Internet Engineering Task Force R. Wilton, Ed.
Internet-Draft D. Ball
Intended status: Standards Track Cisco Systems
Expires: April 21, 2016 T. Singh
S. Sivaraj
Juniper Networks
October 19, 2015
Common Interface Extension YANG Data Models
draft-wilton-netmod-intf-ext-yang-01
Abstract
This document defines two YANG modules that augment the Interfaces
data model defined in the "YANG Data Model for Interface Management"
with additional configuration and operational data nodes to support
common lower layer interface properties, such as interface MTU.
These properties are common to many types of interfaces on network
routers and switches and are implemented by multiple network
equipment vendors with similar semantics, even though some of the
features are not formally defined in any published standard.
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
working documents as Internet-Drafts. The list of current Internet-
Drafts is at http://datatracker.ietf.org/drafts/current/.
Internet-Drafts are draft documents valid for a maximum of six months
and may be updated, replaced, or obsoleted by other documents at any
time. It is inappropriate to use Internet-Drafts as reference
material or to cite them other than as "work in progress."
This Internet-Draft will expire on April 21, 2016.
Copyright Notice
Copyright (c) 2015 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
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publication of this document. Please review these documents
carefully, as they describe your rights and restrictions with respect
to this document. Code Components extracted from this document must
include Simplified BSD License text as described in Section 4.e of
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described in the Simplified BSD License.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2
1.1. Terminology . . . . . . . . . . . . . . . . . . . . . . . 3
1.2. Tree Diagrams . . . . . . . . . . . . . . . . . . . . . . 3
2. Objectives . . . . . . . . . . . . . . . . . . . . . . . . . 4
3. Interfaces Extensions Module . . . . . . . . . . . . . . . . 4
3.1. Bandwidth . . . . . . . . . . . . . . . . . . . . . . . . 5
3.2. Carrier Delay . . . . . . . . . . . . . . . . . . . . . . 6
3.3. Dampening . . . . . . . . . . . . . . . . . . . . . . . . 7
3.3.1. Suppress Threshold . . . . . . . . . . . . . . . . . 7
3.3.2. Half-Life Period . . . . . . . . . . . . . . . . . . 8
3.3.3. Reuse Threshold . . . . . . . . . . . . . . . . . . . 8
3.3.4. Maximum Suppress Time . . . . . . . . . . . . . . . . 8
3.4. Encapsulation . . . . . . . . . . . . . . . . . . . . . . 8
3.5. Loopback . . . . . . . . . . . . . . . . . . . . . . . . 8
3.6. MTU . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
3.7. Sub-interface . . . . . . . . . . . . . . . . . . . . . . 9
3.8. Transport Layer . . . . . . . . . . . . . . . . . . . . . 10
4. Interfaces Ethernet-Like Module . . . . . . . . . . . . . . . 10
5. Interfaces Common YANG Module . . . . . . . . . . . . . . . . 10
6. Interfaces Ethernet-Like YANG Module . . . . . . . . . . . . 19
7. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 21
8. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 21
9. Security Considerations . . . . . . . . . . . . . . . . . . . 22
9.1. interfaces-common.yang . . . . . . . . . . . . . . . . . 22
9.2. interfaces-ethernet-like.yang . . . . . . . . . . . . . . 23
10. References . . . . . . . . . . . . . . . . . . . . . . . . . 23
10.1. Normative References . . . . . . . . . . . . . . . . . . 24
10.2. Informative References . . . . . . . . . . . . . . . . . 24
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 24
1. Introduction
This document defines two YANG RFC 6020 [RFC6020] modules for the
management of network interfaces. It defines various augmentations
to the generic interfaces data model defined in RFC 7223 [RFC7223] to
support configuration of lower layer interface properties that are
common across many types of network interface.
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One of the aims of this draft is to provide a standard namespace and
path for these configuration items regardless of the underlying
interface type. For example a standard namespace and path for
configuring or reading the MAC address associated with an interface
is provided that can be used for any interface type that uses
Ethernet framing.
Several of the augmentations defined here are not backed by any
formal standard specification. Instead, they are for features that
are commonly implemented in equivalent ways by multiple independent
network equipment vendors. The aim of this draft is to define common
paths and leaves for the configuration of these equivalent features
in a uniform way, making it easier for users of the YANG model to
access these features in a vendor independent way. Where necessary,
a description of the expected behavior is also provided with the aim
of ensuring vendors implementations are consistent with the specified
behaviour.
Given that the modules contain a collection of discrete features with
the common theme that they generically apply to interfaces, it is
plausible that not all implementors of the YANG module will decide to
support all features. Hence separate feature keywords are defined
for each logically discrete feature to allow implementors the
flexibility to choose which specific parts of the model they support.
The augmentations are split into two separate YANG modules that each
focus on a particular area of functionality. The two YANG modules
defined in this internet draft are:
interface-extensions.yang - Defines extensions to the IETF
interface data model to support common configuration data nodes.
etherlike-interfaces.yang - Defines a module for any configuration
and operational data nodes that are common across interfaces that
use Ethernet framing.
1.1. Terminology
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 RFC 2119 [RFC2119].
1.2. Tree Diagrams
A simplified graphical representation of the data model is used in
this document. The meaning of the symbols in these diagrams is as
follows:
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o Brackets "[" and "]" enclose list keys.
o Abbreviations before data node names: "rw" means configuration
(read-write), and "ro" means state data (read-only).
o Symbols after data node names: "?" means an optional node, "!"
means a presence container, 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.
2. Objectives
The aim of of the YANG modules contained in this draft is to provide
standard definitions for common interface based configuration on
network devices.
The expectation is that the YANG leaves that are being defined are
fairly widely implemented by network vendors. However, the features
described here are mostly not backed by formal standards because they
are fairly basic in their behavior and do not need to interoperate
with other devices. Where required a concise explanation of the
expected behavior is also provided to ensure consistency between
vendors.
3. Interfaces Extensions Module
The Interfaces Common module provides some basic extensions to the
IETF interfaces YANG module.
The module provides:
o A bandwidth configuration leaf to specify the bandwidth available
on an interface to control routing metrics.
o A carrier delay feature used to provide control over short lived
link state flaps.
o An interface link state dampening feature that is used to provide
control over longer lived link state flaps.
o An encapsulation container and extensible choice statement for use
by any interface types that allow for configurable L2
encapsulations.
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o A loopback configuration leaf that is primarily aimed at loopback
at the physical layer.
o MTU configuration leaves applicable to all packet/frame based
interfaces.
o A transport layer leaf to indicate whether the interface handles
traffic at L1, L2 or L3.
o A parent interface leaf useable for all types of sub-interface
that are children of parent interfaces.
The "interface-extensions" YANG module has the following structure:
module: interfaces-common
augment /if:interfaces/if:interface:
+--rw bandwidth? uint64
augment /if:interfaces/if:interface:
+--rw carrier-delay
+--rw down? uint32
+--rw up? uint32
augment /if:interfaces/if:interface:
+--rw dampening!
+--rw half-life? uint32
+--rw reuse? uint32
+--rw suppress? uint32
+--rw max-suppress-time? uint32
augment /if:interfaces/if:interface:
+--rw encapsulation
+--rw (encaps-type)?
augment /if:interfaces/if:interface:
+--rw loopback? identityref
augment /if:interfaces/if:interface:
+--rw l2-mtu? uint16 {configurable-l2-mtu}?
augment /if:interfaces/if:interface:
+--rw parent-interface? if:interface-ref
augment /if:interfaces/if:interface:
+--rw transport-layer? enumeration
3.1. Bandwidth
The bandwidth configuration leaf allows the specified bandwidth of an
interface to be reduced from the inherent interface bandwidth. The
bandwidth leaf affects the routing metric cost associated with the
interface.
Note that the bandwidth leaf does not actually limit the amount of
traffic that can be sent/received over the interface. If required,
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interface traffic can be limited to the required bandwidth by
configuring an explicit QoS policy.
Note for reviewers: Given that the bandwidth only controls routing
metrics, it may be more appropriate for this leaf, or an equivalent,
to be defined as part of one of the routing YANG modules. Although
conversely, it is also worth considering that the corresponding
existing CLI configuration command is an interface level bandwidth
command in many implementations.
3.2. Carrier Delay
The carrier delay feature augments the IETF interfaces data model
with configuration for a simple algorithm that is used, generally on
physical interfaces, to suppress short transient changes in the
interface link state. It can be used in conjunction with the
dampening feature described in Section 3.3 to provide effective
control of unstable links and unwanted state transitions.
The principal of the carrier delay feature is to use a short per
interface timer to ensure that any interface link state transition
that occurs and reverts back within the specified time interval is
entirely suppressed without providing any signalling to any upper
layer protocols that the state transition has occurred. E.g. in the
case that the link state transition is suppressed then there is no
change of the /if:interfaces-state/if:interface/oper-status or
/if:interfaces-state/if:interfaces/last-change leaves for the
interface that the feature is operating on. One obvious side effect
of using this feature that is worth noting is that any state
transition will always be delayed by the specified time interval.
The configuration allows for separate timer values to be used in the
suppression of down->up->down link transitions vs up->down->up link
transitions.
The carrier delay down timer leaf specifies the amount of time that
an interface that is currently in link up state must be continuously
down before the down state change is reported to higher level
protocols. Use of this timer can cause traffic to be black holed for
the configured value and delay reconvergence after link failures,
therefore its use is normally restricted to cases where it is
necessary to allow enough time for another protection mechanism (such
as an optical layer automatic protection system) to take effect.
The carrier delay up timer leaf specifies the amount of time that an
interface that is currently in link down state must be continuously
up before the down->up link state transition is reported to higher
level protocols. This timer is generally useful as a debounce
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mechanism to ensure that a link is relatively stable before being
brought into service. It can also be used effectively to limit the
frequency at which link state transition events can occur. The
default value for this leaf is determined by the underlying network
device.
3.3. Dampening
The dampening feature introduces a configurable exponential decay
mechanism to suppress the effects of excessive interface link state
flapping. This feature allows the network operator to configure a
device to automatically identify and selectively dampen a local
interface which is flapping. Dampening an interface keeps the
interface operationally down until the interface stops flapping and
becomes stable. Configuring the dampening feature can improve
convergence times and stability throughout the network by isolating
failures so that disturbances are not propagated, which reduces the
utilization of system processing resources by other devices in the
network and improves overall network stability.
The basic algorithm uses a counter that is nominally increased by
1000 units every time the underlying interface link state changes
from up to down. If the counter increases above the suppress
threshold then the interface is kept down (and out of service) until
either the maximum suppression time is reached, or the counter has
reduced below the reuse threshold. The half-life period determines
that rate at which the counter is periodically reduced.
Implementations are not required to use a penalty of 1000 units in
their dampening algorithm, but should ensure that the Suppress
Threshold and Reuse Threshold values are scaled relative to the
nominal 1000 unit penalty to ensure that the same configuration
values provide consistent behaviour. The configurable values are
described in more detail below.
3.3.1. Suppress Threshold
The suppress threshold is the value of the accumulated penalty that
triggers the device to dampen a flapping interface. The flapping
interface is identified by the device and assigned a penalty for each
up to down link state change, but the interface is not automatically
dampened. The device tracks the penalties that a flapping interface
accumulates. When the accumulated penalty reaches the default or
configured suppress threshold, the interface is placed in a dampened
state.
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3.3.2. Half-Life Period
The half-life period determines how fast the accumulated penalties
can decay exponentially. Any penalties that have been accumulated on
a flapping interface are reduced by half after each half-life period.
3.3.3. Reuse Threshold
If, after one or more half-life periods, the accumulated penalty
decreases below the reuse threshold and the underlying interface link
state is up then the interface is taken out of dampened state and
allowed to go up.
3.3.4. Maximum Suppress Time
The maximum suppress time represents the maximum amount of time an
interface can remain dampened when a penalty is assigned to an
interface. The default of the maximum suppress timer is four times
the half-life period. The maximum value of the accumulated penalty
is calculated using the maximum suppress time, reuse threshold and
half-life period.
3.4. Encapsulation
The encapsulation container holds a choice node that is to be
augmented with datalink layer specific encapsulations, such as HDLC,
PPP, or sub-interface 802.1Q tag match encapsulations. It ensures
that an interface can only have a single datalink layer protocol
configured.
3.5. Loopback
The loopback configuration leaf allows any physical interface to be
configured to be in one of the possible following physical loopback
modes, i.e. internal loopback, line loopback, or use of an external
loopback connector. The use of YANG identities allows for the model
to be extended with other modes of loopback if required.
3.6. MTU
Two MTU configuration leaves are provided to program the layer 2
interface in two different ways. Different mechanisms are provided
to reflect the fact that devices handle their MTU configuration in
different ways. A given device would only normally be expected to
support MTU configuration using one of these mechanisms.
The preferable way to configure MTU is using the l2-mtu leaf that
specifies the maximum size of a layer 2 frame including header and
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payload, but excluding any frame checksum (FCS) bytes. The payload
MTU available to higher layer protocols is calculated from the l2-mtu
after taking the layer 2 header size into account.
For Ethernet interfaces carrying 802.1Q VLAN tagged frames, the
l2-mtu excludes the 4-8 byte overhead of any known (e.g. explicitly
matched by a child sub-interface) 801.1Q VLAN tags.
The alternative way to configure MTU is using the l3-mtu leaf that
specifies the maximum size of payload carried by a layer 2 frame.
The maximum size of the layer 2 frame can then be derived by adding
on the size of the layer 2 header overheads.
Note for reviewers: Is it correct/beneficial to support l3-mtu? It
would be easier for clients if they only had a single MTU that they
could configure. Can all devices sensibly handle an l2-mtu
configuration leaf?
3.7. Sub-interface
The sub-interface feature specifies the minimal leaves required to
define a child interface that is parented to another interface.
A sub-interface is a logical interface that handles a subset of the
traffic on the parent interface. Separate configuration leaves are
used to classify the subset of ingress traffic received on the parent
interface to be processed in the context of a given sub-interface.
All egress traffic processed on a sub-interface is given to the
parent interface for transmission. Otherwise, a sub-interface is
like any other interface in /if:interfaces and supports the standard
interface features and configuration.
For some vendor specific interface naming conventions the name of the
child interface is sufficient to determine the parent interface,
which implies that the child interface can never be reparented to a
different parent interface after it has been created without deleting
the existing the sub-interface and recreating a new sub-interface.
Even in this case it is useful to have a well defined leaf to cleanly
identify the parent interface.
The model also allows for arbitrarily named sub-interfaces by having
an explicit parent-interface leaf define the child -> parent
relationship. In this naming scenario it is also possible for
implementations to allow for logical interfaces to be reparented to
new parent interfaces without needing the sub-interface to be
destroyed and recreated.
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3.8. Transport Layer
The transport layer leaf provides additional information as to which
layer an interface is logically operating and forwarding traffic at.
The implication of this leaf is that for traffic forwarded at a given
layer that any headers for lower layers are stripped off before the
packet is forwarded at the given layer. Conversely, on egress any
lower layer headers must be added to the packet before it is
transmitted out of the interface.
This leaf can also be used as a simple mechanism to determine whether
particular types of configuration are valid. E.g. a layer 2 QoS
policy could ensure that it is only applied to a interface running at
transport layer 2.
4. Interfaces Ethernet-Like Module
The Interfaces Ethernet-Like Module is a small module that contains
all configuration and operational data that is common across
interface types that use Ethernet framing as their datalink layer
encapsulation.
This module currently contains leaves for the configuration and
reporting of the operational MAC address and the burnt-in MAC address
(BIA) associated with any interface using Ethernet framing.
The "interfaces-ethernet-like" YANG module has the following
structure:
module: interfaces-ethernet-like
augment /if:interfaces/if:interface:
+--rw ethernet-like
+--rw mac-address? yang:mac-address
augment /if:interfaces-state/if:interface:
+--ro ethernet-like
+--ro mac-address? yang:mac-address
+--ro bia-mac-address? yang:mac-address
5. Interfaces Common YANG Module
This YANG module augments the interface container defined in RFC 7223
[RFC7223].
<CODE BEGINS> file "interfaces-common@2015-10-19.yang"
module interfaces-common {
yang-version 1.1;
namespace "urn:ietf:params:xml:ns:yang:interfaces-common";
prefix if-cmn;
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import ietf-interfaces {
prefix if;
}
import iana-if-type {
prefix ianaift;
}
organization
"Cisco Systems, Inc.
Customer Service
Postal: 170 W Tasman Drive
San Jose, CA 95134
Tel: +1 1800 553-NETS
E-mail: cs-yang@cisco.com";
contact
"Robert Wilton - rwilton@cisco.com";
description
"This module contains common definitions for extending the IETF
interface YANG model (RFC 7223) with common configurable layer 2
properties.";
revision 2015-10-19 {
description
"Add support for various common interface configuration
parameters that are likely to be widely implemented by various
network device vendors.";
reference "Internet draft: draft-wilton-netmod-intf-ext-yang-01";
}
feature bandwidth {
description
"This feature indicates that the device supports configurable
interface bandwidth.";
reference "Section 3.1 Bandwidth";
}
feature carrier-delay {
description
"This feature indicates that configurable interface
carrier delay is supported, which is a feature is used to
limit the propagation of very short interface link state
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flaps.";
reference "Section 3.2 Carrier Delay";
}
feature dampening {
description
"This feature indicates that the device supports interface
dampening, which is a feature that is used to limit the
propagation of interface link state flaps over longer
periods";
reference "Section 3.3 Dampening";
}
feature loopback {
description
"This feature indicates that configurable interface loopback
is supported.";
reference "Section 3.5 Loopback";
}
feature configurable-l2-mtu {
description
"This feature indicates that the device supports configuring
layer 2 MTUs on interfaces. Such MTU configurations include
the layer 2 header overheads (but exclude any FCS overhead).
The payload MTU available to higher layer protocols is either
derived from the layer 2 MTU, taking into account the size of
the layer 2 header, or is further restricted by explicit layer
3 or protocol specific MTU configuration.";
reference "Section 3.6 MTU";
}
feature sub-interfaces {
description
"This feature indicates that the device supports the
instantiation of sub-interfaces. Sub-interfaces are defined
as logical child interfaces that allow features and forwarding
decisions to be applied to a subset of the traffic processed
on the specified parent interface.";
reference "Section 3.7 Sub-interface";
}
feature transport-layer {
description
"This feature indicates that the device supports configurable
transport layer.";
reference "Section 3.8 Transport Layer";
}
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/*
* Define common identities to help allow interface types to be
* assigned properties.
*/
identity sub-interface {
description "Base type for generic sub-interfaces. New or custom
interface types can derive from this type to
inherit generic sub-interface configuration";
}
identity ethSubInterface{
base ianaift:l2vlan;
base sub-interface;
description "Sub-interface of any interface types that uses
Ethernet framing (with or without 802.1Q tagging)";
}
identity loopback {
description "Base type for interface loopback options";
}
identity loopback-internal {
base loopback;
description "All egress traffic on the interface is internally
looped back within the interface to be received on
the ingress path.";
}
identity loopback-line {
base loopback;
description "All ingress traffic received on the interface is
internally looped back within the interface to the
egress path.";
}
identity loopback-connector {
base loopback;
description "The interface has a physical loopback connector
attached to that loops all egress traffic back into
the interface's ingress path, with equivalent
semantics to loopback-internal";
}
/*
* Augments the IETF interfaces model with a leaf to explicitly
* specify the bandwidth available on an interface.
*/
augment "/if:interfaces/if:interface" {
if-feature "bandwidth";
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description "Add a top level node for interface bandwidth.";
leaf bandwidth {
type uint64;
units kbps;
description
"The bandwidth available on the interface in Kb/s. This
configuration is used by routing protocols to adjust the
metrics associated with the interface, but does not limit
the amount of traffic that can be sent or received on the
interface. A separate QoS policy would need to be configured
to limit the ingress or egress traffic. If not configured,
the default bandwidth is the maximum available bandwidth of
the underlying interface.";
}
}
/*
* Defines standard YANG for the Carrier Delay feature.
*/
augment "/if:interfaces/if:interface" {
if-feature "carrier-delay";
description "Augments the IETF interface model with
carrier delay configuration for interfaces that
support it.";
container carrier-delay {
description "Holds carrier delay related feature
configuration";
leaf down {
type uint32;
units milliseconds;
description
"Delays the propagation of a 'loss of carrier signal' event
that would cause the interface state to go down, i.e. the
command allows short link flaps to be suppressed. The
configured value indicates the minimum time interval (in
milliseconds) that the carrier signal must be continuously
down before the interface state is brought down. If not
configured, the behaviour on loss of carrier signal is
vendor/interface specific, but with the general
expectation that there should be little or no delay.";
}
leaf up {
type uint32;
units milliseconds;
description
"Defines the minimum time interval (in milliseconds) that
the carrier signal must be continuously present and
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error free before the interface state is allowed to
transition from down to up. If not configured, the
behaviour is vendor/interface specific, but with the
general expectation that sufficient default delay
should be used to ensure that the interface is stable
when enabled before being reported as being up.
Configured values that are too low for the hardware
capabilties may be rejected.";
}
}
}
/*
* Augments the IETF interfaces model with a container to hold
* generic interface dampening
*/
augment "/if:interfaces/if:interface" {
if-feature "dampening";
description
"Add a container for interface dampening configuration";
container dampening {
presence "Enable interface link flap dampening with default
settings (that are vendor/device specific)";
description "Interface dampening limits the propagation of
interface link state flaps over longer periods";
leaf half-life {
type uint32;
units seconds;
description
"The Time (in seconds) after which a penalty reaches half
its original value. Once the interface has been assigned
a penalty, the penalty is decreased by half after the
half-life period. For some devices, the allowed values may
be restricted to particular multiples of seconds. The
default value is vendor/device specific.";
}
leaf reuse {
type uint32;
description
"Penalty value below which a stable interface is
unsuppressed (i.e. brought up) (no units). The default
value is vendor/device specific. The penalty value for a
link up->down state change is nominally 1000 units.";
}
leaf suppress {
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type uint32;
description
"Limit at which an interface is suppressed (i.e. held down)
when its penalty exceeds that limit (no units). The value
must be greater than the reuse threshold. The default
value is vendor/device specific. The penalty value for a
link up->down state change is nominally 1000 units.";
}
leaf max-suppress-time {
type uint32;
units seconds;
description
"Maximum time (in seconds) that an interface can be
suppressed. This value effectively acts as a ceiling that
the penalty value cannot exceed. The default value is
vendor/device specific.";
}
}
}
/*
* Various types of interfaces support a configurable layer 2
* encapsulation, any that are supported by YANG should be
* listed here.
*
* Different encapsulations can hook into the common encaps-type
* choice statement.
*/
augment "/if:interfaces/if:interface" {
when "if:type = 'ianaift:ethernetCsmacd' or
if:type = 'ianaift:ieee8023adLag' or
if:type = 'ethSubInterface' or
if:type = 'ianaift:pos' or
if:type = 'ianaift:atmSubInterface'" {
description "All interface types that can have a configurable
L2 encapsulation";
/*
* TODO - Should we introduce an abstract type to make this
* extensible to new interface types, or vendor specific
* interface types?
*/
}
description "Add encapsulation top level node to interface types
that support a configurable L2 encapsulation";
container encapsulation {
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description
"Holds the L2 encapsulation associated with an interface";
choice encaps-type {
description "Extensible choice of L2 encapsulations";
}
}
}
/*
* Various types of interfaces support loopback configuration, any
* that are supported by YANG should be listed here.
*/
augment "/if:interfaces/if:interface" {
when "if:type = 'ianaift:ethernetCsmacd' or
if:type = 'ianaift:sonet' or
if:type = 'ianaift:atm' or
if:type = 'ianaift:otnOtu'" {
description
"All interface types that support loopback configuration.";
}
if-feature "loopback";
description "Augments the IETF interface model with loopback
configuration for interfaces that support it.";
leaf loopback {
type identityref {
base loopback;
}
description "Enables traffic loopback.";
}
}
/*
* Many types of interfaces support a configurable layer 2 MTU.
*/
augment "/if:interfaces/if:interface" {
description "Add configurable layer 2 MTU to all appropriate
interface types.";
leaf l2-mtu {
if-feature "configurable-l2-mtu";
type uint16 {
range "64 .. 65535";
}
description
"The maximum size of layer 2 frames that may be transmitted
or received on the interface (excluding any FCS overhead).
In the case of Ethernet interfaces it also excludes the
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4-8 byte overhead of any known (i.e. explicitly matched by
a child sub-interface) 801.1Q VLAN tags.";
}
}
/*
* Add generic support for sub-interfaces.
*
* This should be extended to cover all interface types that are
* child interfaces of other interfaces.
*/
augment "/if:interfaces/if:interface" {
when "derived-from(if:type,
'ietf-if-cmn',
'sub-interface') or
if:type = 'ianaift:atmSubInterface' or
if:type = 'ianaift:frameRelay'" {
description
"Any ianaift:types that explicitly represent sub-interfaces
or any types that derive from the sub-interface identity";
}
if-feature "sub-interfaces";
description "Add a parent interface field to interfaces that
model sub-interfaces";
leaf parent-interface {
type if:interface-ref;
mandatory true;
description
"This is the reference to the parent interface of this
sub-interface.";
}
}
/*
* Augments the IETF interfaces model with a leaf that indicates
* which layer traffic is to be transported at.
*/
augment "/if:interfaces/if:interface" {
if-feature "transport-layer";
description "Add a top level node to appropriate interfaces to
indicate which tranport layer an interface is
operating at";
leaf transport-layer {
type enumeration {
enum layer-1 {
value 1;
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description "Layer 1 transport.";
}
enum layer-2 {
value 2;
description "Layer 2 transport";
}
enum layer-3 {
value 3;
description "Layer 3 transport";
}
}
default layer-3;
description
"The transport layer at which the interface is operating at";
}
}
}
<CODE ENDS>
6. Interfaces Ethernet-Like YANG Module
This YANG module augments the interface container defined in RFC 7223
[RFC7223] for Etherlike interfaces. This includes Ethernet
interfaces, 802.3 LAG (802.1AX) interfaces, VLAN sub-interfaces,
Switch Virtual interfaces, and Pseudo-Wire Head-End interfaces.
<CODE BEGINS> file "interfaces-ethernet-like@2015-06-26.yang"
module interfaces-ethernet-like {
namespace "urn:ietf:params:xml:ns:yang:interfaces-ethernet-like";
prefix ethlike;
import ietf-interfaces {
prefix if;
}
import ietf-yang-types {
prefix yang;
}
import iana-if-type {
prefix ianaift;
}
organization
"Cisco Systems, Inc.
Customer Service
Postal: 170 W Tasman Drive
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San Jose, CA 95134
Tel: +1 1800 553-NETS
E-mail: cs-yang@cisco.com";
contact
"Robert Wilton - rwilton@cisco.com";
description
"This module contains YANG definitions for configuration for
'Ethernet-like' interfaces. It is applicable to all interface
types that use Ethernet framing and expose an Ethernet MAC
layer, and includes such interfaces as physical Ethernet
interfaces, Ethernet LAG interfaces and VLAN sub-interfaces.";
revision 2015-06-26 {
description "Updated reference to new internet draft name.";
reference
"Internet draft: draft-wilton-netmod-intf-ext-yang-00";
}
/*
* Configuration parameters for Etherlike interfaces.
*/
augment "/if:interfaces/if:interface" {
when "if:type = 'ianaift:ethernetCsmacd' or
if:type = 'ianaift:ieee8023adLag' or
if:type = 'ianaift:l2vlan' or
if:type = 'ianaift:ifPwType'" {
description "Applies to all Ethernet-like interfaces";
}
description
"Augment the interface model with configuration parameters for
all Ethernet-like interfaces";
container ethernet-like {
description "Contains configuration parameters for interfaces
that use Ethernet framing and expose an Ethernet
MAC layer.";
leaf mac-address {
type yang:mac-address;
description
"The configured MAC address of the interface.";
}
}
}
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/*
* Operational state for Etherlike interfaces.
*/
augment "/if:interfaces-state/if:interface" {
when "if:type = 'ianaift:ethernetCsmacd' or
if:type = 'ianaift:ieee8023adLag' or
if:type = 'ianaift:l2vlan' or
if:type = 'ianaift:ifPwType'" {
description "Applies to all Ethernet-like interfaces";
}
description
"Augments the interface model with operational state parameters
for all Ethernet-like interfaces.";
container ethernet-like {
description "Contains operational state parameters for
interfaces that use Ethernet framing and expose an
Ethernet MAC layer.";
leaf mac-address {
type yang:mac-address;
description
"The operational MAC address of the interface, if
applicable";
}
leaf bia-mac-address {
type yang:mac-address;
description
"The 'burnt-in' MAC address. I.e the default MAC address
assigned to the interface if none is explicitly
configured.";
}
}
}
}
<CODE ENDS>
7. Acknowledgements
The authors wish to thank Juergen Schoenwaelder, Mahesh Jethanandani,
Michael Zitao, Neil Ketley and Qin Wu for their helpful comments
contributing to this draft.
8. IANA Considerations
This document defines several new YANG module and the authors
politely request that IANA assigns unique names to the YANG module
files contained within this draft, and also appropriate URIs in the
"IETF XML Registry".
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9. Security Considerations
The YANG module defined in this memo is designed to be accessed via
the NETCONF protocol RFC 6241 [RFC6241]. The lowest NETCONF layer is
the secure transport layer and the mandatory to implement secure
transport is SSH RFC 6242 [RFC6242]. The NETCONF access control
model RFC 6536 [RFC6536] provides the means to restrict access for
particular NETCONF users to a pre-configured subset of all available
NETCONF protocol operations and content.
There are a number of data nodes defined in this YANG module which
are writable/creatable/deletable (i.e. config true, which is the
default). These data nodes may be considered sensitive or vulnerable
in some network environments. Write operations (e.g. edit-config) to
these data nodes without proper protection can have a negative effect
on network operations. These are the subtrees and data nodes and
their sensitivity/vulnerability:
9.1. interfaces-common.yang
The interfaces-common YANG module contains various configuration
leaves that affect the behavior of interfaces. Modifying these
leaves can cause an interface to go down, or become unreliable, or to
drop traffic forwarded over it. More specific details of the
possible failure modes are given below.
The following leaf could cause the interface to go down, and stop
processing any ingress or egress traffic on the interface:
o /if:interfaces/if:interface/loopback
The following leaf could cause changes to the routing metrics. Any
change in routing metrics could cause too much traffic to be routed
through the interface, or through other interfaces in the network,
potentially causing traffic loss due to excesssive traffic on a
particular interface or network device:
o /if:interfaces/if:interface/bandwidth
The following leaves could cause instabilities at the interface link
layer, and cause unwanted higher layer routing path changes if the
leaves are modified, although they would generally only affect a
device that had some underlying link stability issues:
o /if:interfaces/if:interface/carrier-delay/down
o /if:interfaces/if:interface/carrier-delay/up
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o /if:interfaces/if:interface/dampening/half-life
o /if:interfaces/if:interface/dampening/reuse
o /if:interfaces/if:interface/dampening/suppress
o /if:interfaces/if:interface/dampening/max-suppress-time
The following leaves could cause traffic loss on the interface
because the received or transmitted frames do not comply with the
frame matching criteria on the interface and hence would be dropped:
o /if:interfaces/if:interface/encapsulation
o /if:interfaces/if:interface/l2-mtu
o /if:interfaces/if:interface/l3-mtu
o /if:interfaces/if:interface/transport-layer
Normally devices will not allow the parent-interface leaf to be
changed after the interfce has been created. If an implementation
did allow the parent-interface leaf to be changed then it could cause
all traffic on the affected interface to be dropped. The affected
leaf is:
o /if:interfaces/if:interface/parent-interface
9.2. interfaces-ethernet-like.yang
Generally, the configuration nodes in the interfaces-ethernet-like
YANG module are concerned with configuration that is common across
all types of Ethernet-like interfaces. Currently, the module only
contains a node for configuring the operational MAC address to use on
an interface. Adding/modifying/deleting this leaf has the potential
risk of causing protocol instability, excessive protocol traffic, and
general traffic loss, particularly if the configuration change caused
a duplicate MAC address to be present on the local network . The
following leaf is affected:
o interfaces/interface/ethernet-like/mac-address
10. References
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10.1. 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,
<http://www.rfc-editor.org/info/rfc2119>.
[RFC6020] Bjorklund, M., Ed., "YANG - A Data Modeling Language for
the Network Configuration Protocol (NETCONF)", RFC 6020,
DOI 10.17487/RFC6020, October 2010,
<http://www.rfc-editor.org/info/rfc6020>.
[RFC7223] Bjorklund, M., "A YANG Data Model for Interface
Management", RFC 7223, DOI 10.17487/RFC7223, May 2014,
<http://www.rfc-editor.org/info/rfc7223>.
[RFC7224] Bjorklund, M., "IANA Interface Type YANG Module", RFC
7224, DOI 10.17487/RFC7224, May 2014,
<http://www.rfc-editor.org/info/rfc7224>.
10.2. Informative References
[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,
<http://www.rfc-editor.org/info/rfc6241>.
[RFC6242] Wasserman, M., "Using the NETCONF Protocol over Secure
Shell (SSH)", RFC 6242, DOI 10.17487/RFC6242, June 2011,
<http://www.rfc-editor.org/info/rfc6242>.
[RFC6536] Bierman, A. and M. Bjorklund, "Network Configuration
Protocol (NETCONF) Access Control Model", RFC 6536, DOI
10.17487/RFC6536, March 2012,
<http://www.rfc-editor.org/info/rfc6536>.
Authors' Addresses
Robert Wilton (editor)
Cisco Systems
Email: rwilton@cisco.com
David Ball
Cisco Systems
Email: daviball@cisco.com
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Tapraj Singh
Juniper Networks
Email: tsingh@juniper.net
Selvakumar Sivaraj
Juniper Networks
Email: ssivaraj@juniper.net
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