
constraints";
}
identity bearer-diverse {
base placement-diversity;
description
"Identity for bearer diversity.
The bearers should not use common elements.";
}
identity pe-diverse {
base placement-diversity;
description
"Identity for PE diversity";
}
identity pop-diverse {
base placement-diversity;
description
"Identity for POP diversity";
}
identity linecard-diverse {
base placement-diversity;
description
"Identity for linecard diversity";
}
identity same-pe {
base placement-diversity;
description
"Identity for having sites connected
on the same PE";
}
identity same-bearer {
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base placement-diversity;
description
"Identity for having sites connected
using the same bearer";
}
identity l2-access-type {
description
"This identify the access type
of the vpn acccess interface";
}
identity untag {
base l2-access-type;
description
"Untag";
}
identity port {
base l2-access-type;
description
"Port";
}
identity dot1q {
base l2-access-type;
description
"Qot1q";
}
identity qinq {
base l2-access-type;
description
"QinQ";
}
identity sub-interface {
base l2-access-type;
description
"Create a default sub-interface and keep vlan";
}
identity vxlan {
base l2-access-type;
description
"Vxlan access into the vpn";
}
identity mac-learning-mode {
description
"MAC learning mode";
}
identity data-plane {
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base mac-learning-mode;
description
"User MAC addresses are learned through ARP broadcast.";
}
identity control-plane {
base mac-learning-mode;
description
"User MAC addresses are advertised through EVPN-BGP";
}
identity vpn-policy-filter-type {
description
"Base identity for filter type.";
}
identity lan {
base vpn-policy-filter-type;
description
"Identity for lan tag filter type.";
}
identity mac-action {
description
"Base identity for MAC action.";
}
identity drop {
base mac-action;
description
"Identity for packet drop.";
}
identity flood {
base mac-action;
description
"Identity for packet flooding.";
}
identity warning {
base mac-action;
description
"Identity for sending a warning log message.";
}
identity load-balance-method {
description
"Base identity for load balance method.";
}
identity fat-pw {
base load-balance-method;
description
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"Identity for Fat PW. Fat label is
applied to Pseudowires across MPLS
network.";
}
identity entropy-label {
base load-balance-method;
description
"Identity for entropy label.Entropy label
is applied to IP forwarding,
L2VPN or L3VPN across MPLS network";
}
identity vxlan-source-port {
base load-balance-method;
description
"Identity for vxlan source port.VxLAN
Source Port is one load balancing method.";
}
identity qos-profile-direction {
description
"Base identity for qos profile direction.";
}
identity site-to-wan {
base qos-profile-direction;
description
"Identity for Site to WAN direction.";
}
identity wan-to-site {
base qos-profile-direction;
description
"Identity for WAN to Site direction.";
}
identity bidirection {
base qos-profile-direction;
description
"Identity for both WAN to Site direction and Site to WAN direction.";
}
identity vxlan-peer-mode {
description
"Base identity for vxlan peer mode.";
}
identity static-mode {
base vxlan-peer-mode;
description
"Identity for the vxlan access in static mode.";
}
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identity bgp-mode {
base vxlan-peer-mode;
description
"Identity for the vxlan access by bgp evpn learning.";
}
/* Groupings */
grouping vpn-service-cloud-access {
container cloud-accesses {
if-feature cloud-access;
list cloud-access {
key cloud-identifier;
leaf cloud-identifier {
type string;
description
"Identification of cloud service. Local
admin meaning.";
}
choice list-flavor {
case permit-any {
leaf permit-any {
type empty;
description
"Allow all sites.";
}
}
case deny-any-except {
leaf-list permit-site {
type leafref {
path "/l2vpn-svc/sites/site/site-id";
}
description
"Site ID to be authorized.";
}
}
case permit-any-except {
leaf-list deny-site {
type leafref {
path "/l2vpn-svc/sites/site/site-id";
}
description
"Site ID to be denied.";
}
}
description
"Choice for cloud access policy.";
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}
container authorized-sites {
list authorized-site {
key site-id;
leaf site-id {
type leafref {
path "/l2vpn-svc/sites/site/site-id";
}
description
"Site ID.";
}
description
"List of authorized sites.";
}
description
"Configuration of authorized sites.";
}
container denied-sites {
list denied-site {
key site-id;
leaf site-id {
type leafref {
path "/l2vpn-svc/sites/site/site-id";
}
description
"Site ID.";
}
description
"List of denied sites.";
}
description
"Configuration of denied sites.";
}
description
"Cloud access configuration.";
}
description
"Container for cloud access configurations";
}
description
"Grouping for vpn cloud definition";
}
grouping site-device {
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container device {
list devices {
key "device-id";
leaf device-id {
type string;
description
"Device ID";
}
leaf location {
type leafref {
path "/l2vpn-svc/sites/site/locations/location/location-id";
}
description
"Site name";
}
container management {
leaf address {
type inet:ip-address;
description
"Address";
}
leaf management-transport {
type identityref {
base address-family;
}
description
"Transport protocol used for management.";
}
description
"Container for management";
}
description
"List of devices";
}
description
"Devices configuration";
}
description
"Device parameters for the site.";
}
grouping site-management {
container management {
leaf type {
type identityref {
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base management;
}
description
"Management type of the connection.";
}
description
"Container for management";
}
description
"Grouping for management";
}
grouping site-vpn-policy {
container vpn-policies {
list vpn-policy {
key vpn-policy-id;
leaf vpn-policy-id {
type string;
description
"Unique identifier for the VPN policy.";
}
list entries {
key id;
leaf id {
type string;
description
"Unique identifier for the policy entry.";
}
container filters {
list filter {
key type;
ordered-by user;
leaf type {
type identityref {
base vpn-policy-filter-type;
}
description
"Type of VPN Policy filter.";
}
leaf-list lan-tag {
when "derived-from-or-self(../type, 'l2vpn-svc:lan')" {
description
"Only applies when VPN Policy filter is LAN Tag filter.";
}
if-feature lan-tag;
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type uint32;
description
"List of Ethernet LAN Tag to be matched. Ethernet LAN Tag
identifies a particular broadcast domain in a VPN. ";
}
leaf-list ipv4-lan-prefix {
when "derived-from-or-self(../type, 'l2vpn-svc:ipv4')" {
description
"Only applies when VPN Policy filter is IPv4 Prefix filter.";
}
if-feature ipv4;
type inet:ipv4-prefix;
description
"List of IPv4 prefixes as LAN Prefixes to be matched.";
}
leaf-list ipv6-lan-prefix {
when "derived-from-or-self(../type, 'l2vpn-svc:ipv6')" {
description
"Only applies when VPN Policy filter is IPv6 Prefix filter.";
}
if-feature ipv6;
type inet:ipv6-prefix;
description
"List of IPv6 prefixes as LAN prefixes to be matched.";
}
description
"List of filters used on the site. This list can
be augmented.";
}
description
"If a more-granular VPN attachment is necessary, filtering can
be used. If used, it permits the splitting of site LANs among
multiple VPNs.The Site LAN can be split based on either LAN-tag
or LAN prefix. If no filter is used, all the LANs will be
part of the same VPNs with the same role.";
}
list vpn {
key vpn-id;
leaf vpn-id {
type leafref {
path "/l2vpn-svc/vpn-services/"+
"vpn-svc/vpn-id";
}
mandatory true;
description
"Reference to an IP VPN.";
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}
leaf site-role {
type identityref {
base site-role;
}
default any-to-any-role;
description
"Role of the site in the IP VPN.";
}
description
"List of VPNs the LAN is associated with.";
}
description
"List of entries for export policy.";
}
description
"List of VPN policies.";
}
description
"VPN policy.";
}
description
"VPN policy parameters for the site.";
}
grouping umb-frame-delivery {
leaf unicast-frame-delivery {
type identityref {
base data-svc-frame-delivery;
}
description
"Unicast Data Service Frame Delivery Mode
(unconditional[default], conditional, or discard).";
}
leaf multicast-frame-delivery {
type identityref {
base data-svc-frame-delivery;
}
description
"Multicast Data Service Frame Delivery Mode
(unconditional[default], conditional, or discard).";
}
leaf broadcast-frame-delivery {
type identityref {
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base data-svc-frame-delivery;
}
description
"Broadcast Data Service Frame Delivery Mode
(unconditional[default], conditional, or discard).";
}
description
"Grouping for unicast, mulitcast, broadcast frame delivery";
}
grouping customer-location-info {
container locations {
list location {
key location-id;
leaf location-id{
type string;
description
"Location ID";
}
leaf address {
type string;
description
"Address (number and street) of the site.";
}
leaf zip-code {
type string;
description
"ZIP code of the site.";
}
leaf state {
type string;
description
"State of the site. This leaf can also be used to
describe a region for country who does not have
states.";
}
leaf city {
type string;
description
"City of the site.";
}
leaf country-code {
type string;
description
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"Country of the site.";
}
description
"List for location";
}
description
"Location of the site.";
}
description
"This grouping defines customer location parameters";
}
grouping site-diversity {
container site-diversity {
if-feature site-diversity;
container groups {
list group {
key group-id;
leaf group-id {
type string;
description
"Group-id the site is belonging to";
}
description
"List of group-id";
}
description
"Groups the site is belonging to.
All site network accesses will inherit those group
values.";
}
description
"Diversity constraint type.";
}
description
"This grouping defines site diversity parameters";
}
grouping site-service {
list cvlan-id-to-svc-map {
key "svc-id type";
leaf svc-id {
type leafref {
path "/l2vpn-svc/vpn-services/vpn-svc/vpn-id";
}
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description
"VPN Service identifier";
}
leaf type {
type identityref {
base bundling-type;
}
description
"Bundling type";
}
list cvlan-id {
key vid;
leaf vid {
type identityref {
base ianaift:iana-interface-type;
}
description
"CVLAN ID";
}
description
"List of CVLAN-ID to EVC Map configurations";
}
description
"List for cvlan-id to evc map configurations";
}
description
"This grouping defines site service parameters";
}
grouping service-protection {
container service-protection {
leaf protection-mode {
type identityref {
base protection-mode;
}
description
"Container of protection mode configurations";
}
description
"Container of End-to-end Service Protection
configurations";
}
description
"Grouping for service protection";
}
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grouping vpn-service-multicast {
container multicast {
if-feature multicast;
leaf enabled {
type boolean;
default false;
description
"Enables multicast.";
}
container customer-tree-flavors {
leaf-list tree-flavor {
type identityref {
base multicast-tree-type;
}
description
"Type of tree to be used.";
}
description
"Type of trees used by customer.";
}
leaf traffic-type {
type identityref {
base tf-type;
}
description
"Traffic Type";
}
leaf group-port-mapping {
type identityref {
base mapping-type;
}
description
"Describe the way in which each interface is associated with the Multicast group";
}
description
"Multicast global parameters for the VPN service.";
}
description
"Grouping for multicast VPN definition.";
}
grouping vpn-extranet {
container extranet-vpns {
if-feature extranet-vpn;
list extranet-vpn {
key vpn-id;
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leaf vpn-id {
type svc-id;
description
"Identifies the target VPN.";
}
leaf local-sites-role {
type identityref {
base site-role;
}
default any-to-any-role;
description
"This describes the role of the
local sites in the target VPN topology.";
}
description
"List of extranet VPNs the local VPN is attached to.";
}
description
"Container for extranet VPN configuration.";
}
description
"Grouping for extranet VPN configuration.
This provides an easy way to interconnect
all sites from two VPNs.";
}
grouping signaling-options-grouping {
list signaling-options {
key "type";
leaf type {
type identityref {
base vpn-signaling-type;
}
description
"VPN signaling types";
}
container bgp-l2vpn {
when "../type = 'bgp-l2vpn'" {
description
"Only applies when vpn signaling type is bgp-l2vpn.";
}
leaf vpn-id {
type leafref{
path "/l2vpn-svc/vpn-services/vpn-svc/vpn-id";
}
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description
"Identifies the target VPN";
}
leaf type {
type identityref {
base l2vpn-type;
}
description
"L2VPN types";
}
leaf pwe-encapsulation-type {
type identityref {
base pwe-encapsulation-type;
}
description
"Leaf for PWE Encapsulation Type configurations";
}
container pwe-mtu {
leaf allow-mtu-mismatch {
type boolean;
description
"Allow MTU mismatch";
}
description
"Container of PWE MTU configurations";
}
leaf address-family {
type identityref {
base address-family;
}
description
"Address family used for management.";
}
description
"Container for MP BGP L2VPN";
}
container mp-bgp-evpn {
when "../type = 'mp-bgp-evpn'" {
description
"Only applies when vpn signaling type is mp-bgp-evpn.";
}
leaf vpn-id {
type leafref{
path "/l2vpn-svc/vpn-services/vpn-svc/vpn-id";
}
description
"Identifies the target EVPN";
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}
leaf type {
type identityref {
base evpn-type;
}
description
"L2VPN types";
}
leaf address-family {
type identityref {
base address-family;
}
description
"Address family used for management.";
}
leaf mac-learning-mode {
type identityref {
base mac-learning-mode;
}
description
"Indicates through which plane MAC addresses are
advertised.";
}
leaf arp-suppress {
type boolean;
default false;
description
"Indicates whether to suppress ARP broadcast.";
}
description
"Container for MP BGP L2VPN";
}
container t-ldp-pwe {
when "../type = 't-ldp-pwe3'" {
description
"Only applies when vpn signaling type is bgp-l2vpn.";
}
leaf type {
type identityref {
base t-ldp-pwe-type;
}
description
"T-LDP PWE type";
}
leaf pwe-encapsulation-type {
type identityref {
base pwe-encapsulation-type;
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}
description
"Leaf for PWE Encapsulation Type configurations";
}
container pwe-mtu {
leaf allow-mtu-mismatch {
type boolean;
description
"Allow MTU mismatch";
}
description
"Container of PWE MTU configurations";
}
list pe-eg-list {
key "service-ip-addr vc-id";
leaf service-ip-addr {
type inet:ip-address;
description
"Service ip lo address";
}
leaf vc-id {
type string;
description
"VC id";
}
leaf peer-id {
type string;
description
"Local Peer id";
}
leaf remote-peer-id {
type string;
description
"Remote Peer id";
}
leaf pw-priority {
type uint32;
description
"PW priority";
}
description
"List of PE/EG";
}
leaf control-word {
type boolean;
description
"Control word configurations";
}
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container qinq {
when "../type = 'h-vpls'" {
description
"Only applies when t-ldp pwe type is h-vpls.";
}
leaf s-tag {
type uint32;
description
"S-TAG";
}
leaf c-tag {
type uint32;
description
"C-TAG";
}
description
"Container for QinQ";
}
description
"Container of T-LDP PWE configurations";
}
container l2tp-pw{
leaf encapsulation-type {
type identityref {
base encapsulation-type;
}
description
"Encapsulation type";
}
leaf control-word {
type boolean;
description
"Control word configurations";
}
description
"Container for l2tp pw";
}
description
"List of VPN Signaling Option.";
}
description
"Grouping for signaling option";
}
grouping load-balance-grouping {
leaf enable {
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type boolean;
description
"Enable load balancing";
}
leaf load-balance-method {
type identityref {
base load-balance-method;
}
description
"select load balancing method such as
fat-pw, entropy-label, or
vxlan-source-udp-port.";
}
description
"Grouping for load balance ";
}
grouping operational-requirements-ops {
leaf actual-site-start {
type yang:date-and-time;
config false;
description
"Optional leaf indicating actual date
and time when the service at a particular
site actually started";
}
leaf actual-site-stop {
type yang:date-and-time;
config false;
description
"Optional leaf indicating actual date
and time when the service at a particular
site actually stopped";
}
description
"This grouping defines some operational parameters
parameters";
}
grouping intra-mkt-grouping {
list intra-mkt {
key "mkt-name";
leaf mkt-name {
type string;
description
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"MKT Name";
}
leaf ovc-id {
type leafref {
path "/l2vpn-svc/vpn-services/vpn-svc/ovc/ovc-list/ovc-id";
}
description
"OVC id";
}
leaf site-id {
type leafref{
path "/l2vpn-svc/sites/site/site-id";
}
description
"OVC identifier";
}
description
"List of intra-MKT";
}
description
"Grouping for intra-MKT";
}
grouping inter-mkt-service {
leaf inter-mkt-service{
type boolean;
description
"Indicate whether service is inter market service.";
}
description
"Grouping for inter-MKT service";
}
grouping svc-type-grouping {
container evc {
if-feature evc;
leaf enabled {
type boolean;
description
"Enabled EVC";
}
leaf evc-type {
type identityref {
base evc-type;
}
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description
"EVC type";
}
leaf number-of-pe {
type uint32;
config false;
description
"Number of PE";
}
leaf number-of-site {
type uint32;
config false;
description
"Number of Sites";
}
container uni-list {
if-feature uni-list;
list uni-list {
key "uni-site-id";
leaf uni-site-id {
type string;
description
"UNI site Identifier";
}
leaf off-net {
type boolean;
description
"If Off net is set to true, off-net is enabled, if
off net is set to false, on-net is enabled";
}
leaf service-multiplexing {
type boolean;
description
"If the Service Multiplexing attribute is enabled then
multiple Ethernet Services can terminate at the UNI.
If Service Multiplexing is disabled, then only one
Ethernet Service can terminate at the UNI.";
}
leaf ce-vlan-preservation {
type boolean;
description
"CE vlan preservation";
}
leaf ce-vlan-cos-perservation {
type boolean;
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description
"CE vlan COS preservation";
}
description
"List for UNIs";
}
description
"Container for UNI List";
}
description
"Container for Ethernet virtual connection.";
}
container ovc {
//if-feature ovc;
list ovc-list {
key ovc-id;
leaf ovc-id {
type svc-id;
description
"OVC ID type";
}
leaf off-net {
type boolean;
description
"Off net";
}
leaf svlan-cos-preservation {
type boolean;
description
"SVLAN CoS preservation";
}
leaf svlan-id-preservation {
type boolean;
description
"SVLAN ID preservation";
}
leaf svlan-id-ethernet-tag {
type string;
description
"SVLAN-ID/Ethernet Tag configurations";
}
leaf ovc-endpoint {
type string;
description
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"OVC Endpoint";
}
description
"List for OVC";
}
description
"Container for OVC";
}
description
"Grouping of service types.";
}
grouping cfm-802-grouping {
leaf maid {
type string;
description
"MA ID";
}
leaf mep-id {
type uint32;
description
"Local MEP ID";
}
leaf mep-level {
type uint32;
description
"MEP level";
}
leaf mep-up-down {
type enumeration {
enum up {
description
"MEP up";
}
enum down {
description
"MEP down";
}
}
description
"MEP up/down";
}
leaf remote-mep-id {
type uint32;
description
"Remote MEP ID";
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}
leaf cos-for-cfm-pdus {
type uint32;
description
"COS for CFM PDUs";
}
leaf ccm-interval {
type uint32;
description
"CCM interval";
}
leaf ccm-holdtime {
type uint32;
description
"CCM hold time";
}
leaf alarm-priority-defect {
type identityref {
base fault-alarm-defect-type;
}
description
"The lowest priority defect that is
allowed to generate a Fault Alarm.
The non-existence of this leaf means
that no defects are to be reported";
}
leaf ccm-p-bits-pri {
type ccm-priority-type;
description
"The priority parameter for CCMs transmitted by the MEP";
}
description
"Grouping for 802.1ag CFM attribute";
}
grouping y-1731 {
list y-1731 {
key maid;
leaf maid {
type string;
description
"MA ID ";
}
leaf mep-id {
type uint32;
description
"Local MEP ID";
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}
leaf type {
type identityref {
base pm-type;
}
description
"Performance monitor types";
}
leaf remote-mep-id {
type uint32;
description
"Remote MEP ID";
}
leaf message-period {
type uint32;
description
"Defines the interval between OAM messages. The message
period is expressed in milliseconds";
}
leaf measurement-interval {
type uint32;
description
"Specifies the measurement interval for statistics. The
measurement interval is expressed in seconds";
}
leaf cos {
type uint32;
description
"Class of service";
}
leaf loss-measurement {
type boolean;
description
"Whether enable loss measurement";
}
leaf synthethic-loss-measurement {
type boolean;
description
"Indicate whether enable synthetic loss measurement";
}
container delay-measurement {
leaf enable-dm {
type boolean;
description
"Whether to enable delay measurement";
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}
leaf two-way {
type boolean;
description
"Whether delay measurement is two-way (true) of one-
way (false)";
}
description
"Container for delay measurement";
}
leaf frame-size {
type uint32;
description
"Frame size";
}
leaf session-type {
type enumeration {
enum proactive {
description
"Proactive mode";
}
enum on-demand {
description
"On demand mode";
}
}
description
"Session type";
}
description
"List for y-1731.";
}
description
"Grouping for y.1731";
}
grouping enni-site-info-grouping {
container site-info {
leaf site-name {
type string;
description
"Site name";
}
leaf address {
type inet:ip-address;
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description
"Address";
}
leaf Edge-Gateway-Device-Info {
type string;
description
"Edge Gateway Device Info ";
}
description
"Container of site info configurations";
}
description
"Grouping for site information";
}
grouping site-security {
container security {
uses mac-loop-prevention-grouping;
container access-control-list {
list mac {
key "mac-address";
leaf mac-address {
type yang:mac-address;
description
"MAC address";
}
description
"List for MAC";
}
description
"Container for access control";
}
uses mac-addr-limit-grouping;
description
"Security parameters";
}
description
"This grouping defines security parameters for a site";
}
grouping lacp-grouping {
container lacp {
leaf lacp-state {
type boolean;
description
"LACP on/off";
}
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leaf lacp-mode {
type boolean;
description
"LACP mode";
}
leaf lacp-speed {
type boolean;
description
"LACP speed";
}
leaf mini-link {
type uint32;
description
"The minimum aggregate bandwidth for a LAG";
}
leaf system-priority {
type uint16;
description
"Indicates the LACP priority for the system.
The range is from 0 to 65535.
The default is 32768.";
}
container micro-bfd {
if-feature micro-bfd;
leaf micro-bfd-on-off {
type enumeration {
enum on {
description
"Micro-bfd on";
}
enum off {
description
"Micro-bfd off";
}
}
description
"Micro BFD ON/OFF";
}
leaf bfd-interval {
type uint32;
description
"BFD interval";
}
leaf bfd-hold-timer {
type uint32;
description
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"BFD hold timer";
}
description
"Container of Micro-BFD configurations";
}
container bfd {
if-feature bfd;
leaf bfd-enabled {
type boolean;
description
"BFD activation";
}
choice holdtime {
case profile {
leaf profile-name {
type string;
description
"Service provider well known profile.";
}
description
"Service provider well known profile.";
}
case fixed {
leaf fixed-value {
type uint32;
units msec;
description
"Expected hold time expressed in msec.";
}
}
description
"Choice for hold time flavor.";
}
description
"Container for BFD.";
}
container member-link-list {
list member-link {
key "name";
leaf name {
type string;
description
"Member link name";
}
leaf port-speed {
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type uint32;
description
"Port speed";
}
leaf mode {
type neg-mode;
description
"Negotiation mode";
}
leaf mtu {
type uint32;
description
"MTU";
}
container oam-802.3ah-link {
if-feature oam-3ah;
leaf enable {
type boolean;
description
"Indicate whether support oam 802.3 ah link";
}
description
"Container for oam 802.3 ah link.";
}
description
"Member link";
}
description
"Container of Member link list";
}
leaf flow-control {
type string;
description
"Flow control";
}
leaf lldp {
type boolean;
description
"LLDP";
}
description
"LACP";
}
description
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"Grouping for lacp";
}
grouping phy-interface-grouping {
container phy-interface {
leaf port-number {
type uint32;
description
"Port number";
}
leaf port-speed {
type uint32;
description
"Port speed";
}
leaf mode {
type neg-mode;
description
"Negotiation mode";
}
leaf phy-mtu {
type uint32;
description
"PHY MTU";
}
leaf flow-control {
type string;
description
"Flow control";
}
leaf physical-if {
type string;
description
"Physical interface";
}
leaf circuit-id {
type string;
description
"Circuit ID";
}
leaf lldp {
type boolean;
description
"LLDP";
}
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container oam-802.3ah-link {
if-feature oam-3ah;
leaf enable {
type boolean;
description
"Indicate whether support oam 802.3 ah link";
}
description
"Container for oam 802.3 ah link.";
}
leaf uni-loop-prevention {
type boolean;
description
"If this leaf set to truth that the port automatically
goes down when a physical loopback is detect.";
}
description
"Container of PHY Interface Attributes configurations";
}
description
"Grouping for phy interface.";
}
grouping lag-interface-grouping {
container lag-interface {
if-feature lag-interface;
list lag-interface {
key "lag-interface-number";
leaf lag-interface-number {
type uint32;
description
"LAG interface number";
}
uses lacp-grouping;
description
"List of LAG interfaces";
}
description
"Container of LAG interface attributes configuration";
}
description
"Grouping for LAG interface";
}
grouping dot1q-interface-grouping {
container dot1q-interface {
leaf l2-access-type {
type identityref {
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base l2-access-type;
}
description
"Encapsulation Type";
}
container dot1q {
when "'../l2-access-type'='dot1q'";
if-feature dot1q;
leaf physical-inf {
type string;
description
"Physical Interface";
}
leaf c-vlan-id {
type uint32;
description
"VLAN identifier";
}
description
"Qot1q";
}
container qinq {
when "'../l2-access-type'='qinq'";
if-feature qinq;
leaf s-vlan-id {
type uint32;
description
"S-VLAN Identifier";
}
leaf c-vlan-id {
type uint32;
description
"C-VLAN Identifier";
}
description
"QinQ";
}
container qinany {
if-feature qinany;
leaf s-vlan-id {
type uint32;
description
"S-Vlan ID";
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}
description
"Container for Q in Any";
}
container vxlan {
when "'../l2-access-type'='vxlan'";
if-feature vxlan;
leaf vni-id {
type uint32;
description
"VNI Identifier";
}
leaf peer-mode {
type identityref {
base vxlan-peer-mode;
}
description
"specify the vxlan access mode";
}
list peer-list {
key peer-ip;
leaf peer-ip {
type inet:ip-address;
description
"Peer IP";
}
description
"List for peer IP";
}
description
"QinQ";
}
description
"Container for dot1Q Interface";
}
description
"Grouping for Layer2 access";
}
grouping ethernet-connection-grouping {
container connection {
leaf encapsulation-type {
type identityref {
base encapsulation-type;
}
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description
"Encapsulation Type";
}
leaf-list eth-inf-type {
type identityref {
base eth-inf-type;
}
description
"Ethernet Interface Type";
}
uses dot1q-interface-grouping;
uses phy-interface-grouping;
uses lag-interface-grouping;
uses l2cp-grouping;
description
"Container for bearer";
}
description
"Grouping for bearer.";
}
grouping svc-mtu-grouping {
leaf svc-mtu {
type uint32;
description
"EVC MTU";
}
description
"Grouping for evc mtu";
}
grouping mac-addr-limit-grouping {
container mac-addr-limit {
leaf exceeding-option {
type uint32;
description
"Exceeding option";
}
description
"Container of MAC-Addr limit configurations";
}
description
"Grouping for mac address limit";
}
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grouping availability-grouping {
container availability {
leaf access-priority {
type uint32;
description
"Access priority";
}
choice redundancy-mode {
case single-active {
leaf single-active {
type boolean;
description
"Single active";
}
description
"Single active case";
}
case all-active {
leaf all-active {
type boolean;
description
"All active";
}
description
"All active case";
}
description
"Redundancy mode choice";
}
description
"Container of availability optional configurations";
}
description
"Grouping for availability";
}
grouping l2cp-grouping {
container l2cp-control {
if-feature L2CP-control;
leaf stp-rstp-mstp {
type control-mode;
description
"STP/RSTP/MSTP protocol type applicable to all UNIs";
}
leaf pause {
type control-mode;
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description
"Pause protocol type applicable to all UNIs";
}
leaf lacp-lamp {
type control-mode;
description
"LACP/LAMP ";
}
leaf link-oam {
type control-mode;
description
"Link OAM";
}
leaf esmc {
type control-mode;
description
"ESMC";
}
leaf l2cp-802.1x {
type control-mode;
description
"802.x";
}
leaf e-lmi {
type control-mode;
description
"E-LMI";
}
leaf lldp {
type boolean;
description
"LLDP protocol type applicable to all UNIs";
}
leaf ptp-peer-delay {
type control-mode;
description
"PTP peer delay";
}
leaf garp-mrp {
type control-mode;
description
"GARP/MRP";
}
leaf provider-bridge-group {
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type control-mode;
description
"Provider bridge group reserved MAC address
01-80-C2-00-00-08";
}
leaf provider-bridge-mvrp {
type control-mode;
description
"Provider bridge MVRP reserved MAC address
01-80-C2-00-00-0D";
}
description
"Container of L2CP control configurations";
}
description
"Grouping for l2cp control";
}
grouping B-U-M-grouping {
container broadcast-unknown-unicast-multicast {
leaf multicast-site-type {
type enumeration {
enum receiver-only {
description
"The site only has receivers.";
}
enum source-only {
description
"The site only has sources.";
}
enum source-receiver {
description
"The site has both sources and receivers.";
}
}
default "source-receiver";
description
"Type of multicast site.";
}
list multicast-gp-address-mapping {
key id;
leaf id {
type uint16;
description
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"Unique identifier for the mapping.";
}
leaf vlan-id {
type uint32;
description
"the VLAN ID of the Multicast group";
}
leaf mac-gp-address {
type yang:mac-address;
description
"the MAC address of the Multicast group";
}
leaf port-lag-number {
type uint32;
description
"the ports/LAGs belonging to the Multicast group";
}
description
"List of Port to group mappings.";
}
leaf bum-overall-rate {
type uint32;
description
"overall rate for BUM";
}
list bum-rate-per-type {
key "type";
leaf type {
type identityref {
base bum-type;
}
description
"BUM type";
}
leaf rate {
type uint32;
description
"rate for BUM";
}
description
"List of rate per type";
}
description
"Container of broadcast, unknown unicast, and multicast configurations";
}
description
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"Grouping for broadcast, unknown unicast, and multicast ";
}
grouping mac-loop-prevention-grouping {
container mac-loop-prevention {
leaf frequency {
type uint32;
description
"Frequency";
}
leaf protection-type {
type identityref {
base loop-prevention-type;
}
description
"Protection type";
}
leaf number-retries {
type uint32;
description
"Number of retries";
}
description
"Container of MAC loop prevention.";
}
description
"Grouping for MAC loop prevention";
}
grouping ethernet-svc-oam-grouping {
container ethernet-service-oam {
leaf md-name {
type string;
description
"Maintenance domain name";
}
leaf md-level {
type uint8;
description
"Maintenance domain level";
}
container cfm-802.1-ag {
list n2-uni-c {
key "maid";
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uses cfm-802-grouping;
description
"List of UNI-N to UNI-C";
}
list n2-uni-n {
key "maid";
uses cfm-802-grouping;
description
"List of UNI-N to UNI-N";
}
description
"Container of 802.1ag CFM configurations.";
}
uses y-1731;
description
"Container for Ethernet service OAM.";
}
description
"Grouping for Ethernet service OAM.";
}
grouping fate-sharing-group {
container groups {
leaf fate-sharing-group-size {
type uint16;
description
"Fate sharing group size.";
}
list group {
key group-id;
leaf group-id {
type string;
description
"Group-id the site network access
is belonging to";
}
description
"List of group-id";
}
description
"Groups the fate sharing group member
is belonging to";
}
description
"Grouping for Fate sharing group.";
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}
grouping site-group {
container groups {
list group {
key group-id;
leaf group-id {
type string;
description
"Group-id the site is belonging to";
}
description
"List of group-id";
}
description
"Groups the site or site-network-access
is belonging to.";
}
description
"Grouping definition to assign
group-ids to site or site-network-access";
}
grouping access-diversity {
container access-diversity {
if-feature site-diversity;
uses fate-sharing-group;
container constraints {
list constraint {
key constraint-type;
leaf constraint-type {
type identityref {
base placement-diversity;
}
description
"Diversity constraint type.";
}
container target {
choice target-flavor {
case id {
list group {
key group-id;
leaf group-id {
type string;
description
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"The constraint will apply
against this particular
group-id";
}
description
"List of groups";
}
}
case all-accesses {
leaf all-other-accesses {
type empty;
description
"The constraint will apply
against all other site network
access of this site";
}
}
case all-groups {
leaf all-other-groups {
type empty;
description
"The constraint will apply
against all other groups the
customer is managing";
}
}
description
"Choice for the group definition";
}
description
"The constraint will apply against
this list of groups";
}
description
"List of constraints";
}
description
"Constraints for placing this site
network access";
}
description
"Diversity parameters.";
}
description
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"This grouping defines access diversity
parameters";
}
grouping request-type-profile-grouping {
container request-type-profile {
choice request-type-choice {
case dot1q-case {
container dot1q {
leaf physical-if {
type string;
description
"Physical interface";
}
leaf vlan-id {
type uint16;
description
"VLAN ID";
}
description
"Container for dot1q.";
}
description
"Case for dot1q";
}
case physical-case {
leaf physical-if {
type string;
description
"Physical interface";
}
leaf circuit-id {
type string;
description
"Circuit ID";
}
description
"Physical case";
}
description
"Choice for request type";
}
description
"Container for request type profile.";
}
description
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"Grouping for request type profile";
}
grouping site-attachment-bearer {
container bearer {
container requested-type {
if-feature requested-type;
leaf requested-type {
type string;
description
"Type of requested bearer Ethernet, DSL,
Wireless ..Operator specific.";
}
leaf strict {
type boolean;
default false;
description
"Define if the requested-type is a preference
or a strict requirement.";
}
description
"Container for requested type.";
}
leaf always-on {
if-feature always-on;
type boolean;
default true;
description
"Request for an always on access type.
This means no Dial access type for
example.";
}
leaf bearer-reference {
if-feature bearer-reference;
type string;
description
"This is an internal reference for the
service provider.";
}
description
"Bearer specific parameters.
To be augmented.";
}
description
"Grouping to define physical properties of
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a site attachment.";
}
grouping vpn-attachment-grouping {
container vpn-attachment {
leaf device-id {
type string;
description
"Device ID";
}
container management {
leaf address-family {
type identityref {
base address-family;
}
description
"Address family used for management.";
}
leaf address {
type inet:ip-address;
description
"Management address";
}
description
"Management configuration..";
}
choice attachment-flavor {
case vpn-flavor {
list vpn-flavor {
key vpn-id;
leaf vpn-id {
type leafref {
path "/l2vpn-svc/vpn-services"+
"/vpn-svc/vpn-id";
}
description
"Reference to a VPN.";
}
leaf site-role {
type identityref {
base site-role;
}
default any-to-any-role;
description
"Role of the site in the IPVPN.";
}
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description
"List of IPVPNs attached by the Site Network Access";
}
}
case vpn-policy-id {
leaf vpn-policy-id {
type leafref {
path "/l2vpn-svc/sites/site/vpn-policies/vpn-policy/vpn-policy-id";
}
description
"Reference to a vpn policy";
}
}
mandatory true;
description
"Choice for VPN attachment flavor.";
}
description
"Defines VPN attachment of a site.";
}
description
"Grouping for access attachment";
}
grouping site-service-basic {
container svc-input-bandwidth {
if-feature input-bw;
list input-bandwidth {
key "type";
leaf type {
type identityref {
base bw-type;
}
description
"Bandwidth Type";
}
leaf cos-id {
type uint8;
description
"Identifier of Class of Service
, indicated by DSCP or a CE-CLAN
CoS(802.1p)value in the service frame.";
}
leaf vpn-id {
type svc-id;
description
"Identifies the target VPN.";
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}
leaf cir {
type uint64;
description
"Committed Information Rate. The maximum number of
bits that a port can receive or send during
one-second over an interface.";
}
leaf cbs {
type uint64;
description
"Committed Burst Size.CBS controls the bursty nature
of the traffic. Traffic that does not use the configured
CIR accumulates credits until the credits reach the
configured CBS.";
}
leaf eir {
type uint64;
description
"Excess Information Rate,i.e.,Excess frame delivery
allowed not subject to SLA.The traffic rate can be
limited by eir.";
}
leaf ebs {
type uint64;
description
"Excess Burst Size. The bandwidth available for burst
traffic from the EBS is subject to the amount of bandwidth
that is accumulated during periods when traffic allocated
by the EIR policy is not used.";
}
leaf pir{
type uint32;
description
"Peak Information Rate, i.e., maixmum frame delivery allowed.
It is equal to or less than sum of cir and eir.";
}
leaf pbs {
type uint32;
description
"Peak Burst Size. It is measured in bytes per second.";
}
description
"List for input bandwidth";
}
description
"From the PE perspective, the service input
bandwidth of the connection.";
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}
container svc-output-bandwidth {
if-feature output-bw;
list output-bandwidth {
key "type";
leaf type {
type identityref {
base bw-type;
}
description
"Bandwidth Type";
}
leaf cos-id {
type uint8;
description
"Identifier of Class of Service
, indicated by DSCP or a CE-CLAN
CoS(802.1p)value in the service frame.";
}
leaf vpn-id {
type svc-id;
description
"Identifies the target VPN.";
}
leaf cir {
type uint32;
description
"Committed Information Rate. The maximum number of
bits that a port can receive or send during
one-second over an interface.";
}
leaf cbs {
type uint32;
description
"Committed Burst Size.CBS controls the bursty nature
of the traffic. Traffic that does not use the configured
CIR accumulates credits until the credits reach the
configured CBS.";
}
leaf eir {
type uint32;
description
"Excess Information Rate,i.e.,Excess frame delivery
allowed not subject to SLA.The traffic rate can be
limited by eir.";
}
leaf ebs {
type uint32;
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description
"Excess Burst Size. The bandwidth available for burst
traffic from the EBS is subject to the amount of bandwidth
that is accumulated during periods when traffic allocated
by the EIR policy is not used.";
}
leaf pir{
type uint32;
description
"Peak Information Rate, i.e., maixmum frame delivery allowed.
It is equal to or less than sum of cir and eir.";
}
leaf pbs {
type uint32;
description
"Peak Burst Size. It is measured in bytes per second.";
}
description
"List for output bandwidth";
}
description
"From the PE perspective, the service output
bandwidth of the connection.";
}
description
"Grouping for site service";
}
grouping flow-definition {
container match-flow {
leaf dscp {
type inet:dscp;
description
"DSCP value.";
}
leaf dot1p {
type uint8 {
range "0 .. 7";
}
description
"802.1p matching.";
}
leaf pcp {
type uint8;
description
"PCP value";
}
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leaf src-mac {
type yang:mac-address;
description
"Source MAC";
}
leaf dst-mac {
type yang:mac-address;
description
"Destination MAC";
}
container composite-id {
leaf endpoint-id {
type string;
description
"Endpoint ID";
}
leaf cos-label {
type identityref {
base cos-id;
}
description
"COS label";
}
leaf pcp {
type uint8;
description
"PCP value";
}
leaf dscp {
type inet:dscp;
description
"DSCP value.";
}
description
"Container for cos color id";
}
leaf color-type {
type identityref {
base color-type;
}
description
"Color Types";
}
leaf-list target-sites {
type svc-id;
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description
"Identify a site as traffic destination.";
}
description
"Describe flow matching criteria.";
}
description
"Flow definition based on criteria.";
}
grouping site-service-qos-profile {
container qos {
if-feature qos;
container qos-classification-policy {
list rule {
key id;
ordered-by user;
leaf id {
type uint16;
description
"ID of the rule.";
}
choice match-type {
case match-flow {
uses flow-definition;
}
case match-phy-port {
leaf match-phy-port {
type uint16;
description
"Defines the physical port
to match.";
}
}
description
"Choice for classification";
}
leaf target-class-id {
type string;
description
"Identification of the class of service.
This identifier is internal to the
administration.";
}
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description
"List of marking rules.";
}
description
"Need to express marking rules ...";
}
container qos-profile {
choice qos-profile {
description
"Choice for QoS profile.
Can be standard profile or custom.";
case standard {
leaf profile {
type string;
description
"QoS Profile to be used";
}
}
case custom {
container classes {
if-feature qos-custom;
list class {
key class-id;
leaf class-id {
type string;
description
"Identification of the class of
service. This identifier is internal
to the administration.";
}
leaf direction {
type identityref {
base qos-profile-direction;
}
default bidirection;
description
"The direction which QoS profile is applied to";
}
leaf policing {
type identityref {
base policing;
}
description
"The policing can be either one-rate,
two-color (1R2C) or two-rate, three-color
(2R3C)";
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}
leaf byte-offset {
type uint16;
description
"For not including extra VLAN tags in the QoS
calculation";
}
leaf rate-limit {
type uint8;
units percent;
description
"To be used if class must be rate limited.
Expressed as percentage of the svc-bw.";
}
leaf discard-percentage {
type uint8;
default 100;
description
"The value of the discard-percentage,
Expressed as pecentage of the svc-bw ";
}
container frame-delay {
choice flavor {
case lowest {
leaf use-low-del {
type empty;
description
"The traffic class should use
the lowest delay path";
}
}
case boundary {
leaf delay-bound {
type uint16;
units msec;
description
"The traffic class should use
a path with a defined maximum
delay.";
}
}
description
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"Delay constraint on the traffic
class";
}
description
"Delay constraint on the traffic
class";
}
container frame-jitter {
choice flavor {
case lowest {
leaf use-low-jit {
type empty;
description
"The traffic class should use
the lowest jitter path";
}
}
case boundary {
leaf delay-bound {
type uint32;
units usec;
description
"The traffic class should use
a path with a defined maximum
jitter.";
}
}
description
"Jitter constraint on the traffic
class";
}
description
"Jitter constraint on the traffic
class";
}
container frame-loss {
leaf fr-loss-rate {
type decimal64 {
fraction-digits 2;
}
description
"Loss constraint on the traffic class";
}
description
"Container for frame loss";
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}
container bandwidth {
leaf guaranteed-bw-percent {
type uint8;
units percent;
description
"To be used to define the guaranteed bandwidth
as a percentage of the available service
bandwidth.";
}
leaf end-to-end {
type empty;
description
"Used if the bandwidth reservation
must be done on the MPLS network too.";
}
description
"Bandwidth constraint on the traffic class.";
}
description
"List of class of services.";
}
description
"Container for list of class of services.";
}
}
}
description
"Qos profile configuration.";
}
description
"QoS configuration.";
}
description
"This grouping defines QoS parameters
for a site";
}
grouping services-grouping {
container service {
uses site-service-qos-profile;
description
"Container for service";
}
description
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"Grouping for Services";
}
grouping service-grouping {
container service {
uses site-service-basic;
uses site-service-qos-profile;
description
"Container for service";
}
description
"Grouping for service.";
}
/* MAIN L2VPN SERVICE */
container l2vpn-svc {
container vpn-services {
list vpn-svc {
key "vpn-id";
leaf vpn-id {
type svc-id;
description
"Defining a service id.";
}
leaf vpn-type {
type identityref {
base service-type;
}
description
"Service type";
}
leaf customer-account-number {
type uint32;
description
"Customer account number";
}
leaf customer-name {
type string;
description
"Customer name";
}
uses svc-type-grouping;
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leaf svc-topo {
type identityref {
base vpn-topology;
}
description
"Defining service topology, such as
any-to-any,hub-spoke, etc.";
}
uses vpn-service-cloud-access;
container metro-networks {
list metro-network {
key id;
leaf id {
type string;
description
"Unique identifier for each end to end
network connectivity in metro networks.";
}
uses inter-mkt-service;
uses intra-mkt-grouping;
description
"List of end to end network connectivity
associated with metro networks.";
}
description
"Container of Metro-Network ID configurations";
}
container global-l2cp-control {
if-feature L2CP-control;
leaf stp-rstp-mstp {
type control-mode;
description
"STP/RSTP/MSTP protocol type applicable to all UNIs";
}
leaf pause {
type control-mode;
description
"Pause protocol type applicable to all UNIs ";
}
leaf lldp {
type boolean;
description
"LLDP protocol type applicable to all UNIs ";
}
description
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"Container of L2CP control global configurations";
}
container service-level-mac-limit {
leaf service-level-mac-limit {
type uint16;
description
"maximum number of MAC addresses learned from
the subscriber for a single service instance
";
}
leaf action {
type identityref {
base mac-action;
}
description
"specify the action when the upper limit is
exceeded: drop the packet, flood the
packet, or simply send a warning log message.
";
}
description
"Service-level MAC-limit (E-LAN only)";
}
uses service-protection;
uses site-service;
uses vpn-service-multicast;
uses vpn-extranet;
description
"List of vpn-svc";
}
description
"Container for VPN services.";
}
/* SITE */
container sites {
list site {
key "site-id site-type";
leaf site-id {
type string;
description
"Site id";
}
leaf site-type {
type identityref {
base site-type;
}
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description
"Site type";
}
uses site-device;
uses customer-location-info;
uses site-management;
uses site-diversity;
uses site-vpn-policy;
container signaling-options {
if-feature signaling-options;
uses signaling-options-grouping;
description
"Container for signaling option";
}
container load-balance-options {
uses load-balance-grouping;
description
"Container for load balance options";
}
uses services-grouping;
uses B-U-M-grouping;
uses site-security;
uses operational-requirements-ops;
container site-network-accesses {
list site-network-accesse {
key "network-access-id";
leaf network-access-id {
type string;
description
"Identifier of network access";
}
leaf remote-carrier-name {
when "'../site-type' = 'enni'" {
description
"Site type = enni";
}
type string;
description
"Remote carrier name";
}
uses access-diversity;
uses site-attachment-bearer;
uses ethernet-connection-grouping;
uses svc-mtu-grouping;
uses availability-grouping;
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uses vpn-attachment-grouping;
uses service-grouping;
uses B-U-M-grouping;
uses ethernet-svc-oam-grouping;
uses site-security;
description
"List of Site Network Accesses.";
}
description
"Container of Site Network Access configurations";
}
description
"List of sites";
}
description
"Container of site configurations";
}
description
"Container for L2VPN service";
}
}
9. Security Considerations
The YANG modules defined in this document MAY be accessed via the
RESTCONF protocol [RFC8040] or NETCONF protocol ([RFC6241]). The
lowest RESTCONF or NETCONF layer requires that the transport-layer
protocol provides both data integrity and confidentiality, see
Section 2 in [RFC8040] and [RFC6241]. The client MUST carefully
examine the certificate presented by the server to determine if it
meets the client's expectations, and the server MUST authenticate
client access to any protected resource. The client identity derived
from the authentication mechanism used is subject to the NETCONF
Access Control Module (NACM) ([RFC6536]). Other protocols to access
this YANG module are also required to support the similar mechanism.
The data nodes defined in the "ietf-l2vpn-svc" YANG module MUST be
carefully created/read/updated/deleted. The entries in the lists
below include customer proprietary or confidential information,
therefore only authorized clients MUST access the information and the
other clients MUST NOT be able to access to the information.
o /l2vpn-svc/customer-info/customer-info
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o /l2vpn-svc/vpn-services/vpn-svc
o /l2vpn-svc/sites/site
10. Acknowledgements
Thanks to Qin Wu and Adrian Farrel for facilitating work on the
initial revisions of this document. Thanks to Zonghe Huang, Wei Deng
and Xiaoling Song to help review this draft.
This document has drawn on the work of the L3SM Working Group
expressed in [RFC8049].
11. IANA Considerations
IANA is requested to assign a new URI from the IETF XML registry
([RFC3688]). The following URI is suggested:
URI: urn:ietf:params:xml:ns:yang:ietf-l2vpn-svc
Registrant Contact: L2SM WG
XML: N/A, the requested URI is an XML namespace
This document also requests a new YANG module name in the YANG Module
Names registry ([RFC6020]) with the following suggestion:
name: ietf-l2vpn-svc
namespace: urn:ietf:params:xml:ns:yang:ietf-l2vpn-svc
prefix: l2vpn-svc
reference: RFC XXXX
12. References
12.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
.
[RFC3688] Mealling, M., "The IETF XML Registry", BCP 81, RFC 3688,
DOI 10.17487/RFC3688, January 2004,
.
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[RFC4448] Martini, L., Ed., Rosen, E., El-Aawar, N., and G. Heron,
"Encapsulation Methods for Transport of Ethernet over MPLS
Networks", RFC 4448, DOI 10.17487/RFC4448, April 2006,
.
[RFC4761] Kompella, K., Ed. and Y. Rekhter, Ed., "Virtual Private
LAN Service (VPLS) Using BGP for Auto-Discovery and
Signaling", RFC 4761, DOI 10.17487/RFC4761, January 2007,
.
[RFC4762] Lasserre, M., Ed. and V. Kompella, Ed., "Virtual Private
LAN Service (VPLS) Using Label Distribution Protocol (LDP)
Signaling", RFC 4762, DOI 10.17487/RFC4762, January 2007,
.
[RFC6020] Bjorklund, M., Ed., "YANG - A Data Modeling Language for
the Network Configuration Protocol (NETCONF)", RFC 6020,
DOI 10.17487/RFC6020, October 2010,
.
[RFC6073] Martini, L., Metz, C., Nadeau, T., Bocci, M., and M.
Aissaoui, "Segmented Pseudowire", RFC 6073,
DOI 10.17487/RFC6073, January 2011,
.
[RFC6074] Rosen, E., Davie, B., Radoaca, V., and W. Luo,
"Provisioning, Auto-Discovery, and Signaling in Layer 2
Virtual Private Networks (L2VPNs)", RFC 6074,
DOI 10.17487/RFC6074, January 2011,
.
[RFC6241] Enns, R., Ed., Bjorklund, M., Ed., Schoenwaelder, J., Ed.,
and A. Bierman, Ed., "Network Configuration Protocol
(NETCONF)", RFC 6241, DOI 10.17487/RFC6241, June 2011,
.
[RFC6536] Bierman, A. and M. Bjorklund, "Network Configuration
Protocol (NETCONF) Access Control Model", RFC 6536,
DOI 10.17487/RFC6536, March 2012,
.
[RFC6991] Schoenwaelder, J., Ed., "Common YANG Data Types",
RFC 6991, DOI 10.17487/RFC6991, July 2013,
.
[RFC7224] Bjorklund, M., "IANA Interface Type YANG Module",
RFC 7224, DOI 10.17487/RFC7224, May 2014,
.
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[RFC7348] Mahalingam, M., Dutt, D., Duda, K., Agarwal, P., Kreeger,
L., Sridhar, T., Bursell, M., and C. Wright, "Virtual
eXtensible Local Area Network (VXLAN): A Framework for
Overlaying Virtualized Layer 2 Networks over Layer 3
Networks", RFC 7348, DOI 10.17487/RFC7348, August 2014,
.
[RFC7432] Sajassi, A., Ed., Aggarwal, R., Bitar, N., Isaac, A.,
Uttaro, J., Drake, J., and W. Henderickx, "BGP MPLS-Based
Ethernet VPN", RFC 7432, DOI 10.17487/RFC7432, February
2015, .
[RFC8040] Bierman, A., Bjorklund, M., and K. Watsen, "RESTCONF
Protocol", RFC 8040, DOI 10.17487/RFC8040, January 2017,
.
[RFC8049] Litkowski, S., Tomotaki, L., and K. Ogaki, "YANG Data
Model for L3VPN Service Delivery", RFC 8049,
DOI 10.17487/RFC8049, February 2017,
.
12.2. Informative References
[I-D.ietf-bess-evpn-yang]
Brissette, P., Sajassi, A., Shah, H., Li, Z.,
Tiruveedhula, K., Hussain, I., and J. Rabadan, "Yang Data
Model for EVPN", draft-ietf-bess-evpn-yang-02 (work in
progress), March 2017.
[I-D.ietf-bess-l2vpn-yang]
Shah, H., Brissette, P., Chen, I., Hussain, I., Wen, B.,
and K. Tiruveedhula, "YANG Data Model for MPLS-based
L2VPN", draft-ietf-bess-l2vpn-yang-06 (work in progress),
June 2017.
[I-D.ietf-opsawg-service-model-explained]
Wu, Q., LIU, W., and A. Farrel, "Service Models
Explained", draft-ietf-opsawg-service-model-explained-03
(work in progress), September 2017.
[IEEE-802-1ag]
IEEE, "802.1ag - Connectivity Fault Management", December
2007.
[ITU-T-Y-1731]
ITU-T, "Recommendation Y.1731 - OAM functions and
mechanisms for Ethernet based networks", February 2008.
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[MEF-23-2]
MEF Forum, "Implementation Agreement MEF 23.2 : Carrier
Ethernet Class of Service - Phase 3", August 2016.
[RFC6624] Kompella, K., Kothari, B., and R. Cherukuri, "Layer 2
Virtual Private Networks Using BGP for Auto-Discovery and
Signaling", RFC 6624, DOI 10.17487/RFC6624, May 2012,
.
Appendix A. Changes Log
Changes in v-(01) include:
o Reference Update.
o Fix figure in section 3.3 and section 3.4
o Consider VPWS, VPLS, EVPN as basic service and view EVC related
service as additional service.
o Model structure change, move two customer information related
parameter into VPN Services container, remove 'customer-info
'container
o Redefine vpn-type to cover VPWS, VPLS, EVPN service;
o Consolidate EVC and OVC container, make them optional since for
some L2VPN service such as EVPN sevice, OVC, EVC are not needed.
o Add service and security filter under sites container and change
"ports" into "site-network-accesses" to get consistent with L3SM
and also make it generalized.
o Fixed usage examples in the l2sm model draft.
Changes in v-(02) include:
o Fix figure 3 and figure 4 in section 3.4 to apply IEEE802.3 on the
segment between C and CE and apply IEEE802.1Q on the segment
between CE and PE.
o Update Signaling Option section and add L2TP support and classify
the signaling option type into BGP-L2VPN, BGP-EVPN, LDP-PWE, L2TP-
PW.
o Add Multicast Support in section 5.2.13, section 5.10.3 and move
the text in BUM Storm Control section into section 5.10.3.
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o Add new section 5.3.1, section 5.4, section 5.5, section 5.6,
section 5.7, section 5.8, section 5.11to explain the usage of
constraint parameters and service placement related parameters.
o Add new section 5.1 and 5.14 to allow augmentation and external ID
References.
o Add new section to discuss inter-AS support and inter-provider
support with NNI and EVC, OVC.
o Update Service Section 5.10 and define four type for svc-input-
bandwidth and svc-output-bandwidth and add guaranteed-bw-percent
parameter and related description.
o Add extranet VPN support.
o Remove duplicated parameters from cloud access.
o Move L2CP control plane protocol parameters under connection.
o Update section 5.3.3.2 to address loop avoidance issue and divide
section 5.3.3.2 into Physical interface section, LAG interface
section and Addressing Section.
o Reference Update.
Changes in v-(03) include:
o Introduce additional terminology.
o Modify figure 5 to get consistent with RFC8049.
o Add end to end Multi-segment connectivity support and site-vpn-
flavor-e2e attribute.
o Add usage example to explain how to use EVC and OVC.
o Discuss applicability of this model to inter-provider support.
o Reduce redundant parameters related to encapsulation type and
Ethernet type in the model.
o Clarify the relationship between guarantee-bandwidth-percent and
CIR, EIR and PIR.
o Modify model structure for VPN service to make it consistent with
the text in section 5.
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o Remove Sub-inf parameter since it is similar to QinQ parameter.
o Add "direction" parameter for QoS profile.
o Update XML example and figure in section 5.16.
Appendix B. Open Issues
o Do we need to support L2VPN Interworking with ATMoMPLS,PPPoMPLS,
FroMPLS?
o Need to understand relationship between member link name under
LAG-interface and network-access-id.
Authors' Addresses
Bin Wen
Comcast
Email: bin_wen@comcast.com
Giuseppe Fioccola (editor)
Telecom Italia
Email: giuseppe.fioccola@telecomitalia.it
Chongfeng Xie
China Telecom
Email: xiechf@ctbri.com.cn
Luay Jalil
Verizon
Email: luay.jalil@verizon.com
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