Network Working Group A. Clemm
Internet-Draft J. Medved
Intended status: Experimental T. Tkacik
Expires: April 13, 2015 R. Varga
Cisco
N. Bahadur
Bracket Computing
H. Ananthakrishnan
Packet Design
October 10, 2014
A YANG Data Model for Network Topologies
draft-clemm-i2rs-yang-network-topo-01.txt
Abstract
This document defines a YANG data model for network and service
topologies.
Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
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and may be updated, replaced, or obsoleted by other documents at any
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This Internet-Draft will expire on April 13, 2015.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2
2. Definitions and Acronyms . . . . . . . . . . . . . . . . . . 4
3. Model Structure . . . . . . . . . . . . . . . . . . . . . . . 5
3.1. Main building blocks . . . . . . . . . . . . . . . . . . 5
3.2. Discussion and selected design decisions . . . . . . . . 6
3.3. Open issues and items for further discussion . . . . . . 8
4. Network Topology YANG module . . . . . . . . . . . . . . . . 9
5. Security Considerations . . . . . . . . . . . . . . . . . . . 17
6. Contributors . . . . . . . . . . . . . . . . . . . . . . . . 17
7. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 17
8. References . . . . . . . . . . . . . . . . . . . . . . . . . 17
8.1. Normative References . . . . . . . . . . . . . . . . . . 17
8.2. Informative References . . . . . . . . . . . . . . . . . 18
1. Introduction
This document introduces an abstract (basic) topology YANG [RFC6020]
[RFC6021] model, which can be augmented to cover many different
network topologies. Applications can operate on any topology at a
generic level where specifics of particular topology types are not
required, or at a topology-specific level when those specifics come
into play. Examples of specific topology types include Layer 1,
Layer 2 and Layer 3 topologies, such as unicast or multicast IGP
topologies (IS-IS [RFC1195] or OSPF [RFC2328]), traffic engineering
(TE) data [RFC3209], or any of the variety of transport and service
topologies. Information specific to particular network topology
tpyes would be captured in separate, technology-specific models. The
basic data model introduced in this document is generic in nature and
can be applied to many network topologies.
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This document introduces the network-topology YANG module, which
defines a generic topology model at its most general level of
abstraction. The module defines a topology graph and components from
which it is composed: nodes, edges and termination points. Nodes
represent graph vertices and links represent graph edges. Nodes
contain termination points that anchor the links. A network can
contain multiple topologies, for example topologies at different
layers and overlay topologies. The model therefore allows to capture
relationships between topologies, as well as dependencies between
nodes and termination points across topologies. An example of a
topology stack is shown in the following figure.
+---------------------------------------+
/ _[X1]_ "Service" /
/ _/ : \_ /
/ _/ : \_ /
/ _/ : \_ /
/ / : \ /
/ [X1]__________________[X3] /
+---------:--------------:------:-------+
: : :
+----:--------------:----:--------------+
/ : : : "L3" /
/ : : : /
/ : : : /
/ [Y1]_____________[Y2] /
/ * * * /
/ * * * /
+--------------*-------------*--*-------+
* * *
+--------*----------*----*--------------+
/ [Z1]_______________[Z1] "Optical" /
/ \_ * _/ /
/ \_ * _/ /
/ \_ * _/ /
/ \ * / /
/ [Z] /
+---------------------------------------+
The figure shows three topology levels. At top, the "Service"
topology shows relationships between service entities, such as
service functions in a service chain. The "L3" topology shows
network elements at Layer 3 (IP) and the "Optical" topology shows
network elements at Layer 1. Service functions in the "Service"
topology are mapped onto network elements in the "L3" topology, which
in turn are mapped onto network elements in the "Optical" topology.
The figure shows two Service Functions - X1 and X2 - mapping onto a
single L3 network element; this could happen, for example, if two
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service functions reside in the same VM (or server) and share the
same set of network interfaces. The figure shows a single "L3"
network element mapped onto multiple "Optical" network elements.
This could happen, for example, if a single IP router attaches to
multiple ROADMs in the optical domain.
There are multiple applications for such a data model. For example,
within the context of I2RS, nodes within the network can use the data
model to capture their understanding of the overall network topology
and expose it to a network controller. A network controller can then
use the instantiated topology data to compare and reconcile its own
view of the network topology with that of the network elements that
it controls. Alternatively, nodes within the network could propagate
this understanding to compare and reconcile this understanding either
among themselves or with help of a controller. Beyond the network
element and the immediate context of I2RS itself, a network
controller might even use the data model to represent its view of the
topology that it controls and expose it to applications north of
itself. Further use cases that the data model can be applied to are
described in [topology-use-cases].
2. Definitions and Acronyms
Datastore: A conceptual store of instantiated management information,
with individual data items represented by data nodes which are
arranged in hierarchical manner ([RFC6241]).
Data subtree: An instantiated data node and the data nodes that are
hierarchically contained within it.
HTTP: Hyper-Text Transfer Protocol
IGP: Interior Gateway Protocol
IS-IS: Intermediate System to Intermediate System protocol
NETCONF: Network Configuration Protocol
OSPF: Open Shortest Path First, a link state routing protocol
URI: Uniform Resource Identifier
ReST: Representational State Transfer, a style of stateless interface
and protocol that is generally carried over HTTP
YANG: A data definition language for NETCONF
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3. Model Structure
The structure of the network topology data model is depicted in the
following diagram. Brackets enclose list keys, "rw" means
configuration data, "ro" means operational state data, and "?"
designates optional nodes.
module: network-topology
+--rw network-topology
+--rw topology* [topology-id]
+--rw topology-id topology-id
+--ro server-provided? boolean
+--rw topology-types
+--rw supporting-topology* [topo-ref]
| +--rw topo-ref leafref
+--rw node* [node-id]
| +--rw node-id node-id
| +--rw termination-point* [tp-id]
| | +--rw tp-id tp-id
| | +--rw supporting-termin-point* [topo-ref node-ref tp-ref]
| | +--rw topo-ref leafref
| | +--rw node-ref leafref
| | +--rw tp-ref leafref
| +--rw supporting-node* [topo-ref node-ref]
| +--rw topo-ref leafref
| +--rw node-ref leafref
+--rw link* [link-id]
+--rw link-id link-id
+--rw source
| +--rw source-node leafref
| +--rw source-tp? leafref
+--rw destination
| +--rw dest-node leafref
| +--rw dest-tp? leafref
+--rw supporting-link* [topo-ref link-ref]
+--rw topo-ref leafref
+--rw link-ref leafref
3.1. Main building blocks
A network can contain multiple topologies. Each topology is captured
in its own list entry, distinguished via a topology-id. This is
captured by list "topology", contained underneath the root container
for this module, "network-topology".
A topology has a certain type, such as L2, L3, OSPF or IS-IS. A
topology can even have multiple types simultaneously. The type, or
types, are captured underneath the container "topology-types". This
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container serves as container for data nodes that represent specific
topology types. In this module it serves merely as an augmentation
target; topology-specific modules will later introduce new data nodes
to represent new topology types below this target, i.e. insert them
below "topology-types" by ways of yang augmentation.
Topology types SHOULD always be represented using presence
containers, not leafs of empty type. This allows to represent
hierarchies of topology subtypes within the instance information.
For example, an instance of an OSPF topology (which, at the same
time, is a layer 3 unicast IGP topology) would contain underneath
"topology-types" another container "l3-unicast-igp-topology", which
in turn would contain a container "ospf-topology".
A topology can in turn be part of a hierarchy of topologies, building
on top of other topologies. Any such topologies are captured in the
list "underlay-topology".
Furthermore, a topology contains nodes and links, each captured in
their own list.
A node has a node-id that distinguishes the node from other nodes in
the list. In addition, a node has a list of termination points that
are used to terminate links. An example of a termination point might
be a physical or logical port or, more generally, an interface.
Also, a node can map onto one or more other nodes in an underlay
topology. This is captured in the list "supporting-node".
A link is identified by a link-id that uniquely identifies the link
within a given topology. Links are point-to-point and
unidirectional. Accordingly, a link contains a source and a
destination. Both source and destination reference a corresponding
node, as well as a termination point on that node. Similar to a
node, a link can map onto one or more links in an underlay topology.
This is captured in the list "supporting-link".
3.2. Discussion and selected design decisions
Rather than maintaining lists in separate containers, the model is
kept relatively flat in terms of its containment structure.
Therefore, path specifiers used to refer to specific nodes, be it in
management operations or in specifications of constraints, can remain
relatively compact. Of course, this means there is no separate
structure in instance information that separates elements of
different lists from one another. Such structure is semantically not
required, although it might enhance human readability in some cases.
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To minimize assumptions of what a topology might actually represent,
mappings between topologies, nodes, links, and termination points are
kept strictly generic. For example, no assumptions are made whether
a termination point actually refers to an interface, or whether a
node refers to a specific "system" or device; the model at this
generic level makes no provisions for that. Any greater specifics
about mappings between upper and lower layers can be captured in
augmenting modules. For example, if a termination point maps to an
interface, an augmenting module can augment the termination point
with a leaf that references the corresponding interface [RFC7223].
If a node maps to a particular device or network element, an
augmenting module can augment node with a leaf that references the
network element.
The model makes use of groupings, instead of simply defining data
nodes "in-line". This allows to more easily include the
corresponding data nodes in notifications, which then do not need to
respecify each data node that is to be included. The tradeoff for
this is that it makes the specification of constraints more complex,
because constraints involving data nodes outside the grouping need to
be specified in conjunction with a "uses" statement where the
grouping is applied. This also means that constraints and XPath-
statements need to specified in such a way that the navigate "down"
first and select entire sets of nodes, as opposed to being able to
simply specify them against individual data nodes.
The topology model includes links that are point-to-point and
unidirectional. It does not directly support multipoint and
bidirectional links. While this may appear as a limitation, it does
keep the model simple, generic, and allows it to very easily be
subjected applications that make use of graph algorithms. Bi-
directional connections can be represented through pairs of
unidirectional links. Multipoint networks can be represented through
pseudo-nodes (similar to IS-IS, for example). By introducing
hierarchies of nodes, with nodes at one level mapping onto a set of
other nodes at another level, and the introducing new links for nodes
at that level, topologies with connections representing non-point-to-
point communication patterns can be represented.
Links are terminated by a single termination point, not sets of
termination points. Connections involving multihoming or link
aggregation schemes need to be represented using multiple point-to-
point links, then defining a link at a higher layer that is supported
by those individual links.
In a hierarchy of topologies, there are nodes mapping to nodes, links
mapping to links, and termination points mapping to termination
points. Some of this information is redundant. Specifically, with
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the link-to-links mapping known, and the termination points of each
link known, maintaining separate termination point mapping
information is not needed but can be derived via transitive closure.
The model does provide for the option to include this information
explicitly, but does not allow for it to be configured to avoid the
potential to introduce (and having to validate) corresponding
integrity issues.
A topology's topology types are represented using a container which
contains a data node for each of its topology types. A topology can
encompass several types of topology simultaneously, hence a container
is used instead of a case construct, with each topology type in turn
represented by a dedicated presence container itself. The reason for
not simply using an empty leaf, or even simpler, do away even with
the topology container and just use a leaf-list of topology-type
instead, is to be able to represent "class hierarchies" of topology
types, with one topology type refining the other. Topology-type
specific containers are to be defined in the topology-specific
modules, augmenting the topology-types container.
3.3. Open issues and items for further discussion
YANG requires data needs to be designated as either configuration or
operational data, but not both, yet it is important to have all
topology information, including vertical cross-topology dependencies,
captured in one coherent model. In most cases topology information
is discovered about a network; the topology is considered a property
of the network that is reflected in the model. That said, it is
conceivable that certain types of topology need to also be
configurable by an application.
There are several alternatives in which this can be addressed. The
alternative chosen in this draft does not restrict topology
information as read-only, but includes a flag that indicates for each
topology whether it should be considered as read-only or configurable
by applications.
An alternative would be to designate topology list elements as read
only. The read-only topology list includes each topology; it is the
complete reference. In parallel a second topology list is
introduced. This list serves the purpose of being able to configure
topologies which are then mirrored in the read-only list. The
configurable topology list adheres to the same structure and uses the
same groupings as its read-only counterpart. As most data is defined
in those groupings, the amount of additional definitions required
will be limited. A configurable topology will thus be represented
twice: once in the read-only list of all topologies, a second time in
a configuration sandbox.
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4. Network Topology YANG module
<CODE BEGINS> file "network-topology.yang"
module network-topology {
yang-version 1;
namespace "urn:TBD:params:xml:ns:yang:network-topology";
prefix nt;
import ietf-inet-types {
prefix inet;
}
organization "TBD";
contact
"WILL-BE-DEFINED-LATER";
description
"This module defines a model for the topology of a network.
Key design decisions are as follows:
A topology consists of a set of nodes and links.
Links are point-to-point and unidirectional.
Bidirectional connections need to be represented through
two separate links.
Multipoint connections, broadcast domains etc can be represented
through a hierarchy of nodes, then connecting nodes at
upper layers of the hierarchy.";
revision 2014-10-11 {
description
"Initial revision.";
reference "draft-clemm-i2rs-yang-network-topo-01";
}
typedef topology-id {
type inet:uri;
description
"An identifier for a topology.";
}
typedef node-id {
type inet:uri;
description
"An identifier for a node in a topology.
The identifier may be opaque.
The identifier SHOULD be chosen such that the same node in a
real network topology will always be identified through the
same identifier, even if the model is instantiated in separate
datastores. An implementation MAY choose to capture semantics
in the identifier, for example to indicate the type of node
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and/or the type of topology that the node is a part of.";
}
typedef link-id {
type inet:uri;
description
"An identifier for a link in a topology.
The identifier may be opaque.
The identifier SHOULD be chosen such that the same link in a
real network topology will always be identified through the
same identifier, even if the model is instantiated in separate
datastores. An implementation MAY choose to capture semantics
in the identifier, for example to indicate the type of link
and/or the type of topology that the link is a part of.";
}
typedef tp-id {
type inet:uri;
description
"An identifier for termination points on a node.
The identifier may be opaque.
The identifier SHOULD be chosen such that the same TP in a
real network topology will always be identified through the
same identifier, even if the model is instantiated in separate
datastores. An implementation MAY choose to capture semantics
in the identifier, for example to indicate the type of TP
and/or the type of node and topology that the TP is a part
of.";
}
grouping topo-ref {
leaf topo-ref {
type leafref {
path "/network-topology/topology/topology-id";
}
}
}
grouping link-ref {
description
"A type for an absolute reference a link instance.
(This type should not be used for relative references.
In such a case, a relative path should be used instead.)";
uses topo-ref;
leaf link-ref {
type leafref {
path "/network-topology/topology[topology-id=current()" +
"/..\/topo-ref]/link/link-id";
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}
}
}
grouping node-ref {
uses topo-ref;
leaf node-ref {
type leafref {
path "/network-topology/topology[topology-id=current()" +
"/../topo-ref]/node/node-id";
}
}
}
grouping tp-ref {
description
"A type for an absolute reference to a termination point.
(This type should not be used for relative references.
In such a case, a relative path should be used instead.)";
uses node-ref;
leaf tp-ref {
type leafref {
path "/network-topology/topology[topology-id=current()" +
"/../topo-ref]/node[node-id=current()/../node-ref]" +
"/termination-point/tp-id";
}
}
}
container network-topology {
description
"This container acts as the top-level data element of this
model.";
list topology {
key "topology-id";
description
"This is the model of an abstract topology. A topology
contains nodes and links. Each topology MUST be identified
by a unique topology-id for reason that a network could
contain many topologies.";
leaf topology-id {
type topology-id;
description
"It is presumed that a datastore will contain many
topologies. To distinguish between topologies it is
vital to have UNIQUE topology identifiers.";
}
leaf server-provided {
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type boolean;
config false;
description
"Indicates whether the topology is configurable by clients,
or whether it is provided by the server. This leaf is
populated by the server implementing the model.
It is set to false for topologies that are created by a
client; it is set to true otherwise. If it is set to true,
any attempt to edit the topology MUST be rejected.";
}
container topology-types {
description
"This container is used to identify the type, or types (as
a topology can support several types simultaneously), of
the topology.
Topology types are the subject of several integrity
constraints that an implementing server can validate in
order to maintain integrity of the datastore.
Topology types are indicated through separate data nodes;
the set of topology types is expected to increase over
time.
To add support for a new topology, an augmenting module
needs to augment this container with a new empty optional
container to indicate the new topology type.
The use of a container allows to indicate a
subcategorization of topology types.
The container SHALL NOT be augmented with any data nodes
that serve a purpose other than identifying a particular
topology type.";
}
list supporting-topology {
key "topo-ref";
leaf topo-ref {
type leafref {
path "/network-topology/topology/topology-id";
}
description
"This leaf identifies a topology which is forms a part
of this topology's underlay. Reference loops, where
a topology identifies itself as its underlay, either
directly or transitively, are not allowed.";
}
description
"Identifies the topology, or topologies, that this topology
is dependent on.";
}
list node {
key "node-id";
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leaf node-id {
type node-id;
description
"The identifier of a node in the topology.
A node is specific to a topology to which it belongs.";
}
description
"The list of network nodes defined for the topology.";
list termination-point {
key "tp-id";
description
"A termination point can terminate a link.
Depending on the type of topology, a termination point
could, for example, refer to a port or an interface.";
leaf tp-id {
type tp-id;
description
"Termination point identifier.";
}
list supporting-termination-point {
key "topo-ref node-ref tp-ref";
description
"The leaf list identifies any termination points that
the termination point is dependent on, or maps onto.
Those termination points will themselves be contained
in a supporting node.
This dependency information can be inferred from
the dependencies between links. For this reason,
this item is not separately configurable. Hence no
corresponding constraint needs to be articulated.
The corresponding information is simply provided by the
implementing system.";
leaf topo-ref {
type leafref {
path "../../../supporting-node/topo-ref";
}
description
"This leaf identifies in which topology the
supporting termination point is present.";
}
leaf node-ref {
type leafref {
path "../../../supporting-node/node-ref";
}
description
"This leaf identifies in which node the supporting
termination point is present.";
}
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leaf tp-ref {
type leafref {
path "/network-topology/topology[topology-id=current()"+
"/../topo-ref]/node[node-id=current()" +
"/../node-ref]/termination-point/tp-id";
}
description
"Reference to the underlay node, must be in a
different topology";
}
}
}
list supporting-node {
key "topo-ref node-ref";
description
"This list defines vertical layering information for
nodes.
It allows to capture for any given node, which node (or
nodes) in the corresponding underlay topology it maps
onto.
A node can map to zero, one, or more nodes below it;
accordingly there can be zero, one, or more elements in
the list.
If there are specific layering requirements, for example
specific to a particular type of topology that only
allows for certain layering relationships, the choice
below can be augmented with additional cases.
A list has been chosen rather than a leaf-list in order
to provide room for augmentations, e.g. for
statistics or priorization information associated with
supporting nodes.";
leaf topo-ref {
type leafref {
path "../../../supporting-topology/topo-ref";
}
description
"This leaf identifies in which underlay topology
supporting node is present.";
}
leaf node-ref {
type leafref {
path "/network-topology/topology[topology-id=current()" +
"/../topo-ref]/node/node-id";
}
description
"Reference to the underlay node, must be in a
different topology";
}
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}
}
list link {
key "link-id";
leaf link-id {
type link-id;
description
"The identifier of a link in the topology.
A link is specific to a topology to which it belongs.";
}
description
"A Network Link connects a by Local (Source) node and
a Remote (Destination) Network Nodes via a set of the
nodes' termination points.
As it is possible to have several links between the same
source and destination nodes, and as a link could
potentially be re-homed between termination points, to
ensure that we would always know to distinguish between
links, every link is identified by a dedicated link
identifier.
Note that a link models a point-to-point link, not a
multipoint link.
Layering dependencies on links in underlay topologies are
not represented as the layering information of nodes and of
termination points is sufficient.";
container source {
description
"This container holds the logical source of a particular
link.";
leaf source-node {
type leafref {
path "../../../node/node-id";
}
mandatory true;
description
"Source node identifier, must be in same topology.";
}
leaf source-tp {
type leafref {
path "../../../node[node-id=current()/../source-node]" +
"/termination-point/tp-id";
}
description
"Termination point within source node that terminates
the link.";
}
}
container destination {
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description
"This container holds the logical destination of a
particular link.";
leaf dest-node {
type leafref {
path "../../../node/node-id";
}
mandatory true;
description
"Destination node identifier, must be in the same
topology.";
}
leaf dest-tp {
type leafref {
path "../../../node[node-id=current()/../dest-node]" +
"/termination-point/tp-id";
}
description
"Termination point within destination node that
terminates the link.";
}
}
list supporting-link {
key "topo-ref link-ref";
description
"Identifies the link, or links, that this link
is dependent on.";
leaf topo-ref {
type leafref {
path "../../../supporting-topology/topo-ref";
}
description
"This leaf identifies in which underlay topology
supporting link is present.";
}
leaf link-ref {
type leafref {
path "/network-topology/topology[topology-id=current()" +
"/../topo-ref]/link/link-id";
}
description
"This leaf identifies a link which is forms a part
of this link's underlay. Reference loops, where
a link identifies itself as its underlay, either
directly or transitively, are not allowed.";
}
}
}
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}
}
}
<CODE ENDS>
5. Security Considerations
The transport protocol used for sending the topology data MUST
support authentication and SHOULD support encryption. The data-model
by itself does not create any security implications.
6. Contributors
The model presented in this paper was contributed to by more people
than can be listed on the author list. Additional contributors
include:
o Ken Gray, Cisco Systems
o Tom Nadeau, Brocade
o Aleksandr Zhdankin, Cisco
7. Acknowledgements
We wish to acknowledge the helpful contributions, comments, and
suggestions that were received from Martin Bjorklund, Ladislav
Lhotka, Andy Bierman, Carlos Pignataro, Juergen Schoenwaelder, Alia
Atlas and Benoit Claise.
8. References
8.1. Normative References
[RFC1195] Callon, R., "Use of OSI IS-IS for routing in TCP/IP and
dual environments", RFC 1195, December 1990.
[RFC2328] Moy, J., "OSPF Version 2", STD 54, RFC 2328, April 1998.
[RFC3209] Awduche, D., Berger, L., Gan, D., Li, T., Srinivasan, V.,
and G. Swallow, "RSVP-TE: Extensions to RSVP for LSP
Tunnels", RFC 3209, December 2001.
[RFC6020] Bjorklund, M., "YANG - A Data Modeling Language for the
Network Configuration Protocol (NETCONF)", RFC 6020,
October 2010.
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[RFC6021] Schoenwaelder, J., "Common YANG Data Types", RFC 6021,
October 2010.
[RFC6241] Enns, R., Bjorklund, M., Schoenwaelder, J., and A.
Bierman, "Network Configuration Protocol (NETCONF)", RFC
6241, June 2011.
8.2. Informative References
[I-D.ietf-netconf-restconf]
Bierman, A., Bjorklund, M., and K. Watsen, "RESTCONF
Protocol", draft-ietf-netconf-restconf-02 (work in
progress), October 2014.
[I-D.ietf-netmod-yang-json]
Lhotka, L., "JSON Encoding of Data Modeled with YANG",
draft-ietf-netmod-yang-json-00 (work in progress), April
2014.
[RFC7223] Bjorklund, M., "A YANG Data Model for Interface
Management", RFC 7223, May 2014.
[topology-use-cases]
Medved, J., Previdi, S., Lopez, V., and S. Amante,
"Topology API Use Cases", I-D draft-amante-i2rs-topology-
use-cases-01, October 2013.
Authors' Addresses
Alexander Clemm
Cisco
EMail: alex@cisco.com
Jan Medved
Cisco
EMail: jmedved@cisco.com
Tony Tkacik
Cisco
EMail: ttkacik@cisco.com
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Robert Varga
Cisco
EMail: rovarga@cisco.com
Nitin Bahadur
Bracket Computing
EMail: nitin_bahadur@yahoo.com
Hariharan Ananthakrishnan
Packet Design
EMail: hanantha@juniper.net
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