TEAS Working Group Y. Lee (Editor)
Internet Draft Huawei
Intended Status: Standard Track D. Ceccarelli
Ericsson
Dhruv Doddy
Huawei
Takuya Miyasaka
KDDI
Peter Park
KT
Bin Young Yoon
ETRI
Expires: January 20, 2017 July 20, 2016
A Yang Data Model for ACTN VN Operation
draft-lee-teas-actn-vn-yang-01.txt
Abstract
This document provides a YANG data model for the Abstraction and
Control of Traffic Engineered (TE) networks (ACTN) Virtual Network
(VN) operation.
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Copyright Notice
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Table of Contents
1. Introduction...................................................2
1.1. Terminology...............................................3
1.2. ACTN CMI context..........................................3
2. ACTN VN YANG Model (Tree Structure)............................7
3. ACTN-VN YANG Model.............................................8
4. Security Considerations.......................................16
5. IANA Considerations...........................................16
6. Acknowledgments...............................................16
7. References....................................................17
7.1. Normative References.....................................17
7.2. Informative References...................................17
8. Contributors..................................................17
Authors' Addresses...............................................18
1. Introduction
This document provides a YANG data model for the Abstraction and
Control of Traffic Engineered (TE) networks (ACTN) Virtual Network
(VN) operation that is going to be implemented for the Customer
Network Controller (CNC)- Multi-Domain Service Coordinator (MSDC)
interface (CMI). The YANG model discussed in this document is used
to operate customer-driven VNs during the VN instantiation and its
life-cycle operations stages.
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This document is based on the requirements identified in [ACTN-REQ]
and on the architecture framework defined in [ACTN-FWK]. As defined
in [ACTN-FW], a Virtual Network (VN) is a customer view of the TE
networks and may comprise a set of end-to-end tunnels connecting
customer's end points. Therefore, it is important to associate a VN
with its members (which are a number of end-to-end tunnels) that are
going to be created in the provider network. Each end-to-end tunnel
defined under a VN is referred to as a VN member.
The YANG model discussed in this document basically provides the
characteristics of VNs such as VN level parameters (e.g., VN ID, VN
member, VN objective function, VN service preference, etc.),
customer's end point characteristics (e.g., Customer Interface
Capability, Access Points Interface characteristics, etc.), and
other relevant VN information that needs to be known to the MDSC to
facilitate ACTN VN operation.
1.1. Terminology
- Abstract Topology: Every lower controller in the provider
network, when is representing its network topology to a higher
layer, it may want to hide details of the actual network
topology. In such case, an abstract topology may be used for
this purpose. Abstract topology enhances scalability for the
MDSC to operate multi-domain networks. The abstraction of
topology can be applied on both MPI and CMI, from PNC to MDSC
and from MDSC to CNC respectively.
- Access link: A link between a customer node and a provider
node.
- Access Point (AP): An access point is defined on an access
link. It is used to keep confidentiality between the customer
and the provider. It is an identifier shared between the
customer and the provider, used to map the end points of the
border node in the provider NW. The AP can be used by the
customer when requesting connectivity service to the provider.
A number of parameters, e.g. available bandwidth, need to be
associated to the AP to qualify it.
- VN Access Point (VNAP): A VNAP is defined within an AP as part
of a given VN and is used to identify the portion of the AP,
(and hence of the access link) dedicated to a given VN.
1.2. ACTN CMI context
The model presented in this document has the following ACTN context.
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+-------+
| CNC |
+-------+
|
| <--- CMI (CNC-MDSC Interface)
|
+-----------------------+
| MDSC |
+-----------------------+
Figure 1. ACTN CMI
The CNC is the actor of the VN creation/modification/deletion (aka
VN CRUD (Create, Read, Update and Delete) model).
1. A VN may comprise a set of end-to-end tunnels from a customer
point of view that connects customer endpoints (i.e., source CE
and destination CE). See Figure 3 for this VN type.
2. A VN may comprise of a number of virtual nodes and virtual links
(more than a tunnel).
For both cases, the CNC can dynamically add VN elements. For case 1,
the VN element is an end-to-end tunnel and for case 2, the VN
element can be virtual nodes or virtual links.
In the subsequent discussion, the first form of VN will be
discussed.
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The following figure describes a VN that comprises three VN members
forming a full mesh for the VN as an illustration.
VN Member 1
|<-------------------------------------->|
| |
| ------------- |
| ( ) |
| - - |
+---+ X ( Provider ) Z +---+
|CE1|---+----( )---+---|CE2|
+---+ AP1 ( Network ) AP2 +---+
.- - - _ -.
|\ ( ) /|
\ ------------- /
\ | /
---- + AP3 ----
VN Member 2 \ | / VN Member 3
\ Y | /
\ +---+ /
`----> |CE3|<----`
+---+
Figure 2. Full Mesh Example for a VN
In Figure 2, a VN has three members, namely, VN Member 1, VN member
2, and VN member 3. VN Member 1 is an end-to-end tunnel identified
by CE1-AP1 (source) and CE2-AP2 (destination). Similarly, VN Member
2 by CE1-AP1 and CE3-AP3 and VN Member 3 by CE3-AP3 and CE2-AP2.
This particular VN shown in Figure 2 is a full mesh connectivity
across these three customer end-points.
It is also possible for the customer to create a VN which can be a
hub and spoke or any other form of connectivity depending on its
connectivity requirement. Each end-to-end tunnel may be
unidirectional or bidirectional which is also depending on its
connectivity requirements. The following figure shows some examples
of a VN that can represented in a different connectivity form
depending on the customer's connectivity requirements.
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+---+ +---+ +---+ +---+ +---+ +---+
|CE1|---------|CE2| |CE4|---------|CE5| |CE8|---------|CE9|
+---+ +---+ +---+ +---+ +---+ +---+
\ / | \ | \ |
\ / | \ | \ |
\ / | \ | \ |
\ / | \ | \ |
\ / | \ | \ |
\ / | \ | \ |
+---+ +---+ +---+ +---+ +---+
|CE3| |CE6| |CE7| |CE6|---------|CE7|
+---+ +---+ +---+ +---+ +---+
(a) Full Mesh (b) Hub and Spoke (c) partial Mesh
Figure 3. Different Connectivity Forms of a VN
It is important to note that a VN can associate a multiple number of
end-to-end tunnels (i.e., VN members) with one unique identifier.
From a customer standpoint, this simplifies its VN operation
significantly.
The MDSC interacts with the CNC for the VN operation. Once the
customer VN is requested by the CNC to the MDSC, the MDSC shall be
responsible for translating and mapping the VN request into specific
network centric-models (e.g., TE-tunnels [TE-Tunnel], TE-topology
[TE-TOPO], etc.) to coordinate the multi-domain network operations
with PNCs. The mapping and translation of a VN into network-centric
models is out of the scope of this document.
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The set of assumptions that applies to this document is the
following:
- CNC is responsible for providing necessary Customer End-Points
information to the MDSC via the CMI.
- The access links (between Customer Edge (CE) Devices and the
Provider Edge (PE) Devices) are assumed to have been
provisioned prior to the VN instantiation request.
- Access point identifiers have been configured and therefore are
known in both the CNC and the MDSC.
2. ACTN VN YANG Model (Tree Structure)
module: ietf-actn-vn
+--rw actn
| +--rw ap
| | +--rw access-point-list* [access-point-id]
| | +--rw access-point-id uint32
| | +--rw access-point-name? string
| | +--rw max-bandwidth? decimal64
| | +--rw avl-bandwidth? decimal64
| +--rw vn
| +--rw vn-list* [vn-id]
| +--rw vn-id uint32
| +--rw vn-name? string
| +--rw vn-member-list* [vn-member-id]
| | +--rw vn-member-id uint32
| | +--rw src? leafref
| | +--rw src-vn-ap-id? uint32
| | +--rw dest? leafref
| | +--rw dest-vn-ap-id? uint32
| +--rw delay? uint32
| +--rw delay-variation? uint32
| +--rw packet-loss? decimal64
| +--rw bandwidth? decimal64
| +--rw protection? identityref
| +--rw local-reroute? boolean
| +--rw push-allowed? boolean
| +--rw incremental-update? boolean
| +--rw admin-status? identityref
+--ro actn-state
+--ro ap
| +--ro access-point-list* [access-point-id]
| +--ro access-point-id uint32
| +--ro access-point-name? string
| +--ro max-bandwidth? decimal64
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| +--ro avl-bandwidth? decimal64
+--ro vn
+--ro vn-list* [vn-id]
+--ro vn-id uint32
+--ro vn-name? string
+--ro vn-member-list* [vn-member-id]
| +--ro vn-member-id uint32
| +--ro src? leafref
| +--ro src-vn-ap-id? uint32
| +--ro dest? leafref
| +--ro dest-vn-ap-id? uint32
| +--ro delay? uint32
| +--ro delay-variation? uint32
| +--ro packet-loss? decimal64
| +--ro oper-status? identityref
+--ro delay? uint32
+--ro delay-variation? uint32
+--ro packet-loss? decimal64
+--ro bandwidth? decimal64
+--ro protection? identityref
+--ro local-reroute? boolean
+--ro push-allowed? boolean
+--ro incremental-update? boolean
+--ro admin-status? identityref
+--ro oper-status? Identityref
3. ACTN-VN YANG Code
The YANG code is as follows:
<CODE BEGINS> file ietf-actn-vn@2016-7-5.yang
module ietf-actn-vn {
namespace "urn:ietf:params:xml:ns:yang:ietf-actn-vn";
prefix "vn";
/* Import TE generic types */
import ietf-te-types {
prefix "te-types";
}
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organization
"IETF Traffic Engineering Architecture and Signaling (TEAS)
Working Group";
contact
"Editor: Young Lee <leeyoung@huawei.com>";
description
"This module contains a YANG module for the ACTN VN. It
describes a VN operation module that takes place in the
context of the CNC-MDSC Interface (CMI) of the ACTN
architecture where the CNC is the actor of a VN creation
/modification /deletion.";
revision 2016-07-05 {
description
"initial version.";
reference
"TBD";
}
/*
* Groupings
*/
grouping access-point{
description
"AP related information";
leaf access-point-id {
type uint32;
description
"unique identifier for the referred
access point";
}
leaf access-point-name {
type string;
description
"ap name";
}
leaf max-bandwidth {
type decimal64 {
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fraction-digits 2;
range "0..max";
}
description
"max bandwidth of the AP";
}
leaf avl-bandwidth {
type decimal64 {
fraction-digits 2;
range "0..max";
}
description
"available bandwidth of the AP";
}
/*add details and any other properties of AP,
not associated by a VN
CE port, PE port etc.
This link may not be in the TE topology model(?)
thus reference to that model would be incorrect
*/
}//access-point
grouping vn-member {
description
"vn-member is described by this container";
leaf vn-member-id {
type uint32;
description
"vn-member identifier";
}
leaf src {
type leafref {
path "/actn/ap/access-point-list/access-point-id";
}
description
"reference to source AP";
}
leaf src-vn-ap-id{
type uint32;
description
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"vn-ap-id";
}
leaf dest {
type leafref {
path "/actn/ap/access-point-list/access-point-id";
}
description
"reference to destination AP";
}
leaf dest-vn-ap-id{
type uint32;
description
"vn-ap-id";
}
/* can we add reference to itef-te model(?) here
*/
}//vn-member
grouping connectivity-metric {
description
"service aware metrics";
leaf delay {
type uint32 {
range "0..max";
}
description
"Path Delay or latency in micro seconds.";
}
leaf delay-variation {
type uint32 {
range "0..max";
}
description
"Path Delay variation in micro seconds.";
}
leaf packet-loss {
type decimal64 {
fraction-digits 6;
range "0 .. max";
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}
description
"Path Packet Loss in percentage";
}
/*should we add other metrics
like bandwidth utilization?*/
}//connectivity-metric
grouping policy {
description
"policy related to vn-member-id";
leaf local-reroute {
type boolean;
description
"Policy to state if reroute
can be done locally";
}
leaf push-allowed {
type boolean;
description
"Policy to state if changes
can be pushed to the customer";
}
leaf incremental-update {
type boolean;
description
"Policy to allow only the
changes to be reported";
}
}//policy
grouping objective-function {
description
"objective-function";
uses connectivity-metric;
leaf bandwidth {
type decimal64 {
fraction-digits 2;
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range "0..max";
}
description
"bandwidth requested/required for
vn-member-id";
}
leaf protection {
type identityref {
base te-types:lsp-prot-type;
}
description "protection type.";
}
uses policy;
}//objective-function
/*
* Configuration data nodes
*/
container actn {
description
"actn is described by this container";
container ap {
description
"AP configurations";
list access-point-list {
key "access-point-id";
description
"access-point identifier";
uses access-point{
description
"access-point information";
}
}
}
container vn {
description
"VN configurations";
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list vn-list {
key "vn-id";
description
"a virtual network is identified by a vn-id";
leaf vn-id {
type uint32;
description
"a unique vn identifier";
}
leaf vn-name {
type string;
description "vn name";
}
list vn-member-list{
key "vn-member-id";
description
"List of VN-members in a VN";
uses vn-member;
}
uses objective-function;
leaf admin-status {
type identityref {
base te-types:state-type;
}
default te-types:state-up;
description "VN administrative state.";
}
}//vn-list
}//vn
}//actn
/*
* Operational data nodes
*/
container actn-state{
config false;
description
"actn is described by this container";
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container ap {
description
"AP state";
list access-point-list {
key "access-point-id";
description
"access-point identifier";
uses access-point{
description
"access-point information";
}
}
}
container vn {
description
"VN state";
list vn-list {
key "vn-id";
description
"a virtual network is identified by a vn-id";
leaf vn-id {
type uint32;
description
"a unique vn identifier";
}
leaf vn-name {
type string;
description "vn name";
}
list vn-member-list{
key "vn-member-id";
description
"List of VN-members in a VN";
uses vn-member;
uses connectivity-metric;
leaf oper-status {
type identityref {
base te-types:state-type;
}
description
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"VN-member operational state.";
}
}
uses objective-function;
leaf admin-status {
type identityref {
base te-types:state-type;
}
description "VN administrative state.";
}
leaf oper-status {
type identityref {
base te-types:state-type;
}
description "VN operational state.";
}
}//vn-list
}//vn
}//actn-state
}
<CODE ENDS>
4. Security Considerations
TDB
5. IANA Considerations
TDB
6. Acknowledgments
This document was prepared using 2-Word-v2.0.template.dot.
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7. References
7.1. Normative References
[ACTN-REQ] Lee, et al., "Requirements for Abstraction and Control of
TE Networks", work in progress: draft-ietf-teas-actn-
requirements.
[ACTN-FWK] D. Ceccarelli, Y. Lee [Editors], "Framework for
Abstraction and Control of Traffic Engineered Networks",
work in progress: draft-ceccarelli-teas-actn-framework.
[TE-TOPO] X. Liu, et al., "YANG Data Model for TE Topologies", work
in progress: draft-ietf-teas-yang-te-topo.
[TE-tunnel] T. Saad, et al., "A YANG Data Model for Traffic
Engineering Tunnels and Interfaces", work in progress:
draft-ietf-teas-yang-te.
7.2. Informative References
8. Contributors
Contributor's Addresses
Haomian Zheng
Huawei Technologies
Email: zhenghaomian@huawei.com
Xian Zhang
Huawei Technologies
Email: zhang.xian@huawei.com
Sergio Belotti
Nokia
Email: sergio.belotti@nokia.com
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Authors' Addresses
Young Lee (ed.)
Huawei Technologies
Email: leeyoung@huawei.com
Daniele Ceccarelli
Ericsson
Torshamnsgatan,48
Stockholm, Sweden
Email: daniele.ceccarelli@ericsson.com
Dhruv Dhoddy
Huawei Technologies,
Email: dhruv.ietf@gmail.com
Takuya Miyasaka
KDDI
Email: ta-miyasaka@kddi.com
Peter Park
KT
Email: peter.park@kt.com
Bin Yeong Yoon
ETRI
Email: byyun@etri.re.kr
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