Internet-Draft Consumer-Facing Interface YANG Data Mode February 2023
Jeong, et al. Expires 27 August 2023 [Page]
Workgroup:
I2NSF Working Group
Internet-Draft:
draft-ietf-i2nsf-consumer-facing-interface-dm-25
Published:
Intended Status:
Standards Track
Expires:
Authors:
J. Jeong, Ed.
Sungkyunkwan University
C. Chung
Sungkyunkwan University
T. Ahn
Korea Telecom
R. Kumar
Juniper Networks
S. Hares
Huawei

I2NSF Consumer-Facing Interface YANG Data Model

Abstract

This document describes an information model and the corresponding YANG data model for the Consumer-Facing Interface of the Security Controller in an Interface to Network Security Functions (I2NSF) system in a Network Functions Virtualization (NFV) environment. The information model defines various types of managed objects and the relationship among them needed to build the flow policies from users' perspective. This information model is based on the "Event-Condition-Action" (ECA) policy model defined by a capability information model for I2NSF, and the YANG data model is defined for enabling different users of a given I2NSF system to define, manage, and monitor flow policies within an administrative domain (e.g., user group).

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 https://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 27 August 2023.

Table of Contents

1. Introduction

In a framework of Interface to Network Security Functions (I2NSF) [RFC8329], each vendor can register their Network Security Functions (NSFs) using a Developer's Management System (DMS). Then the I2NSF User (e.g., an application for a security administrator such as a web application) can configure the NSFs by defining high-level security policies. Most vendors provide various proprietary applications or tools to define security policies for their own NSFs. The Consumer-Facing Interface is required because the applications developed by each vendor need to have a standard interface specifying the data types used when the I2NSF User and Security Controller (i.e., Network Operator Management System) communicate with each other using this interface. Therefore, this document specifies the required information such as their data types and encoding schemes so that high-level security policies (or configuration information for security policies) can be transferred to the Security Controller through the Consumer-Facing Interface. Security Controller will use the given information to translate the high-level security policies into the corresponding low-level security policies. The Security Controller delivers the translated security policies to the NSFs according to their respective security capabilities for the required security enforcement.

The Consumer-Facing Interface would be built using a set of objects, with each object capturing a unique set of information from an I2NSF User [RFC8329] needed to express a Security Policy. An object may have relationship with various other objects to express a complete set of requirements. An information model captures the managed objects and relationship among these objects. The information model proposed in this document is structured in accordance with the "Event-Condition-Action" (ECA) policy model.

An NSF Capability model is proposed in [I-D.ietf-i2nsf-capability-data-model] as the basic model for both the NSF-Facing interface and Consumer-Facing Interface security policy model of this document.

[RFC3444] explains differences between an information and data model. This document uses the guidelines in [RFC3444] to define both the information and data model for Consumer-Facing Interface. Figure 1 shows a high-level abstraction of Consumer-Facing Interface. A data model, which represents an implementation of the information model in a specific data representation language, is also defined in this document.

                    +-----------------+
                    | Consumer-Facing |
                    |    Interface    |
                    +--------+--------+
                             ^
                             |
                             +-------------+------------+
                             |             |            |
                       +-----+----+  +-----+----+  +----+---+
                       |  Policy  |  | Endpoint |  | Threat |
                       |          |  |  groups  |  |  feed  |
                       +-----+----+  +----------+  +--------+
                             ^
                             |
                      +------+------+
                      |     Rule    |
                      +------+------+
                             ^
                             |
            +----------------+----------------+
            |                |                |
     +------+------+  +------+------+  +------+------+
     |    Event    |  |  Condition  |  |    Action   |
     +-------------+  +-------------+  +-------------+

Figure 1: Diagram for High-level Abstraction of Consumer-Facing Interface

Data models are defined at a lower level of abstraction and provide many details. They provide details about the implementation of a protocol's specification, e.g., rules that explain how to map managed objects onto lower-level protocol constructs. Since conceptual models can be implemented in different ways, multiple data models can be derived from a single information model.

The efficient and flexible provisioning of network functions by a Network Functions Virtualization (NFV) system supports rapid deployment of newly developed functions. As practical applications, Network Security Functions (NSFs), such as firewall, Intrusion Detection System (IDS)/Intrusion Prevention System (IPS), and attack mitigation, can also be provided as Virtual Network Functions (VNF) in the NFV system. By the efficient virtualization technology, these VNFs might be automatically provisioned and dynamically migrated based on real-time security requirements. This document presents a YANG data model to implement security functions based on NFV.

2. Terminology

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.

This document uses the terminology described in [RFC8329].

This document follows the guidelines of [RFC8407], uses the common YANG types defined in [RFC6991], and adopts the Network Management Datastore Architecture (NMDA) [RFC8342]. The meaning of the symbols in tree diagrams is defined in [RFC8340].

3. Information Model for Policy

A Policy object is a means to express a Security Policy set by an I2NSF User with the Consumer-Facing Interface. It is sent to the Security Controller which converts it into an NSF-specific configuration via the NSF-Facing Interface for enforcement of the NSF. Figure 2 shows the YANG tree of the Policy object. The Policy object SHALL have the following information:

Name:
This field identifies the name of this object.
Language:
The language field indicates the language tag that is used for the natural language text that is included in all of the 'description' attributes. The language field is encoded following the rules in Section 2.1 of [RFC5646]. The default language tag is "en-US".
Resolution-strategy:
This field represents how to resolve conflicts that occur between actions of the same or different policy rules that are matched and contained in this particular NSF. The resolution strategy is described in Section 3.2 of [I-D.ietf-i2nsf-capability-data-model] in detail.
Rules:
This field contains a list of rules. These rules are defined for implementing business requirements such as 1) supporting communication between two Endpoint Groups (see Section 4), 2) preventing communication with externally or internally identified threats, and 3) controlling access to internal or external resources for meeting regulatory compliance. An organization may restrict certain communication between a set of users and applications for example. The threats may be identified from threat feeds obtained from external sources. Note that rule conflict analysis should be performed by a monitoring service for policy rule conflicts in Security Controller to detect such rule conflicts among the policy rules installed into network security functions.


module: ietf-i2nsf-cons-facing-interface
  +--rw i2nsf-cfi-policy* [name]
  |  +--rw name                   string
  |  +--rw language?              string
  |  +--rw resolution-strategy?   identityref
  |  +--rw rules* [name]
  |     ...
  +--rw endpoint-groups
  |  ...
  +--rw threat-prevention
     ...

Figure 2: Policy YANG Data Tree

A policy contains a list of rules. In order to express a Rule, a Rule must have complete information such as where and when a policy needs to be applied. This is done by defining a set of managed objects and relationship among them. A Policy Rule defined in this module is a set of management guidelines that defines a desired behavior based on the Event-Condition-Action policy model (Section 3.1 of [I-D.ietf-i2nsf-capability-data-model]), but that is independent of a specific device and implementation. Figure 3 shows the YANG data tree of the Rule object. The rule object SHALL have the following information:

Name:
This field identifies the name of this object.
Priority:
This field identifies the priority of the rule.
Event:
This field includes the information to determine whether the Rule Condition can be evaluated or not (see the definition of Event in Section 3.1 of [I-D.ietf-i2nsf-capability-data-model]). See details of the Event Object in Section 3.1.
Condition:
This field contains a set of attributes, features, and/or values that are to be matched with the attributes of a packet or traffic flow to determine whether the Rule Action can be executed or not (see Section 3.1 of [I-D.ietf-i2nsf-capability-data-model]). See details of the Condition Object in Section 3.2.
Action:
This field identifies the action taken when a rule is matched (see Section 3.1 of [I-D.ietf-i2nsf-capability-data-model]). There is always an implicit action to drop traffic if no rule is matched for a traffic type. See details of the Action Object in Section 3.3.
     +--rw rules* [name]
     |  +--rw name         string
     |  +--rw priority?    uint8
     |  +--rw event
     |  |  ...
     |  +--rw condition
     |  |  ...
     |  +--rw action
     |     ...

Figure 3: Rule YANG Data Tree

3.1. Event Sub-model

The Event Object contains information related to scheduling a Rule. The Event Object activates the evaluation of the Condition Object based on a security event (i.e., system event and system alarm). Note that an empty Event Object means that the event will always evaluate to true and start the evaluation of the Condition Object. Figure 4 shows the YANG tree of the Event object. Event object SHALL have the following information:

System-event (also called alert):
is defined as a warning about any changes of configuration, any access violation, the information of sessions and traffic flows.
System-alarm:
is defined as a warning related to service degradation in system hardware.
  +--rw event
  |  +--rw system-event*   identityref
  |  +--rw system-alarm*   identityref

Figure 4: Event Sub-model YANG Data Tree

3.2. Condition Sub-model

The Condition object describes the network traffic pattern or fields that must be matched against the observed network traffic for the rule to trigger. The fields used to express the required conditions to trigger the rule are organized around the class of NSFs expected to be able to observe or compute them. Figure 5 shows the YANG tree of the Condition object. The Condition Sub-model SHALL have the following information:

Case (firewall):
This field represents the layer-2 header (e.g., MAC addresses), layer-3 header (e.g., IPv4 or IPv6 addresses, ICMPv4 or ICMPv6 parameters, and transport layer protocol) and layer-4 header (e.g., port numbers) of the network traffic. Note that the YANG module only provides high-level ICMP messages that are shared between ICMPv4 and ICMPv6 (e.g., Destination Unreachable: Port Unreachable which is ICMPv4's type 3 and code 3 or ICMPv6's type 1 and code 4). Also note that QUIC protocol [RFC9000] is excluded in the data model as it is not considered in the initial I2NSF documents [RFC8329]. The QUIC traffic should not be treated as UDP traffic and will be considered in the future I2NSF documents.
Case (ddos):
This field represents the threshold limit for the rate of the network traffic to mitigate a DDoS attack. The threshold configuration can be given in packet rate, byte rate, and flow rate. Definition of packet rate, byte rate, and flow rate are defined in Section 6 of [I-D.ietf-i2nsf-capability-data-model].
Case (anti-virus):
This field represents the configuration for an Antivirus interruption. A specific security profile can be added to Security Controller in order to update the security of the Antivirus. Filenames or paths that contain the profile can be specified by I2NSF User. The decision to either perform or skip the Antivirus interruption depends on the action of the rule. For example, a drop action uses the security profile for dropping either packets or flows in the Antivirus interruption. On the other hand, a pass action uses the security profile for allowing either packets or flows without the Antivirus interruption.
Case (payload):
This field represents the payload information of the network traffic. The configuration is given in a high-level form that maps into the corresponding binary form registered with the Threat Prevention object (see Section 5.2).
Case (url-category):
This field represents the URL to be filtered. This information can be used to block or allow a certain URL or website. The url-name is a group of URL or websites to be matched.
Case (voice):
This field contains the call source-id, call destination-id, and user-agent. This information describes a caller id or receiver id in order to prevent any exploits (or attacks) of Voice over IP (VoIP) or Voice over Cellular Network (VoCN). Note that VoCN can be either Voice over LTE (VoLTE) [TR-29.949-3GPP] or Voice over 5G (Vo5G) [TR-21.915-3GPP].
Case (context):
This field represents the extra information for the condition such as time, application, device type, user condition, and geographic location (see Section 5.1 of [I-D.ietf-i2nsf-capability-data-model]).
Case (Threat-feed):
This field contains the information obtained from threat-feeds. This field is used when security rule condition is based on the existing threat reports gathered from other sources.

Note that the identities for ICMP messages provided in the YANG module are combined for ICMPv4 and ICMPv6 such as echo/echo-reply for ICMPv4 and echo-request/echo-reply for ICMPv6. For more information about the mapping between ICMPv4 and ICMPv6 messages, refer to [IANA-ICMP-Parameters] and [IANA-ICMPv6-Parameters].

 +--rw condition
 |  +--rw firewall
 |  |  +--rw source*                     union
 |  |  +--rw destination*                union
 |  |  +--rw transport-layer-protocol?   identityref
 |  |  +--rw range-port-number* [start end]
 |  |  |  +--rw start    inet:port-number
 |  |  |  +--rw end      inet:port-number
 |  |  +--rw icmp
 |  |     +--rw message*   identityref
 |  +--rw ddos
 |  |  +--rw rate-limit
 |  |     +--rw packet-rate-threshold?   uint64
 |  |     +--rw byte-rate-threshold?     uint64
 |  |     +--rw flow-rate-threshold?     uint64
 |  +--rw anti-virus
 |  |  +--rw profile*   string
 |  +--rw payload
 |  |  +--rw content*   -> /threat-prevention/payload-content/name
 |  +--rw url-category
 |  |  +--rw url-name?   -> /endpoint-groups/url-group/name
 |  +--rw voice
 |  |  +--rw source-id*        -> /endpoint-groups/voice-group/name
 |  |  +--rw destination-id*   -> /endpoint-groups/voice-group/name
 |  |  +--rw user-agent*       string
 |  +--rw context
 |  |  +--rw time
 |  |  |  +--rw start-date-time?   yang:date-and-time
 |  |  |  +--rw end-date-time?     yang:date-and-time
 |  |  |  +--rw period
 |  |  |  |  +--rw start-time?   time
 |  |  |  |  +--rw end-time?     time
 |  |  |  |  +--rw day*          day
 |  |  |  |  +--rw date*         int8
 |  |  |  |  +--rw month*        string
 |  |  |  +--rw frequency?         enumeration
 |  |  +--rw application
 |  |  |  +--rw protocol*   identityref
 |  |  +--rw device-type
 |  |  |  +--rw device*   identityref
 |  |  +--rw users
 |  |  |  +--rw user* [id]
 |  |  |  |  +--rw id      uint32
 |  |  |  |  +--rw name?   string
 |  |  |  +--rw group* [id]
 |  |  |     +--rw id      uint32
 |  |  |     +--rw name?   string
 |  |  +--rw geographic-location
 |  |     +--rw source
 |  |     |  +--rw country?   -> /endpoint-groups/location-group/country
 |  |     |  +--rw region?    -> /endpoint-groups/location-group/region
 |  |     |  +--rw city?      -> /endpoint-groups/location-group/city
 |  |     +--rw destination
 |  |        +--rw country?   -> /endpoint-groups/location-group/country
 |  |        +--rw region?    -> /endpoint-groups/location-group/region
 |  |        +--rw city?      -> /endpoint-groups/location-group/city
 |  +--rw threat-feed
 |     +--rw name*   -> /threat-prevention/threat-feed-list/name

Figure 5: Condition Sub-model YANG Data Tree

3.3. Action Sub-model

This object represents actions that Security Admin wants to perform based on certain traffic class. Figure 6 shows the YANG tree of the Action object. The Action object SHALL have following information:

Primary-action:
This field identifies the action when a rule is matched by an NSF. The action could be one of "pass", "drop", "reject", "rate-limit", "mirror", "invoke-signaling", "tunnel-encapsulation", "forwarding", and "transformation". This action is related to the ingress-action-capability and egress-action-capability in [I-D.ietf-i2nsf-capability-data-model]. Note that if the action is "rate-limit", the limit value should be given to Security Controller in order to determine the threshold of the traffic rate.
Secondary-action:
This field identifies the action when a rule is matched by an NSF. The action could be one of "rule-log" and "session-log". This action is related to the log-action in [I-D.ietf-i2nsf-capability-data-model].
  +--rw action
     +--rw primary-action
     |  +--rw action    identityref
     |  +--rw limit?    decimal64
     +--rw secondary-action
        +--rw log-action?   identityref

Figure 6: Action Sub-model YANG Data Tree

4. Information Model for Policy Endpoint Groups

The Policy Endpoint Group is the collection of network nodes that are labeled and placed together into a group. As shown in Figure 7, endpoint groups include User-Group (Section 4.1), Device-Group (Section 4.2), Location-Group (Section 4.3), and URL-Group (Section 4.4). An I2NSF User can create and use these objects to represent a logical entity in their business environment, where a security policy is to be applied. Figure 8 shows the YANG tree of the Endpoint-Groups object.

The endpoint group information delivered by the I2NSF User should be stored into a secure database available to the Security Controller for the translation from a high-level security policy to the corresponding low-level security policy. The information should be synchronized with other systems in real-time for accurate translation.

                           +-------------------+
                           |  Endpoint Groups  |
                           +---------+---------+
                                     ^
                                     |
       +-------------+---------------+--------------+-----------+
  0..n |        0..n |          0..n |         0..n |      0..n |
 +-----+----+ +------+-----+ +-------+------+ +-----+---+ +-----+-----+
 |User-group| |Device-group| |Location-group| |URL-group| |Voice-group|
 +----------+ +------------+ +--------------+ +---------+ +-----------+

Figure 7: Endpoint Group Diagram
  +--rw endpoint-groups
  |  +--rw user-group* [name]
  |  |  ...
  |  +--rw device-group* [name]
  |  |  ...
  |  +--rw location-group* [country region city]
  |  |  ...
  |  +--rw url-group* [name]
  |  |  ...
  |  +--rw voice-group* [name]
  |     ...

Figure 8: Endpoint Group YANG Data Tree

4.1. User-Group

The User-Group object represents the MAC addresses and IP (IPv4 or IPv6) addresses that are labeled as a group of users (e.g., employees). Figure 9 shows the YANG tree of the User-Group object. The User-Group object SHALL have the following information:

Name:
This field identifies the name of the user-group.
mac-address:
This represents the MAC address(es) for the user-group.
Range-ipv4-address:
This represents the list of IPv4 address ranges for the user-group.
Range-ipv6-address:
This represents the list of IPv6 address ranges for the user-group.
 +--rw user-group* [name]
 |  +--rw name                        string
 |  +--rw mac-address*                yang:mac-address
 |  +--rw (match-type)
 |     +--:(range-match-ipv4)
 |     |  +--rw range-ipv4-address* [start end]
 |     |     +--rw start    inet:ipv4-address-no-zone
 |     |     +--rw end      inet:ipv4-address-no-zone
 |     +--:(range-match-ipv6)
 |        +--rw range-ipv6-address* [start end]
 |           +--rw start    inet:ipv6-address-no-zone
 |           +--rw end      inet:ipv6-address-no-zone

Figure 9: User-Group YANG Data Tree

4.2. Device-Group

The Device-Group object represents the labeled network devices that provide services (e.g., servers) hosted on the IP (IPv4 or IPv6) addresses and application protocol. Figure 10 shows the YANG tree of the Device-group object. The Device-Group object SHALL have the following information:

Name:
This field identifies the name of this object.
Range-ipv4-address:
This represents the list of IPv4 address ranges for the device-group.
Range-ipv6-address:
This represents the list of IPv6 address ranges for the device-group.
Application-protocol:
This represents the application layer protocols of devices for the device-group.
 +--rw device-group* [name]
 |  +--rw name                        string
 |  +--rw (match-type)
 |  |  +--:(range-match-ipv4)
 |  |  |  +--rw range-ipv4-address* [start end]
 |  |  |     +--rw start    inet:ipv4-address-no-zone
 |  |  |     +--rw end      inet:ipv4-address-no-zone
 |  |  +--:(range-match-ipv6)
 |  |     +--rw range-ipv6-address* [start end]
 |  |        +--rw start    inet:ipv6-address-no-zone
 |  |        +--rw end      inet:ipv6-address-no-zone
 |  +--rw application-protocol*       identityref

Figure 10: Device-Group YANG Data Tree

4.3. Location-Group

The Location-Group object represents the IP (IPv4 or IPv6) addresses labeled as a geographic location (i.e., country, region, and city). Figure 11 shows the YANG tree of the Location-Group object. The Location-Group object SHALL have the following information:

Country:
This field represents the 2-letter ISO country code conforming to ISO3166-1 alpha 2, e.g., 'US' for United States, 'JP' for Japan, and 'PL' for Poland.
Region:
This field represents the region code conforming to ISO 3166-2. Examples include 'ID-RI' for Riau province of Indonesia and 'NG-RI' for the Rivers province in Nigeria.
City:
This field represents the city of a region, e.g., 'Dublin', 'New York', and 'Sao Paulo'.
Range-ipv4-address:
This represents the list of IPv4 address range of a geographic location in the location group.
Range-ipv6-address:
This represents the list of IPv6 address range of a geographic location in the location group.
 +--rw location-group* [country region city]
 |  +--rw country                     string
 |  +--rw region                      string
 |  +--rw city                        string
 |  +--rw (match-type)
 |     +--:(range-match-ipv4)
 |     |  +--rw range-ipv4-address* [start end]
 |     |     +--rw start    inet:ipv4-address-no-zone
 |     |     +--rw end      inet:ipv4-address-no-zone
 |     +--:(range-match-ipv6)
 |        +--rw range-ipv6-address* [start end]
 |           +--rw start    inet:ipv6-address-no-zone
 |           +--rw end      inet:ipv6-address-no-zone

Figure 11: Location-Group YANG Data Tree

4.4. URL-Group

The URL-Group object represents the collection of Uniform Resource Locators (URLs) or hostnames labeled into a group (e.g., sns-websites). Figure 12 shows the YANG tree of the URL-Group object. The URL-Group object SHALL have the following information:

Name:
This field identifies the name of this object.
URL:
This field represents the URL or hostname.
 +--rw url-group* [name]
 |  +--rw name    string
 |  +--rw url*    inet:uri

Figure 12: URL-Group YANG Data Tree

4.5. Voice-Group

The Voice-Group object represents the collection of Session Initiation Protocol (SIP) identities labeled into a group. Figure 13 shows the YANG tree of the Voice-Group object. The Voice-Group object SHALL have the following information:

Name:
This field identifies the name of this object.
SIP-id:
This field represents the SIP identities in SIP URI scheme (Section 19.1.1 of [RFC3261]).
  +--rw voice-group* [name]
     +--rw name      string
     +--rw sip-id*   inet:uri

Figure 13: Voice-Group YANG Data Tree

5. Information Model for Threat Prevention

The Threat Prevention model describes information obtained from threat feeds (i.e., sources for obtaining the threat information). The presented information is the features or attributes that identify a well-known threat (e.g., signatures or payload) to prevent malicious activity entering the secured network. There are multiple managed objects that constitute this category. Figure 15 shows the YANG tree of a Threat-Prevention object.

                   +-------------------+
                   | Threat Prevention |
                   +---------+---------+
                             ^
                             |
                   +---------+---------+
           0..n    |         0..n      |
            +------+------+   +--------+--------+
            | Threat-feed |   | Payload-content |
            +-------------+   +-----------------+

Figure 14: Threat Prevention Diagram
  +--rw threat-prevention
     +--rw threat-feed-list* [name]
     |  ...
     +--rw payload-content* [name]
        ...

Figure 15: Threat Prevention YANG Data Tree

5.1. Threat Feed

This object represents a threat feed which provides the signatures of malicious activities. Figure 16 shows the YANG tree of a Threat-feed-list. The Threat-Feed object SHALL have the following information:

Name:
This field identifies the name of this object.
IOC:
This field represents the Indicators of Compromise (IOC), i.e., the critical information of patterns or characteristics in the threat feed that identifies malicious activities. The format of the information given in this field is based on the format field (e.g., STIX, MISP, OpenIOC, and IODEF).
Format:
This field represents the format or structure of the IOC field for the threat-feed such as Structured Threat Information Expression (STIX) [STIX], MISP Core [MISPCORE], OpenIOC [OPENIOC], and Incident Object Description Exchange Format (IODEF) [RFC8727]. This can be extended depending on the implementation of the existing threat-feed.

It is assumed that the I2NSF User obtains the threat signatures (i.e., threat content patterns) from a threat-feed server (i.e., feed provider), which is a server providing threat signatures. With the obtained threat signatures, the I2NSF User can deliver them to the Security Controller via the Consumer-Facing Interface. The retrieval of the threat signatures by the I2NSF User is out of the scope of this document.

     +--rw threat-feed-list* [name]
     |  +--rw name      string
     |  +--rw ioc*      string
     |  +--rw format    identityref

Figure 16: Threat Feed YANG Data Tree

5.2. Payload Content

This object represents a list of raw binary patterns of a packet payload content (i.e., data after a transport layer header) to describe a threat. Figure 17 shows the YANG tree of a Payload-content list. The Payload-content object SHALL have the following information:

Name:
This field identifies the name of this object. It is recommended to use short and simple words that describe the content. For example, the name "backdoor" indicates the payload content is related to a backdoor attack.
Description:
This represents the description to further describe the content field in detail. This field is not mandatory but recommended to be used as it is helpful for future usage.
Content:
This represents the payload content patterns (i.e., data after a transport layer header), which are involved in a security attack, in binary. If multiple instances of content are defined, it should match all contents somewhere in the session stream. The content pattern should be matched based on the order given by the user. The scope of the payload to be matched can be defined by the depth and offset/distance fields.
Depth:
This field specifies how far a packet should be searched for the specified content pattern defined in the content field. If this field is undefined, then the content pattern should be searched within the whole payload.
Starting-point:
This field specifies the starting point of matching the content pattern to the payload. If this field is undefined, then the content pattern should be searched from the beginning of the payload. The starting point can be defined by either the offset value or distance value. The offset keyword specifies where to start searching for the specified content pattern. The offset is calculated from the beginning of the payload. The distance keyword specifies how far a payload should be ignored before starting to search for the specified content pattern relative to the end of the previous specified content pattern match. This can be thought of as exactly the same thing as offset, except it is relative to the end of the last pattern match instead of the beginning of the packet. Note that this field cannot be used if the content is the first order of the list.
     +--rw payload-content* [name]
        +--rw name           string
        +--rw description?   string
        +--rw contents* [content]
           +--rw content           binary
           +--rw depth?            uint16
           +--rw (starting-point)?
              +--:(offset)
              |  +--rw offset?     int32
              +--:(distance)
                 +--rw distance?   int32

Figure 17: Payload Content in YANG Data Tree

6. YANG Data Model of Consumer-Facing Interface

The main objective of this document is to provide the YANG data model of the I2NSF Consumer-Facing Interface. This interface can be used to deliver control and management messages between an I2NSF User and Security Controller for the I2NSF User's high-level security policies.

The semantics of the data model is aligned with the information model of the Consumer-Facing Interface. This data model is designed to support the I2NSF framework that can be extended according to the security needs. In other words, the model design is independent of the content and meaning of specific policies as well as the implementation approach.

With the YANG data model of I2NSF Consumer-Facing Interface, this document provide examples for security policy rules such as time-based firewall, VoIP/VoCN security service, and DDoS-attack mitigation in Section 7.

6.1. YANG Module of Consumer-Facing Interface

This section describes a YANG module of Consumer-Facing Interface. This document provides identities in the data model to be used for configuration of an NSF. Each identity is used for a different type of configuration. The details are explained in the description of each identity. This YANG module imports from [RFC6991]. It makes references to [RFC0768] [RFC0792] [RFC0854] [RFC0959] [RFC1939] [RFC2595] [RFC3022] [RFC3261] [RFC3986] [RFC4250] [RFC4340] [RFC4443] [RFC5321] [RFC5646] [RFC8075] [RFC8335] [RFC8727] [RFC9051] [RFC9110] [RFC9112] [RFC9113] [RFC9260] [RFC9293] [GLOB] [IANA-ICMP-Parameters] [IANA-ICMPv6-Parameters] [ISO-3166-1alpha2] [ISO-3166-2] [I-D.ietf-i2nsf-capability-data-model] [I-D.ietf-i2nsf-nsf-monitoring-data-model] [MISPCORE] [OPENIOC] [STIX]

<CODE BEGINS> file "ietf-i2nsf-cons-facing-interface@2023-02-23.yang"

module ietf-i2nsf-cons-facing-interface {
  yang-version 1.1;
  namespace
    "urn:ietf:params:xml:ns:yang:ietf-i2nsf-cons-facing-interface";
  prefix
    i2nsfcfi;

  import ietf-inet-types{
    prefix inet;
    reference "RFC 6991";
  }

  import ietf-yang-types{
    prefix yang;
    reference "RFC 6991";
  }

  organization
    "IETF I2NSF (Interface to Network Security Functions)
     Working Group";

  contact
    "WG Web: <https://datatracker.ietf.org/wg/i2nsf>
     WG List: <mailto:i2nsf@ietf.org>

     Editor: Jaehoon Paul Jeong
     <mailto:pauljeong@skku.edu>

     Editor: Patrick Lingga
     <mailto:patricklink@skku.edu>";

  description
    "This module is a YANG module for Consumer-Facing Interface.

     Copyright (c) 2023 IETF Trust and the persons identified as
     authors of the code. All rights reserved.

     Redistribution and use in source and binary forms, with or
     without modification, is permitted pursuant to, and subject to
     the license terms contained in, the Revised BSD License set
     forth in Section 4.c of the IETF Trust's Legal Provisions
     Relating to IETF Documents
     (https://trustee.ietf.org/license-info).

     This version of this YANG module is part of RFC XXXX
     (https://www.rfc-editor.org/info/rfcXXXX); see the RFC itself
     for full legal notices.";

  // RFC Ed.: replace XXXX with an actual RFC number and remove
  // this note.

  revision "2023-02-23" {
    description "Initial revision.";
    reference
      "RFC XXXX: I2NSF Consumer-Facing Interface YANG Data Model";

    // RFC Ed.: replace XXXX with an actual RFC number and remove
    // this note.
  }

  identity resolution-strategy {
    description
      "Base identity for resolution strategy";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Resolution Strategy";
  }

  identity fmr {
    base resolution-strategy;
    description
      "Conflict resolution with First Matching Rule (FMR).";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Resolution Strategy";
  }

  identity lmr {
    base resolution-strategy;
    description
      "Conflict resolution with Last Matching Rule (LMR)";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Resolution Strategy";
  }

  identity pmre {
    base resolution-strategy;
    description
      "Conflict resolution with Prioritized Matching Rule with
       Errors (PMRE)";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Resolution Strategy";
  }

  identity pmrn {
    base resolution-strategy;
    description
      "Conflict resolution with Prioritized Matching Rule with
       No Errors (PMRN)";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Resolution Strategy";
  }

  identity event {
    description
      "Base identity for policy events.";
    reference
      "draft-ietf-i2nsf-nsf-monitoring-data-model-20: I2NSF NSF
       Monitoring Interface YANG Data Model - Event";
  }

  identity system-event {
    base event;
    description
      "Base Identity for system events. System event (also called
       alert) is defined as a warning about any changes of
       configuration, any access violation, the information of
       sessions and traffic flows.";
    reference
      "draft-ietf-i2nsf-nsf-monitoring-data-model-20: I2NSF NSF
       Monitoring Interface YANG Data Model - System event";
  }

  identity system-alarm {
    base event;
    description
      "Base identity for system alarms. System alarm is defined as a
       warning related to service degradation in system hardware.";
    reference
      "draft-ietf-i2nsf-nsf-monitoring-data-model-20: I2NSF NSF
       Monitoring Interface YANG Data Model - System alarm";
  }

  identity access-violation {
    base system-event;
    description
      "Access-violation system event is an event when a user tries
       to access (read, write, create, or delete) any information or
       execute commands above their privilege (i.e., not-conformant
       with the access profile).";
    reference
      "draft-ietf-i2nsf-nsf-monitoring-data-model-20: I2NSF NSF
       Monitoring Interface YANG Data Model - System event for access
       violation";
  }

  identity configuration-change {
    base system-event;
    description
      "The configuration-change system event is an event when a user
       adds a new configuration or modify an existing configuration
       (write configuration).";
    reference
      "draft-ietf-i2nsf-nsf-monitoring-data-model-20: I2NSF NSF
       Monitoring Interface YANG Data Model - System event for
       configuration change";
  }

  identity memory-alarm {
    base system-alarm;
    description
      "Memory is the hardware to store information temporarily or for
       a short period, i.e., Random Access Memory (RAM). A
       memory-alarm is emitted when the memory usage is exceeding
       the threshold.";
    reference
      "draft-ietf-i2nsf-nsf-monitoring-data-model-20: I2NSF NSF
       Monitoring Interface YANG Data Model - System alarm for
       memory";
  }

  identity cpu-alarm {
    base system-alarm;
    description
      "CPU is the Central Processing Unit that executes basic
       operations of the system. A cpu-alarm is emitted when the CPU
       usage is exceeding a threshold.";
    reference
      "draft-ietf-i2nsf-nsf-monitoring-data-model-20: I2NSF NSF
       Monitoring Interface YANG Data Model - System alarm for CPU";
  }

  identity disk-alarm {
    base system-alarm;
    description
      "Disk or storage is the hardware to store information for a
       long period, i.e., Hard Disk and Solid-State Drive. A
       disk-alarm is emitted when the disk usage is exceeding a
       threshold.";
    reference
      "draft-ietf-i2nsf-nsf-monitoring-data-model-20: I2NSF NSF
       Monitoring Interface YANG Data Model - System alarm for disk";
  }

  identity hardware-alarm {
    base system-alarm;
    description
      "A hardware alarm is emitted when a hardware failure (e.g.,
       CPU, memory, disk, or interface) is detected. A hardware
       failure is a malfunction within the electronic circuits or
       electromechanical components of the hardware that makes it
       unusable.";
    reference
      "draft-ietf-i2nsf-nsf-monitoring-data-model-20: I2NSF NSF
       Monitoring Interface YANG Data Model - System alarm for
       hardware";
  }

  identity interface-alarm {
    base system-alarm;
    description
      "Interface is the network interface for connecting a device
       with the network. The interface-alarm is emitted when the
       state of the interface is changed.";
    reference
      "draft-ietf-i2nsf-nsf-monitoring-data-model-20: I2NSF NSF
       Monitoring Interface YANG Data Model - System alarm for
       interface";
  }

  identity protocol {
    description
      "This identity represents the protocol types.";
  }

  identity transport-protocol {
    base protocol;
    description
      "Base identity for the Layer 4 (i.e., Transport Layer)
      Protocols";
  }

  identity tcp {
    base transport-protocol;
    description
      "Base identity for TCP condition capabilities";
    reference
      "RFC 9293: Transmission Control Protocol";
  }

  identity udp {
    base transport-protocol;
    description
      "Base identity for UDP condition capabilities";
    reference
      "RFC 768: User Datagram Protocol";
  }

  identity sctp {
    base transport-protocol;
    description
      "Identity for SCTP condition capabilities";
    reference
      "RFC 9260: Stream Control Transmission Protocol";
  }

  identity dccp {
    base transport-protocol;
    description
      "Identity for DCCP condition capabilities";
    reference
      "RFC 4340: Datagram Congestion Control Protocol";
  }

  identity application-protocol {
    description
      "Base identity for Application protocol. Note that a subset of
       application protocols (e.g., HTTP, HTTPS, FTP, POP3, and
       IMAP) are handled in this YANG module, rather than all
       the existing application protocols.";
  }

  identity http {
    base application-protocol;
    description
      "The identity for Hypertext Transfer Protocol version 1.1
       (HTTP/1.1).";
    reference
      "RFC 9110: HTTP Semantics
       RFC 9112: HTTP/1.1";
  }

  identity https {
    base application-protocol;
    description
      "The identity for Hypertext Transfer Protocol version 1.1
       (HTTP/1.1) over TLS.";
    reference
      "RFC 9110: HTTP Semantics
       RFC 9112: HTTP/1.1";
  }

  identity http2 {
    base application-protocol;
    description
      "The identity for Hypertext Transfer Protocol version 2
       (HTTP/2).";
    reference
      "RFC 9113: HTTP/2";
  }

  identity https2 {
    base application-protocol;
    description
      "The identity for Hypertext Transfer Protocol version 2
       (HTTP/2) over TLS.";
    reference
      "RFC 9113: HTTP/2";
  }

  identity ftp {
    base application-protocol;
    description
      "The identity for File Transfer Protocol.";
    reference
      "RFC 959: File Transfer Protocol (FTP)";
  }

  identity ssh {
    base application-protocol;
    description
      "The identity for Secure Shell (SSH) protocol.";
    reference
      "RFC 4250: The Secure Shell (SSH) Protocol";
  }

  identity telnet {
    base application-protocol;
    description
      "The identity for telnet.";
    reference
      "RFC 854: Telnet Protocol";
  }

  identity smtp {
    base application-protocol;
    description
      "The identity for Simple Mail Transfer Protocol.";
    reference
      "RFC 5321: Simple Mail Transfer Protocol (SMTP)";
  }

  identity pop3 {
    base application-protocol;
    description
      "The identity for Post Office Protocol 3 (POP3).";
    reference
      "RFC 1939: Post Office Protocol - Version 3 (POP3)";
  }

  identity pop3s {
    base application-protocol;
    description
      "The identity for Post Office Protocol 3 (POP3) over TLS";
    reference
      "RFC 1939: Post Office Protocol - Version 3 (POP3)
       RFC 2595: Using TLS with IMAP, POP3 and ACAP";
  }

  identity imap {
    base application-protocol;
    description
      "The identity for Internet Message Access Protocol (IMAP).";
    reference
      "RFC 9051: Internet Message Access Protocol (IMAP) - Version
       4rev2";
  }

  identity imaps {
    base application-protocol;
    description
      "The identity for Internet Message Access Protocol (IMAP) over
       TLS";
    reference
      "RFC 9051: Internet Message Access Protocol (IMAP) - Version
       4rev2";
  }

  identity action {
    description
      "Base identity for action";
  }

  identity primary-action {
    base action;
    description
      "Base identity for primary action. Primary action is an action
       that handle the forwarding of the packets or flows in an
       NSF.";
  }

  identity secondary-action {
    base action;
    description
      "Base identity for secondary action. Secondary action is an
       action in the background that does not affect the network,
       such as logging.";
  }

  identity ingress-action {
    base primary-action;
    description
      "Base identity for ingress action. The action to handle the
       network traffic that is entering the secured network.";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Ingress Action";
  }

  identity egress-action {
    base primary-action;
    description
      "Base identity for egress action. The action to handle the
       network traffic that is exiting the secured network.";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Egress Action";
  }

  identity pass {
    base ingress-action;
    base egress-action;
    description
      "The pass action allows traffic that matches
       the rule to proceed through the NSF to reach the
       destination.";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Actions and
       Default Action";
  }

  identity drop {
    base ingress-action;
    base egress-action;
    description
      "The drop action denies the traffic that
       matches the rule. The drop action should do a silent drop,
       which does not give any response to the source.";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Actions and
       Default Action";
  }

  identity reject {
    base ingress-action;
    base egress-action;
    description
      "The reject action denies a packet to go through the NSF
       entering or exiting the internal network and sends a response
       back to the source. The response depends on the packet and
       implementation. For example, a TCP packet is rejected with
       TCP RST response or a UDP packet may be rejected with an
       ICMPv4 response message with Type 3 Code 3 or ICMPv6 response
       message Type 1 Code 4 (i.e., Destination Unreachable:
       Destination port unreachable).";
  }

  identity mirror {
    base ingress-action;
    base egress-action;
    description
      "The mirror action copies a packet and sends the packet's copy
       to the monitoring entity while still allowing the packet or
       flow to go through the NSF.";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Actions and
       Default Action";
  }

  identity rate-limit {
    base ingress-action;
    base egress-action;
    description
      "The rate limit action limits the number of packets or flows
       that can go through the NSF by dropping packets or flows
       (randomly or systematically). The drop mechanism, e.g., silent
       drop and unreachable drop (i.e., reject), is up to the
       implementation";
    reference
      "draft-ietf-i2nsf-capability-data-model-32:
       I2NSF Capability YANG Data Model - Actions and
       Default Action";
  }

  identity invoke-signaling {
    base egress-action;
    description
      "The invoke-signaling action is used to convey information of
       the event triggering this action to a monitoring entity.";
  }

  identity tunnel-encapsulation {
    base egress-action;
    description
      "The tunnel encapsulation action is used to encapsulate the
       packet to be tunneled across the network to enable a secure
       connection.";
  }

  identity forwarding {
    base egress-action;
    description
      "The forwarding action is used to relay the packet from one
       network segment to another node in the network.";
  }

  identity transformation {
    base egress-action;
    description
      "The transformation action is used to transform a packet by
       modifying it (e.g., HTTP-to-CoAP packet translation).
       Note that a subset of transformation (e.g., HTTP-to-CoAP) is
       handled in this YANG module, rather than all the existing
       transformations.  Specific algorithmic transformations can be
       executed by a middlebox (e.g., NSF) for a given transformation
       name.";
    reference
      "RFC 8075: Guidelines for Mapping Implementations: HTTP to the
       Constrained Application Protocol (CoAP) - Translation between
       HTTP and CoAP.";
  }

  identity log-action {
    base secondary-action;
    description
      "Base identity for log action";
  }

  identity rule-log {
    base log-action;
    description
      "Log the policy rule that has been triggered by a packet or
       flow.";
  }

  identity session-log {
    base log-action;
    description
      "A session is a connection (i.e., traffic flow) of a data plane
       that includes source and destination information of IP
       addresses and transport port numbers with the protocol used.
       Log the session that triggered a policy rule.";
  }

  identity icmp-message {
    description
      "Base identity for ICMP Message types. Note that this YANG
       module only provide ICMP messages that is shared between
       ICMPv4 and ICMPv6 (e.g., Destination Unreachable: Port
       Unreachable which is ICMPv4 type 3 code 3 or ICMPv6 type 1
       code 4).";
    reference
      "RFC  792: Internet Control Message Protocol
       RFC 8335: PROBE: A Utility for Probing Interfaces
       IANA: Internet Control Message Protocol (ICMP)
       Parameters
       IANA: Internet Control Message Protocol version 6
       (ICMPv6) Parameters";
  }

  identity echo-reply {
    base icmp-message;
    description
      "Identity for 'Echo Reply' ICMP message type 0 in ICMPv4 or
       type 129 in ICMPv6";
  }

  identity destination-unreachable {
    base icmp-message;
    description
      "Identity for 'Destination Unreachable' ICMP message type 3 in
       ICMPv4 or type 1 in ICMPv6";
  }

  identity redirect {
    base icmp-message;
    description
      "Identity for 'Redirect' ICMP message type 5 in ICMPv4
       or type 137 in ICMPv6";
  }

  identity echo {
    base icmp-message;
    description
      "Identity for 'Echo' ICMP message type 8 in ICMPv4 or type 128
       in ICMPv6";
  }

  identity router-advertisement {
    base icmp-message;
    description
      "Identity for 'Router Advertisement' ICMP message type 9 in
       ICMPv4 or type 134 in ICMPv6";
  }

  identity router-solicitation {
    base icmp-message;
    description
      "Identity for 'Router Solicitation' ICMP message type 10 in
       ICMPv4 or type 135 in ICMPv6";
  }

  identity time-exceeded {
    base icmp-message;
    description
      "Identity for 'Time exceeded' ICMP message type 11 in ICMPv4
       or type 3 in ICMPv6";
  }

  identity parameter-problem {
    base icmp-message;
    description
      "Identity for 'Parameter Problem' ICMP message type 12 in
       ICMPv4 or type 4 in ICMPv6";
  }

  identity experimental-mobility-protocols {
    base icmp-message;
    description
      "Identity for 'Experimental Mobility Protocols' ICMP message
       type 41 in ICMPv4 or type 150 in ICMPv6";
  }

  identity extended-echo-request {
    base icmp-message;
    description
      "Identity for 'Extended Echo Request' ICMP message type 42
       in ICMPv4 or type 160 in ICMPv6";
  }

  identity extended-echo-reply {
    base icmp-message;
    description
      "Identity for 'Extended Echo Reply' ICMP message type 43 in
       ICMPv4 or type 161 in ICMPv6";
  }

  identity port-unreachable {
    base destination-unreachable;
    description
      "Identity for port unreachable in destination unreachable
       message (i.e., ICMPv4 type 3 code 3 or ICMPv6 type 1 code 4)";
  }

  identity request-no-error {
    base extended-echo-request;
    description
      "Identity for request with no error in extended echo request
       message (i.e., ICMPv4 type 42 code 0 or ICMPv6 type 160
       code 0)";
  }

  identity reply-no-error {
    base extended-echo-reply;
    description
      "Identity for reply with no error in extended echo reply
       message (i.e., ICMPv4 type 43 code 0 or ICMPv6 type 161
       code 0)";
  }

  identity malformed-query {
    base extended-echo-reply;
    description
      "Identity for malformed query in extended echo reply message
       (i.e., ICMPv4 type 43 code 1 or ICMPv6 type 161 code 1)";
  }

  identity no-such-interface {
    base extended-echo-reply;
    description
      "Identity for no such interface in extended echo reply message
       (i.e., ICMPv4 type 43 code 2 or ICMPv6 type 161 code 2)";
  }

  identity no-such-table-entry {
    base extended-echo-reply;
    description
      "Identity for no such table entry in extended echo reply
       message (i.e., ICMPv4 type 43 code 3 or ICMPv6 type 161
       code 3)";
  }

  identity multiple-interfaces-satisfy-query {
    base extended-echo-reply;
    description
      "Identity for multiple interfaces satisfy query in extended
       echo reply message (i.e., ICMPv4 type 43 code 4 or ICMPv6
       type 161 code 4) ";
    reference
      "RFC  792: Internet Control Message Protocol
       RFC 8335: PROBE: A Utility for Probing Interfaces";
  }

  identity ioc-format {
    description
      "This represents the base identity for the format of the
       Indicators of Compromise (IOC).";
  }

  identity stix {
    base ioc-format;
    description
      "This represents the Structured Threat Information Expression
       (STIX) format in JSON.";
    reference
      "STIX: Structured Threat Information Expression version 2.1 - JSON
       format";
  }

  identity misp {
    base ioc-format;
    description
      "This represents the Malware Information Sharing Platform (MISP)
       Core format.";
    reference
      "MISPCORE: Malware Information Sharing Platform (MISP) Core
       Format";
  }

  identity openioc {
    base ioc-format;
    description
      "This represents the OpenIOC format.";
    reference
      "OPENIOC: OpenIOC 1.1 Schema document";
  }

  identity iodef {
    base ioc-format;
    description
      "This represents the Incident Object Description Exchange Format
       (IODEF) format.";
    reference
      "RFC 8727: JSON Binding of the Incident Object Description
       Exchange Format";
  }

  identity device-type {
    description
      "Base identity for types of device. This identity is used for
       type of the device for the source or destination of a packet
       or traffic flow.";
  }

  identity computer {
    base device-type;
    description
      "Identity for computer such as personal computer (PC)
       and server.";
  }

  identity mobile-phone {
    base device-type;
    description
      "Identity for mobile-phone such as smartphone and
       cellphone";
  }

  identity voip-vocn-phone {
    base device-type;
    description
      "Identity for VoIP (Voice over Internet Protocol) or VoCN
       (Voice over Cellular Network, such as Voice over LTE or 5G)
       phone";
  }

  identity tablet {
    base device-type;
    description
      "Identity for tablet devices";
  }

  identity network-infrastructure-device {
    base device-type;
    description
      "Identity for network infrastructure devices
       such as switch, router, and access point";
  }

  identity iot-device {
    base device-type;
    description
      "Identity for Internet of Things (IoT) devices
       such as sensors, actuators, and low-power
       low-capacity computing devices";
  }

  identity ot {
    base device-type;
    description
      "Identity for Operational Technology (OT) devices (also
       known as industrial control systems) that interact
       with the physical environment and detect or cause direct
       change through the monitoring and control of devices,
       processes, and events such as programmable logic
       controllers (PLCs), digital oscilloscopes, building
       management systems (BMS), and fire control systems";
  }

  identity vehicle {
    base device-type;
    description
      "Identity for transportation vehicles that connect to and
       share data through the Internet over Vehicle-to-Everything
       (V2X) communications.";
  }

 /*
  * Typedefs
  */

  typedef time {
    type string {
      pattern '(0[0-9]|1[0-9]|2[0-3]):[0-5][0-9]:[0-5][0-9](\.\d+)?'
        + '(Z|[\+\-]((1[0-3]|0[0-9]):([0-5][0-9])|14:00))?';
    }
    description
      "The time type represents an instance of time of zero-duration
       in the specified timezone that recurs every day.";
  }

  typedef day {
    type enumeration {
      enum monday {
        description
          "This represents Monday.";
      }
      enum tuesday {
        description
          "This represents Tuesday.";
      }
      enum wednesday {
        description
          "This represents Wednesday";
      }
      enum thursday {
        description
          "This represents Thursday.";
      }
      enum friday {
        description
          "This represents Friday.";
      }
      enum saturday {
        description
          "This represents Saturday.";
      }
      enum sunday {
        description
          "This represents Sunday.";
      }
    }
    description
      "The type for representing the day of the week.";
  }

 /*
  * Groupings
  */

  grouping ip-address-info {
    description
      "There are two types to configure a security policy
       for an IP address, such as IPv4 adress and IPv6 address.";
    choice match-type {
      description
        "User can choose between IPv4 and IPv6.";
      case range-match-ipv4 {
        list range-ipv4-address {
          key "start end";
          leaf start {
            type inet:ipv4-address-no-zone;
            mandatory true;
            description
              "A start IPv4 address for a range match.";
          }
          leaf end {
            type inet:ipv4-address-no-zone;
            mandatory true;
            description
              "An end IPv4 address for a range match.";
          }
          description
            "A range match for IPv4 addresses is provided.
             Note that the start IPv4 address must be lower than
             the end IPv4 address.";
        }
      }
      case range-match-ipv6 {
        list range-ipv6-address {
          key "start end";
          leaf start {
            type inet:ipv6-address-no-zone;
            mandatory true;
            description
              "A start IPv6 address for a range match.";
          }
          leaf end {
            type inet:ipv6-address-no-zone;
            mandatory true;
            description
              "An end IPv6 address for a range match.";
          }
          description
            "A range match for IPv6 addresses is provided.
             Note that the start IPv6 address must be lower than
             the end IPv6 address.";
        }
      }
    }
  }

  grouping user-group {
    description
      "This group represents user group information to label MAC
       addresses and IP (IPv4 or IPv6) addresses as a group of users.";
    leaf name {
      type string;
      description
        "This represents the name of a user-group.  A user-group name
         is used to map a user-group's name (e.g., employees) to IP
         address(es), MAC address(es).
         It is dependent on implementation.";
    }
    leaf-list mac-address {
      type yang:mac-address;
      description
        "Represent the MAC Address of a user-group. A user-group
         can have multiple MAC Addresses.";
    }
    uses ip-address-info{
      description
        "This represents the IP addresses of a user-group.";
      refine match-type{
        mandatory true;
      }
    }
  }

  grouping device-group {
    description
      "This group represents device group information to label
       IP (IPv4 or IPv6) addresses that provide services hosted
       on the application protocol.";
    leaf name {
      type string;
      description
        "This represents the name of a device-group.";
    }
    uses ip-address-info{
      description
        "This represents the IP addresses of a device-group.";
      refine match-type{
        mandatory true;
      }
    }
    leaf-list application-protocol {
      type identityref {
        base application-protocol;
      }
      description
        "This represents the application layer protocols of devices.
         If this is not set, it cannot support the appropriate
         protocol";
    }
  }

  grouping location-group {
    description
      "This group represents location-group information to map
       IPv4 or IPv6 address to the geographical location.";
    leaf country {
      type string {
        length "2";
        pattern "[a-zA-Z]{2}";
      }
      description
        "This represents the 2-letter ISO country code conforming to
         ISO3166-1 alpha 2. Examples include 'US' for United States,
         'JP' for Japan, and 'PL' for Poland.";
      reference
        "ISO 3166-1: Decoding table alpha-2 country code";
    }
    leaf region {
      type string {
        length "5..6";
        pattern "[a-zA-Z]{2}-[a-zA-Z0-9]{2,3}";
      }
      description
        "This represents the ISO region code conforming to ISO 3166-2.
         Examples include 'ID-RI' for Riau province of Indonesia and
         'NG-RI' for the Rivers province in Nigeria.";
      reference
        "ISO 3166-2: 3166-2 subdivision code";
    }
    leaf city {
      type string;
      description
        "This represents the city of a region. Examples include
         'Dublin', 'New York', and 'Sao Paulo'.";
    }
    uses ip-address-info{
      refine match-type{
        mandatory true;
        description
          "This represents the IP addresses of a location-group.";
      }
    }
  }

  grouping payload-string {
    description
      "The grouping for payload-string content.  It contains
       information such as name and string content.";
  }

  list i2nsf-cfi-policy {
    key "name";
    description
      "This is a security policy list.  Each policy in the list
       contains a list of security policy rules, and is a policy
       instance to have the information of where and when a policy
       needs to be applied.";
    leaf name {
      type string;
      description
        "The name which identifies the policy.";
    }
    leaf language {
      type string {
        pattern '((([A-Za-z]{2,3}(-[A-Za-z]{3}(-[A-Za-z]{3})'
              + '{0,2})?)|[A-Za-z]{4}|[A-Za-z]{5,8})(-[A-Za-z]{4})?'
              + '(-([A-Za-z]{2}|[0-9]{3}))?(-([A-Za-z0-9]{5,8}'
              + '|([0-9][A-Za-z0-9]{3})))*(-[0-9A-WYZa-wyz]'
              + '(-([A-Za-z0-9]{2,8}))+)*(-[Xx](-([A-Za-z0-9]'
              + '{1,8}))+)?|[Xx](-([A-Za-z0-9]{1,8}))+|'
              + '(([Ee][Nn]-[Gg][Bb]-[Oo][Ee][Dd]|[Ii]-'
              + '[Aa][Mm][Ii]|[Ii]-[Bb][Nn][Nn]|[Ii]-'
              + '[Dd][Ee][Ff][Aa][Uu][Ll][Tt]|[Ii]-'
              + '[Ee][Nn][Oo][Cc][Hh][Ii][Aa][Nn]'
              + '|[Ii]-[Hh][Aa][Kk]|'
              + '[Ii]-[Kk][Ll][Ii][Nn][Gg][Oo][Nn]|'
              + '[Ii]-[Ll][Uu][Xx]|[Ii]-[Mm][Ii][Nn][Gg][Oo]|'
              + '[Ii]-[Nn][Aa][Vv][Aa][Jj][Oo]|[Ii]-[Pp][Ww][Nn]|'
              + '[Ii]-[Tt][Aa][Oo]|[Ii]-[Tt][Aa][Yy]|'
              + '[Ii]-[Tt][Ss][Uu]|[Ss][Gg][Nn]-[Bb][Ee]-[Ff][Rr]|'
              + '[Ss][Gg][Nn]-[Bb][Ee]-[Nn][Ll]|[Ss][Gg][Nn]-'
              + '[Cc][Hh]-[Dd][Ee])|([Aa][Rr][Tt]-'
              + '[Ll][Oo][Jj][Bb][Aa][Nn]|[Cc][Ee][Ll]-'
              + '[Gg][Aa][Uu][Ll][Ii][Ss][Hh]|'
              + '[Nn][Oo]-[Bb][Oo][Kk]|[Nn][Oo]-'
              + '[Nn][Yy][Nn]|[Zz][Hh]-[Gg][Uu][Oo][Yy][Uu]|'
              + '[Zz][Hh]-[Hh][Aa][Kk][Kk][Aa]|[Zz][Hh]-'
              + '[Mm][Ii][Nn]|[Zz][Hh]-[Mm][Ii][Nn]-'
              + '[Nn][Aa][Nn]|[Zz][Hh]-[Xx][Ii][Aa][Nn][Gg])))';
      }
      default "en-US";
      description
        "The value in this field indicates the language tag
         used for all of the 'leaf description' described in the
         'i2nsf-cfi-policy'.

         The attribute is encoded following the rules in Section 2.1
         in RFC 5646. The default language tag is 'en-US'";
      reference
        "RFC 5646: Tags for Identifying Languages";
    }
    leaf resolution-strategy {
      type identityref {
        base resolution-strategy;
      }
      default fmr;
      description
        "The resolution strategies that can be used to
         specify how to resolve conflicts that occur between
         actions of the same or different policy rules that
         are matched and contained in this particular NSF";

      reference
        "draft-ietf-i2nsf-capability-data-model-32:
         I2NSF Capability YANG Data Model - Resolution strategy";
    }
    list rules {
      key "name";

      description
        "There can be a single or multiple number of rules.";
      leaf name {
        type string;
        description
          "This represents the name for a rule. Each rule name must
           be unique. Note that since this name is a key in the
           list of rules, its uniqueness is verified.";
      }

      leaf priority {
        type uint8 {
          range "1..255";
        }
        description
          "The priority keyword comes with a mandatory
           numeric value which can range from 1 through 255.
           Note that a higher number means a higher priority";
      }

      container event {
        description
          "This represents an event (i.e., a security event), for
           which a security rule is made.";
        leaf-list system-event {
          type identityref {
            base system-event;
          }
          description
            "The security policy rule according to
             system events.";
        }

        leaf-list system-alarm {
          type identityref {
            base system-alarm;
          }
          description
            "The security policy rule according to
             system alarms.";
        }
      }

      container condition {
        description
        "Conditions for general security policies.";
        container firewall {
          description
            "A general firewall condition based on the packet
             header.";
          leaf-list source {
            type union {
              type leafref {
                path "/endpoint-groups/user-group/name";
              }
              type leafref {
                path "/endpoint-groups/device-group/name";
              }
            }
            description
            "This describes the path of the source.";
          }

          leaf-list destination {
            type union {
              type leafref {
                path "/endpoint-groups/user-group/name";
              }
              type leafref {
                path "/endpoint-groups/device-group/name";
              }
            }
            description
              "This describes the path to the destinations.";
          }

          leaf transport-layer-protocol {
            type identityref {
              base transport-protocol;
            }
            description
              "The transport-layer protocol to be matched.";
          }

          list range-port-number {
            key "start end";
            leaf start {
              type inet:port-number;
              description
                "A start port number for a range match.";
            }
            leaf end {
              type inet:port-number;
              must '. >= ../start' {
                error-message
                  "An end port number MUST be equal to or greater than
                   a start port number.";
              }
              description
                "An end port number for a range match.";
            }
            description
              "A range match for transport-layer port number. Note
               that the start port number value must be lower than
               the end port number value";
          }

          container icmp {
            description
               "Represents the ICMPv4 and ICMPv6 packet header
                information to determine if the set of policy
                actions in this ECA policy rule should be executed
                or not.";
             reference
               "RFC  792: Internet Control Message Protocol
                RFC 8335: PROBE: A Utility for Probing Interfaces";

            leaf-list message {
              type identityref {
                base icmp-message;
              }
              description
                "The security policy rule according to
                 ICMP message. The type is representing the
                 ICMP message corresponds to the ICMP type and
                 code.";
              reference
                "RFC  792: Internet Control Message Protocol
                 RFC 8335: PROBE: A Utility for Probing Interfaces
                 IANA: Internet Control Message Protocol (ICMP)
                 Parameters
                 IANA: Internet Control Message Protocol version 6
                 (ICMPv6) Parameters";
            }
          }
        }

        container ddos {
          description
            "A condition for a DDoS attack.";
          container rate-limit {
            description
              "This describes the rate-limit.";
            leaf packet-rate-threshold {
              type uint64;
              units "pps";
              description
                "This is a trigger value for a rate limit of packet
                 rate in packets per second (pps) for a
                 DDoS-attack mitigation.";
            }
            leaf byte-rate-threshold {
              type uint64;
              units "Bps";
              description
                "This is a trigger value for a rate limit of byte
                 rate in bytes per second (Bps) for a DDoS-attack
                 mitigation.";
            }
            leaf flow-rate-threshold {
              type uint64;
              description
                "This is a trigger value for a rate limit of flow
                 creating request rate (e.g., new TCP connection
                 establishment) in flows per second for a DDoS-attack
                 mitigation.";
            }
          }
        }

        container anti-virus {
          description
           "A condition for anti-virus";

          leaf-list profile {
            type string;
            description
              "The path or name of the file that contains a security
               profile for the Antivirus interruption. The security
               profile is used to scan the viruses. The absolute
               paths and relative ones are to be interpreted as
               globs. The decision to perform or skip the Antivirus
               interruption depends on the action of the rule. A drop
               action uses the security profile for dropping either
               packets or flows in the Antivirus interruption. On the
               other hand, a pass action uses the security profile
               for allowing either packets or flows without the
               Antivirus interruption.";
            reference
              "GLOB: Linux Programmer's Manual - GLOB";
          }
        }

        container payload {
          description
            "A condition based on a packet's content.";
          leaf-list content {
            type leafref {
              path "/threat-prevention/payload-content/name";
            }
            description
              "This describes the paths to a packet content's";
          }
        }

        container url-category {
          description
            "Condition for url category";
          leaf url-name {
            type leafref {
              path "/endpoint-groups/url-group/name";
            }
            description
              "This is description for the condition of a URL's
               category such as SNS sites, game sites, ecommerce
               sites, company sites, and university sites.";
          }
        }

        container voice {
          description
            "For the VoIP/VoCN security system, a VoIP/
             VoCN security system can monitor each
             VoIP/VoCN flow and manage VoIP/VoCN
             security rules controlled by a centralized
             server for VoIP/VoCN security service
             (called VoIP IPS). The VoIP/VoCN security
             system controls each switch for the
             VoIP/VoCN call flow management by
             manipulating the rules that can be added,
             deleted, or modified dynamically.
             Note that VoIP is Voice over Internet Protocol
             and VoCN is Voice over Cellular Network such as
             Voice over LTE or 5G";
          reference
            "RFC 3261: SIP: Session Initiation Protocol";

          leaf-list source-id {
            type leafref {
              path "/endpoint-groups/voice-group/name";
            }
            description
              "The security policy rule according to
               the 'From' header field of the SIP.";
            reference
              "RFC 3261: SIP: Session Initiation Protocol
                         - Section 8.1.1.3 (From)";
          }

          leaf-list destination-id {
            type leafref {
              path "/endpoint-groups/voice-group/name";
            }
            description
              "The security policy rule according to
               the 'To' header field of the SIP.";
            reference
              "RFC 3261: SIP: Session Initiation Protocol
                         - Section 8.1.1.2 (To)";
          }

          leaf-list user-agent {
            type string;
            description
              "The security policy rule according to
               the 'user-agent' field of the SIP.";
            reference
              "RFC 3261: SIP: Session Initiation Protocol
                         - Section 20.41 (User-Agent)";
          }
        }

        container context {
          description
            "Condition for matching the context of the packet, such
             as geographic location, time, packet direction";
          container time {
            description
              "The time when a security policy rule should be
               applied.";
            leaf start-date-time {
              type yang:date-and-time;
              description
                "This is the start date and time for a security
                 policy rule.";
            }
            leaf end-date-time {
              type yang:date-and-time;
              description
                "This is the end date and time for a security policy
                 rule.  The policy rule will stop working after the
                 specified end date and time.";
            }
            container period {
              when
                "../frequency!='only-once'";
              description
                "This represents the repetition time.  In the case
                 where the frequency is weekly, the days can be
                 set.";
              leaf start-time {
                type time;
                description
                  "This is a period's start time for an event.";
              }
              leaf end-time {
                type time;
                description
                  "This is a period's end time for an event.";
              }
              leaf-list day {
                when
                  "../../frequency='weekly'";
                type day;
                min-elements 1;
                description
                  "This represents the repeated day of every week
                  (e.g., Monday and Tuesday).  More than one day can
                  be specified.";
              }
              leaf-list date {
                when
                  "../../frequency='monthly'";
                type int8 {
                  range "1..31";
                }
                min-elements 1;
                description
                  "This represents the repeated date of every month.
                   More than one date can be specified.";
              }
              leaf-list month {
                when
                  "../../frequency='yearly'";
                type string{
                  pattern '\d{2}-\d{2}';
                }
                min-elements 1;
                description
                  "This represents the repeated date and month of
                   every year.  More than one can be specified.
                   A pattern used here is Month and Date (MM-DD).";
              }
            }

            leaf frequency {
              type enumeration {
                enum only-once {
                  description
                    "This represents that the rule is immediately
                     enforced only once and not repeated. The policy
                     will continuously be active from the
                     start-date-time to the end-date-time.";
                }
                enum daily {
                  description
                    "This represents that the rule is enforced on a
                     daily basis. The policy will be repeated daily
                     until the end-date-time.";
                }
                enum weekly {
                  description
                    "This represents that the rule is enforced on a
                     weekly basis. The policy will be repeated weekly
                     until the end-date-time. The repeated days can
                     be specified.";
                }
                enum monthly {
                  description
                    "This represents that the rule is enforced on a
                     monthly basis. The policy will be repeated
                     monthly until the end-date-time.";
                }
                enum yearly {
                  description
                    "This represents that the rule is enforced on a
                     yearly basis.  The policy will be repeated
                     yearly until the end-date-time.";
                }
              }
              default only-once;
              description
                "This represents how frequently the rule should be
                 enforced.";
            }
          }

          container application {
            description
              "Condition for application";
            leaf-list protocol {
              type identityref {
                base application-protocol;
              }
              description
                "The condition based on the application layer
                 protocol";
            }
          }

          container device-type {
            description
              "Condition for type of the destination device";
            leaf-list device {
              type identityref {
                base device-type;
              }
              description
                "The device attribute that can identify a device (i.e.,
                 computer, mobile phone, smartphone, VoIP/VoCN phone,
                 tablet, network infrastructure device, IoT device,
                 OT device, and vehicle).";
            }
          }

          container users {
            description
              "Condition for users";
            list user {
              key "id";
              description
                "The user with which the traffic flow is associated
                 can be identified by either a user ID or username.
                 The user-to-IP address mapping is assumed to be
                 provided by the unified user management system via
                 network.";
              leaf id {
                type uint32;
                description
                  "The ID of the user.";
              }
              leaf name {
                type string;
                description
                  "The name of the user.";
              }
            }
            list group {
              key "id";
              description
                "The user group with which the traffic flow is
                 associated can be identified by either a group ID
                 or group name. The group-to-IP address and
                 user-to-group mappings are assumed to be provided by
                 the unified user management system via network.";
              leaf id {
                type uint32;
                description
                  "The ID of the group.";
              }
              leaf name {
                type string;
                description
                  "The name of the group.";
              }
            }
          }

          container geographic-location {
            description
              "A condition for a location-based connection";
            container source {
              leaf country {
                type leafref {
                  path "/endpoint-groups/location-group/country";
                }
                description
                  "The name of the country in the 2-letter ISO country
                   code conforming to ISO3166-1 alpha-2.";
                reference
                  "ISO 3166-1: Decoding table alpha-2 country code";
              }
              leaf region {
                type leafref {
                  path "/endpoint-groups/location-group/region";
                }
                description
                  "The region code conforming to ISO 3166-2.";
                reference
                  "ISO 3166-2: 3166-2 subdivision code.";
              }
              leaf city {
                type leafref {
                  path "/endpoint-groups/location-group/city";
                }
                description
                  "The name of the city of the location.";
              }
              description
                "This describes the paths to a location's source.
                 The values in this field will be mapped into
                 either IPv4 or IPv6 addresses defined in
                 /endpoint-groups/location-group.";
            }
            container destination {
              leaf country {
                type leafref {
                  path "/endpoint-groups/location-group/country";
                }
                description
                  "The name of the country in the 2-letter ISO country
                   code conforming to ISO3166-1 alpha-2.";
                reference
                  "ISO 3166-1: Decoding table alpha-2 country code";
              }
              leaf region {
                type leafref {
                  path "/endpoint-groups/location-group/region";
                }
                description
                  "The region code conforming to ISO 3166-2.";
                reference
                  "ISO 3166-2: 3166-2 subdivision code.";
              }
              leaf city {
                type leafref {
                  path "/endpoint-groups/location-group/city";
                }
                description
                  "The name of the city of the location.";
              }
              description
                "This describes the paths to a location's
                 destination. The values in this field will be
                 mapped into either IPv4 or IPv6 addresses defined in
                 /endpoint-groups/location-group.";
            }
          }
        }

        container threat-feed {
          description
            "A condition based on the threat-feed information.";
          leaf-list name {
            type leafref {
              path "/threat-prevention/threat-feed-list/name";
            }
            description
              "This describes the paths to a threat-feed's sources.";
          }
        }
      }

      container action {
        description
          "This is the action container.";
        container primary-action {
          description
            "This represents primary actions (e.g., ingress and
             egress actions) to be applied to a condition.
             If this is not set, it cannot support the primary
             actions.";
          leaf action {
            type identityref {
              base primary-action;
            }
            mandatory true;
            description
              "Ingress actions: pass, drop, reject, rate-limit,
               and mirror.
               Egress actions: pass, drop, reject, rate-limit,
               mirror, invoke-signaling, tunnel-encapsulation,
               forwarding, and transformation.";
          }
          leaf limit {
            when "../action = 'i2nsfcfi:rate-limit'" {
              description
                "Rate-limit is valid only when rate-limit action is
                 used.";
            }
            type decimal64 {
              fraction-digits 2;
            }
            units "bytes per second";
            description
              "Specifies how to rate-limit the traffic.";
          }
        }
        container secondary-action {
          description
            "This represents secondary actions (e.g., log and syslog)
             to be applied if they are needed.  If this is not set,
             it cannot support the secondary actions.";
          leaf log-action {
            type identityref {
              base secondary-action;
            }
            description
              "Log action: rule log and session log";
          }
        }
      }
    }
  }

  container endpoint-groups {
    description
      "A logical entity in a business environment, where a security
       policy is to be applied.";
    list user-group{
      uses user-group;
      key "name";
      description
        "This represents a user group.";
    }
    list device-group {
      key "name";
      uses device-group;
      description
        "This represents a device group.";
    }
    list location-group{
      key "country region city";
      uses location-group;
      description
        "This represents a location group.";
    }
    list url-group {
      key "name";
      description
        "This describes the list of URL.";
      leaf name {
        type string;
        description
          "This is the name of URL group, e.g., SNS sites,
           gaming sites, ecommerce sites";
      }
      leaf-list url {
        type inet:uri;
        description
          "Specifies the URL to be added into the group.";
        reference
          "RFC 3986: Uniform Resource Identifier (URI): Generic
           Syntax";
      }
    }
    list voice-group {
      key "name";
      description
        "This describes the list of Voice ID";
      leaf name {
        type string;
        description
          "This is the name of the voice group.";
      }
      leaf-list sip-id {
        type inet:uri;
        description
          "Specifies the logical identity of the SIP user written in
           SIP URI scheme.";
        reference
          "RFC3261: SIP: Session Initiation Protocol
                    - Section 19.1.1 (SIP and SIPS URI Components)";
      }
    }
  }

  container threat-prevention {
    description
      "The container for threat-prevention.";
    list threat-feed-list {
      key "name";
      description
        "There can be a single or multiple number of
         threat-feeds.";
      leaf name {
        type string;
        description
          "This represents the name of the threat-feed.";
      }
      leaf-list ioc {
        type string;
        description
          "This field represents the Indicators of Compromise (IOC),
           i.e., the critical information of patterns or characteristics
           (signatures) in the threat feed that identifies malicious
           activities. The format of the information given in this field
           should be parsed based on the format field (e.g., STIX, MISP,
           OpenIOC, and IODEF).";
      }
      leaf format {
        type identityref {
          base ioc-format;
        }
        mandatory true;
        description
          "This represents the format of the IOC information. This
           field is mandatory to parse the IOC. The examples of the
           format are STIX, MISP, OpenIOC, and IODEF.";
        reference
          "STIX: Structured Threat Information Expression version 2.1
           MISPCORE: Malware Information Sharing Platform (MISP) Core
           Format
           OPENIOC: OpenIOC 1.1 Schema document
           RFC 8727: JSON Binding of the Incident Object Description
           Exchange Format";
      }
    }

    list payload-content {
      key "name";
      leaf name {
        type string;
        description
          "This represents the name of a packet's payload-content.
           It should give an idea of why a specific payload content
           is marked as a threat.  For example, the name 'backdoor'
           indicates the payload content is related to a backdoor
           attack.";
      }
      leaf description {
        type string;
        description
          "This represents the description of a payload. Describe
           how the payload contents are related to a security
           attack.";
      }
      list contents {
        key "content";
        ordered-by user;
        leaf content {
          type binary;
          description
            "This represents the pattern of the payload contents (i.e.,
             the data after a transport layer header) to be matched.
             Due to the types of threats, the type of the content is
             defined as a binary to accommodate any kind of a payload
             type such as HTTP, HTTPS, and SIP.

             If multiple instances of content are defined, it should
             match all contents somewhere in the session stream. The
             content pattern should be matched based on the order
             given by the user. The scope of the payload to be matched
             can be defined by the depth and offset/distance fields.";
        }
        leaf depth {
          type uint16 {
            range "1..max";
          }
          units "bytes";
          description
            "The field specifies how far a packet should be searched
             for the specified content pattern defined in the content
             field. For example, a depth of 5 means to only look for
             the specified content pattern within the first 5 bytes
             of the payload. This field accept values greater than or
             equal to the content length being searched. If this
             field is undefined, then the content pattern should be
             searched within the whole payload.";
        }
        choice starting-point {
          description
            "Choice of how to specify the starting point of matching
             the pattern to the payload. If this field is undefined,
             then the content pattern should be searched from the
             beginning of the payload.";
          case offset {
            leaf offset {
              type int32;
              units "bytes";
              description
                "The field specifies where to start searching for the
                 specified content pattern within the payload.
                 For example, an offset of 5 means to start looking for
                 the specified content pattern after the first 5 bytes
                 of the payload.";
            }
          }
          case distance {
            leaf distance {
              type int32;
              units "bytes";
              description
                "The field specifies how far a payload should be
                 ignored before starting to search for the specified
                 content pattern relative to the end of the previous
                 specified content pattern match. This can be thought
                 of as exactly the same thing as offset, except it is
                 relative to the end of the last pattern match instead
                 of the beginning of the packet. For example, a distance
                 of 5 means to start looking for the specified content
                 pattern 5 bytes after the last byte of the matched
                 pattern.

                 Note that this field cannot be used if the content is
                 the first order of the list.";
            }
          }
        }
        description
          "List of contents and their scopes for matching content
           pattern with the payload";
      }
      description
        "This represents a payload-string group.";
    }
  }
}

<CODE ENDS>
Figure 18: YANG for Consumer-Facing Interface

7. XML Configuration Examples of High-Level Security Policy Rules

This section shows XML configuration examples of high-level security policy rules that are delivered from the I2NSF User to the Security Controller over the Consumer-Facing Interface. The considered examples are: Database registration, time-based firewall for web filtering, VoIP/VoCN security service, and DDoS-attack mitigation.

7.1. Database Registration: Information of Positions and Devices (Endpoint Group)

The endpoint-group is used to register known network nodes and label them into a higher-level name (i.e., human recognizable language). If new endpoints are introduced to the network, it is necessary to first register their data to the database. For example, if new members are newly introduced in different groups (i.e., user-group, device-group, url-group, and voice-group), each of them should be registered as separate entities with their corresponding information.

<?xml version="1.0" encoding="UTF-8" ?>
<endpoint-groups
 xmlns="urn:ietf:params:xml:ns:yang:ietf-i2nsf-cons-facing-interface">
  <user-group>
    <name>employees</name>
    <range-ipv4-address>
      <start>192.0.2.11</start>
      <end>192.0.2.90</end>
    </range-ipv4-address>
  </user-group>
  <device-group>
    <name>webservers</name>
    <range-ipv4-address>
      <start>198.51.100.11</start>
      <end>198.51.100.20</end>
    </range-ipv4-address>
    <application-protocol>http</application-protocol>
    <application-protocol>https</application-protocol>
  </device-group>
  <url-group>
    <name>sns-websites</name>
    <url>https://www.sns-example1.com/</url>
    <url>https://www.sns-example2.com/</url>
  </url-group>
  <voice-group>
    <name>malicious-id</name>
    <sip-id>sip:alice@atlanta.com</sip-id>
    <sip-id>sip:bob@203.0.113.15</sip-id>
    <sip-id>sip:carol@chicago.com</sip-id>
  </voice-group>
</endpoint-groups>

Figure 19: Registering User-group, Device-group, Voice-group in IPv4 Addresses, and URL-group Information

Figure 19 shows an example XML representation of the registered information for the user-group, device-group, voice-group in IPv4 address [RFC5737], and url-group.

  1. The IPv4 addresses from 192.0.2.11 to 192.0.2.90 are labeled as a group of users called "employees".
  2. The IPv4 addresses from 198.51.100.11 to 198.51.100.20 provide services with HTTP and HTTPS application protocol labeled as "webservers".
  3. The "https://www.sns-example1.com/" and "https://www.sns-example2.com/" URLs are labeled as "sns-websites".
  4. The "sip:alice@atlanta.com", "sip:bob@203.0.113.15", and "sip:carol@chicago.com" SIP identities are labeled as "malicious-id".
<?xml version="1.0" encoding="UTF-8" ?>
<endpoint-groups
 xmlns="urn:ietf:params:xml:ns:yang:ietf-i2nsf-cons-facing-interface">
  <user-group>
    <name>employees-v6</name>
    <range-ipv6-address>
      <start>2001:db8:0:1::11</start>
      <end>2001:db8:0:1::90</end>
    </range-ipv6-address>
  </user-group>
  <device-group>
    <name>webservers-v6</name>
    <range-ipv6-address>
      <start>2001:db8:0:2::11</start>
      <end>2001:db8:0:2::20</end>
    </range-ipv6-address>
    <application-protocol>http</application-protocol>
    <application-protocol>https</application-protocol>
  </device-group>
  <voice-group>
    <name>malicious-id-v6</name>
    <sip-id>sip:david@2001:db8:2ef0::32b7</sip-id>
  </voice-group>
</endpoint-groups>

Figure 20: Registering User-group, Device-group, Voice-group Information in IPv6 Addresses

Also, Figure 20 shows an example XML representation of the registered information for the user-group, device-group, and voice-group in IPv6 addresses [RFC3849].

  1. The IPv6 addresses from 2001:db8:0:1::11 to 2001:db8:0:1::90 are labeled as a group of users called "employees-v6".
  2. The IPv6 addresses from 2001:db8:0:2::11 to 2001:db8:0:2::20 provide services with HTTP and HTTPS application protocol labeled as "webservers-v6".
  3. The "sip:david@[2001:db8:2ef0::32b7]" SIP identity is labeled as "malicious-id-v6".

7.2. Scenario 1: Block SNS Access during Business Hours

The first example scenario is to "block SNS access during office hours" using a time-based firewall policy. In this scenario, all users registered as "employees" in the user-group list are unable to access Social Networking Services (SNS) during the office hours (weekdays). The XML instance is described below:

<?xml version="1.0" encoding="UTF-8" ?>
<i2nsf-cfi-policy
 xmlns="urn:ietf:params:xml:ns:yang:ietf-i2nsf-cons-facing-interface">
  <name>security_policy_for_blocking_sns</name>
  <rules>
    <name>block_access_to_sns_during_office_hours</name>
    <condition>
      <firewall>
        <source>employees</source>
      </firewall>
      <url-category>
        <url-name>sns-websites</url-name>
      </url-category>
      <context>
        <time>
          <start-date-time>2021-03-11T09:00:00.00Z</start-date-time>
          <end-date-time>2021-12-31T18:00:00.00Z</end-date-time>
          <period>
            <start-time>09:00:00Z</start-time>
            <end-time>18:00:00Z</end-time>
            <day>monday</day>
            <day>tuesday</day>
            <day>wednesday</day>
            <day>thursday</day>
            <day>friday</day>
          </period>
          <frequency>weekly</frequency>
        </time>
      </context>
    </condition>
    <action>
      <primary-action>
        <action>drop</action>
      </primary-action>
    </action>
  </rules>
</i2nsf-cfi-policy>

Figure 21: An XML Example for Time-based Firewall

Time-based-condition Firewall

  1. The policy name is "security_policy_for_blocking_sns".
  2. The rule name is "block_access_to_sns_during_office_hours".
  3. The Source is "employees".
  4. The destination target is "sns-websites". "sns-websites" is the key which represents the list containing the information, such as URL, about sns-websites.
  5. The action required is to "drop" any attempt to connect to websites related to Social networking.

7.3. Scenario 2: Block Malicious VoIP/VoCN Packets Coming to a Company

The second example scenario is to "block malicious VoIP/VoCN packets coming to a company" using a VoIP policy. In this scenario, the calls coming from VOIP and/or VoCN sources with VoCN IDs that are classified as malicious are dropped. The IP addresses of the employees and malicious VOIP IDs should be blocked are stored in the database or datastore of the enterprise. Here and the rest of the cases assume that the security administrators or someone responsible for the existing and newly generated policies, are not aware of which and/or how many NSFs are needed to meet the security requirements. Figure 22 represents the XML document generated from YANG discussed in previous sections. Once a high-level security policy is created by a security admin, it is delivered by the Consumer-Facing Interface, through RESTCONF server, to the security controller. The XML instance is described below:

<?xml version="1.0" encoding="UTF-8" ?>
<i2nsf-cfi-policy
 xmlns="urn:ietf:params:xml:ns:yang:ietf-i2nsf-cons-facing-interface">
  <name>
    security_policy_for_blocking_malicious_voip_packets
  </name>
  <rules>
    <name>Block_malicious_voip_and_vocn_packets</name>
    <condition>
      <voice>
        <source-id>malicious-id</source-id>
      </voice>
      <firewall>
        <destination>employees</destination>
      </firewall>
    </condition>
    <action>
      <primary-action>
        <action>drop</action>
      </primary-action>
    </action>
  </rules>
</i2nsf-cfi-policy>

Figure 22: An XML Example for VoIP Security Service

Custom-condition Firewall

  1. The policy name is "security_policy_for_blocking_malicious_voip_packets".
  2. The rule name is "Block_malicious_voip_and_vocn_packets".
  3. The source is "malicious-id". The "malicious-id" is the key, so that it maps to the SIP identities that are named as "malicious-id". This can be a single SIP identity or a list of SIP identities.
  4. The destination target is "employees". "employees" is the key which represents the list containing information about employees, such as IP addresses.
  5. The action required is "drop" when any incoming SIP packets are coming from "malicious-id" and targeting "employees".

7.4. Scenario 3: Mitigate Flood Attacks on a Company Web Server

The third example scenario is to "Mitigate flood attacks on a company web server" using a DDoS-attack mitigation policy. Here, the time information is not set because the service provided by the network should be maintained at all times. If the packets sent by any sources that target "webservers" are more than the set threshold, then the admin can set the percentage of the packets to be dropped to safely maintain the service. Once the rule is set and delivered and enforced to the NSFs by the security controller, the NSFs will monitor the incoming packet amounts to act according to the rule set. The XML instance is described below:

<?xml version="1.0" encoding="UTF-8" ?>
<i2nsf-cfi-policy
  xmlns="urn:ietf:params:xml:ns:yang:ietf-i2nsf-cons-facing-interface">
  <name>security_policy_for_ddos_attacks</name>
  <rules>
    <name>1000_packets_per_second</name>
    <condition>
      <firewall>
        <destination>webservers</destination>
      </firewall>
      <ddos>
        <rate-limit>
          <packet-rate-threshold>1000</packet-rate-threshold>
        </rate-limit>
      </ddos>
    </condition>
    <action>
      <primary-action>
        <action>drop</action>
      </primary-action>
    </action>
  </rules>
</i2nsf-cfi-policy>

Figure 23: An XML Example for DDoS-attack Mitigation

DDoS-condition Firewall

  1. The policy name is "security_policy_for_ddos_attacks".
  2. The rule name is "1000_packets_per_second".
  3. The destination is webservers.
  4. The rate limit exists to limit the incoming amount of packets per second. In this case the rate limit is "1000" packets per second. This amount depends on the packet receiving capacity of the server devices.
  5. The Source is all sources which send abnormal amount of packets. It is assumed that there is a counter per source IP address in this DDoS-condition Firewall. The rate of "1000" packets per second is set for each source to send packets toward the destinations as webservers.
  6. The action required is to "drop" when the packet reception is more than "1000" packets per second for each source that sends packets to the destinations.

8. IANA Considerations

This document requests IANA to register the following URI in the "IETF XML Registry" [RFC3688]:

URI: urn:ietf:params:xml:ns:yang:ietf-i2nsf-cons-facing-interface
Registrant Contact: The IESG.
XML: N/A; the requested URI is an XML namespace.

This document requests IANA to register the following YANG module in the "YANG Module Names" registry [RFC7950][RFC8525]:

name: ietf-i2nsf-cons-facing-interface
namespace: urn:ietf:params:xml:ns:yang:ietf-i2nsf-cons-facing-interface
prefix: i2nsfcfi
reference: RFC XXXX

// RFC Ed.: replace XXXX with an actual RFC number and remove
// this note.

9. Security Considerations

The YANG module specified in this document defines a data schema designed to be accessed through network management protocols such as NETCONF [RFC6241] or RESTCONF [RFC8040]. The lowest NETCONF layer is the secure transport layer, and the required secure transport is Secure Shell (SSH) [RFC6242]. The lowest RESTCONF layer is HTTPS, and the required secure transport is TLS [RFC8446].

The Network Configuration Access Control Model (NACM) [RFC8341] provides a means of restricting access to specific NETCONF or RESTCONF users to a preconfigured subset of all available NETCONF or RESTCONF protocol operations and contents. Thus, NACM SHOULD be used to restrict the NSF registration from unauthorized users.

There are a number of data nodes defined in this YANG module that are writable, creatable, and deletable (i.e., config true, which is the default). These data nodes may be considered sensitive or vulnerable in some network environments. Write operations to these data nodes could have a negative effect on network and security operations. These data nodes have the following sensitivity/vulnerability:

Some of the readable data nodes in this YANG module may be considered sensitive or vulnerable in some network environments. It is thus important to control read access (e.g., via get, get-config, or notification) to these data nodes. These are the subtrees and data nodes with their sensitivity/vulnerability:

10. References

10.1. Normative References

[RFC0768]
Postel, J., "User Datagram Protocol", STD 6, RFC 768, DOI 10.17487/RFC0768, , <https://www.rfc-editor.org/info/rfc768>.
[RFC0792]
Postel, J., "Internet Control Message Protocol", STD 5, RFC 792, DOI 10.17487/RFC0792, , <https://www.rfc-editor.org/info/rfc792>.
[RFC0854]
Postel, J. and J. Reynolds, "Telnet Protocol Specification", STD 8, RFC 854, DOI 10.17487/RFC0854, , <https://www.rfc-editor.org/info/rfc854>.
[RFC0959]
Postel, J. and J. Reynolds, "File Transfer Protocol", STD 9, RFC 959, DOI 10.17487/RFC0959, , <https://www.rfc-editor.org/info/rfc959>.
[RFC1939]
Myers, J. and M. Rose, "Post Office Protocol - Version 3", STD 53, RFC 1939, DOI 10.17487/RFC1939, , <https://www.rfc-editor.org/info/rfc1939>.
[RFC2119]
Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, , <https://www.rfc-editor.org/info/rfc2119>.
[RFC2595]
Newman, C., "Using TLS with IMAP, POP3 and ACAP", RFC 2595, DOI 10.17487/RFC2595, , <https://www.rfc-editor.org/info/rfc2595>.
[RFC3261]
Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston, A., Peterson, J., Sparks, R., Handley, M., and E. Schooler, "SIP: Session Initiation Protocol", RFC 3261, DOI 10.17487/RFC3261, , <https://www.rfc-editor.org/info/rfc3261>.
[RFC3688]
Mealling, M., "The IETF XML Registry", BCP 81, RFC 3688, DOI 10.17487/RFC3688, , <https://www.rfc-editor.org/info/rfc3688>.
[RFC3986]
Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform Resource Identifier (URI): Generic Syntax", STD 66, RFC 3986, DOI 10.17487/RFC3986, , <https://www.rfc-editor.org/info/rfc3986>.
[RFC4250]
Lehtinen, S. and C. Lonvick, Ed., "The Secure Shell (SSH) Protocol Assigned Numbers", RFC 4250, DOI 10.17487/RFC4250, , <https://www.rfc-editor.org/info/rfc4250>.
[RFC4340]
Kohler, E., Handley, M., and S. Floyd, "Datagram Congestion Control Protocol (DCCP)", RFC 4340, DOI 10.17487/RFC4340, , <https://www.rfc-editor.org/info/rfc4340>.
[RFC4443]
Conta, A., Deering, S., and M. Gupta, Ed., "Internet Control Message Protocol (ICMPv6) for the Internet Protocol Version 6 (IPv6) Specification", STD 89, RFC 4443, DOI 10.17487/RFC4443, , <https://www.rfc-editor.org/info/rfc4443>.
[RFC5321]
Klensin, J., "Simple Mail Transfer Protocol", RFC 5321, DOI 10.17487/RFC5321, , <https://www.rfc-editor.org/info/rfc5321>.
[RFC5646]
Phillips, A., Ed. and M. Davis, Ed., "Tags for Identifying Languages", BCP 47, RFC 5646, DOI 10.17487/RFC5646, , <https://www.rfc-editor.org/info/rfc5646>.
[RFC6241]
Enns, R., Ed., Bjorklund, M., Ed., Schoenwaelder, J., Ed., and A. Bierman, Ed., "Network Configuration Protocol (NETCONF)", RFC 6241, DOI 10.17487/RFC6241, , <https://www.rfc-editor.org/info/rfc6241>.
[RFC6242]
Wasserman, M., "Using the NETCONF Protocol over Secure Shell (SSH)", RFC 6242, DOI 10.17487/RFC6242, , <https://www.rfc-editor.org/info/rfc6242>.
[RFC6991]
Schoenwaelder, J., Ed., "Common YANG Data Types", RFC 6991, DOI 10.17487/RFC6991, , <https://www.rfc-editor.org/info/rfc6991>.
[RFC7950]
Bjorklund, M., Ed., "The YANG 1.1 Data Modeling Language", RFC 7950, DOI 10.17487/RFC7950, , <https://www.rfc-editor.org/info/rfc7950>.
[RFC8040]
Bierman, A., Bjorklund, M., and K. Watsen, "RESTCONF Protocol", RFC 8040, DOI 10.17487/RFC8040, , <https://www.rfc-editor.org/info/rfc8040>.
[RFC8075]
Castellani, A., Loreto, S., Rahman, A., Fossati, T., and E. Dijk, "Guidelines for Mapping Implementations: HTTP to the Constrained Application Protocol (CoAP)", RFC 8075, DOI 10.17487/RFC8075, , <https://www.rfc-editor.org/info/rfc8075>.
[RFC8174]
Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, , <https://www.rfc-editor.org/info/rfc8174>.
[RFC8335]
Bonica, R., Thomas, R., Linkova, J., Lenart, C., and M. Boucadair, "PROBE: A Utility for Probing Interfaces", RFC 8335, DOI 10.17487/RFC8335, , <https://www.rfc-editor.org/info/rfc8335>.
[RFC8340]
Bjorklund, M. and L. Berger, Ed., "YANG Tree Diagrams", BCP 215, RFC 8340, DOI 10.17487/RFC8340, , <https://www.rfc-editor.org/info/rfc8340>.
[RFC8341]
Bierman, A. and M. Bjorklund, "Network Configuration Access Control Model", STD 91, RFC 8341, DOI 10.17487/RFC8341, , <https://www.rfc-editor.org/info/rfc8341>.
[RFC8342]
Bjorklund, M., Schoenwaelder, J., Shafer, P., Watsen, K., and R. Wilton, "Network Management Datastore Architecture (NMDA)", RFC 8342, DOI 10.17487/RFC8342, , <https://www.rfc-editor.org/info/rfc8342>.
[RFC8407]
Bierman, A., "Guidelines for Authors and Reviewers of Documents Containing YANG Data Models", BCP 216, RFC 8407, DOI 10.17487/RFC8407, , <https://www.rfc-editor.org/info/rfc8407>.
[RFC8446]
Rescorla, E., "The Transport Layer Security (TLS) Protocol Version 1.3", RFC 8446, DOI 10.17487/RFC8446, , <https://www.rfc-editor.org/info/rfc8446>.
[RFC8525]
Bierman, A., Bjorklund, M., Schoenwaelder, J., Watsen, K., and R. Wilton, "YANG Library", RFC 8525, DOI 10.17487/RFC8525, , <https://www.rfc-editor.org/info/rfc8525>.
[RFC8727]
Takahashi, T., Danyliw, R., and M. Suzuki, "JSON Binding of the Incident Object Description Exchange Format", RFC 8727, DOI 10.17487/RFC8727, , <https://www.rfc-editor.org/info/rfc8727>.
[RFC9051]
Melnikov, A., Ed. and B. Leiba, Ed., "Internet Message Access Protocol (IMAP) - Version 4rev2", RFC 9051, DOI 10.17487/RFC9051, , <https://www.rfc-editor.org/info/rfc9051>.
[RFC9110]
Fielding, R., Ed., Nottingham, M., Ed., and J. Reschke, Ed., "HTTP Semantics", STD 97, RFC 9110, DOI 10.17487/RFC9110, , <https://www.rfc-editor.org/info/rfc9110>.
[RFC9112]
Fielding, R., Ed., Nottingham, M., Ed., and J. Reschke, Ed., "HTTP/1.1", STD 99, RFC 9112, DOI 10.17487/RFC9112, , <https://www.rfc-editor.org/info/rfc9112>.
[RFC9113]
Thomson, M., Ed. and C. Benfield, Ed., "HTTP/2", RFC 9113, DOI 10.17487/RFC9113, , <https://www.rfc-editor.org/info/rfc9113>.
[RFC9260]
Stewart, R., Tüxen, M., and K. Nielsen, "Stream Control Transmission Protocol", RFC 9260, DOI 10.17487/RFC9260, , <https://www.rfc-editor.org/info/rfc9260>.
[RFC9293]
Eddy, W., Ed., "Transmission Control Protocol (TCP)", STD 7, RFC 9293, DOI 10.17487/RFC9293, , <https://www.rfc-editor.org/info/rfc9293>.
[I-D.ietf-i2nsf-capability-data-model]
Hares, S., Jeong, J. P., Kim, J. T., Moskowitz, R., and Q. Lin, "I2NSF Capability YANG Data Model", Work in Progress, Internet-Draft, draft-ietf-i2nsf-capability-data-model-32, , <https://datatracker.ietf.org/doc/html/draft-ietf-i2nsf-capability-data-model-32>.
[I-D.ietf-i2nsf-nsf-monitoring-data-model]
Jeong, J. P., Lingga, P., Hares, S., Xia, L., and H. Birkholz, "I2NSF NSF Monitoring Interface YANG Data Model", Work in Progress, Internet-Draft, draft-ietf-i2nsf-nsf-monitoring-data-model-20, , <https://datatracker.ietf.org/doc/html/draft-ietf-i2nsf-nsf-monitoring-data-model-20>.
[MISPCORE]
Dulaunoy, A. and A. Iklody, "MISP Core (branch main)", , <https://github.com/MISP/misp-rfc/blob/main/misp-core-format/raw.md.txt>.
[OPENIOC]
Gibb, W., "OpenIOC 1.1 DRAFT (branch master)", , <https://github.com/fireeye/OpenIOC_1.1>.
[STIX]
Jordan, B., Piazza, R., and T. Darley, "Structured Threat Information Expression (STIX)", STIX Version 2.1 https://docs.oasis-open.org/cti/stix/v2.1/os/stix-v2.1-os.html, .

10.2. Informative References

[RFC3022]
Srisuresh, P. and K. Egevang, "Traditional IP Network Address Translator (Traditional NAT)", RFC 3022, DOI 10.17487/RFC3022, , <https://www.rfc-editor.org/info/rfc3022>.
[RFC3444]
Pras, A. and J. Schoenwaelder, "On the Difference between Information Models and Data Models", RFC 3444, DOI 10.17487/RFC3444, , <https://www.rfc-editor.org/info/rfc3444>.
[RFC3849]
Huston, G., Lord, A., and P. Smith, "IPv6 Address Prefix Reserved for Documentation", RFC 3849, DOI 10.17487/RFC3849, , <https://www.rfc-editor.org/info/rfc3849>.
[RFC5737]
Arkko, J., Cotton, M., and L. Vegoda, "IPv4 Address Blocks Reserved for Documentation", RFC 5737, DOI 10.17487/RFC5737, , <https://www.rfc-editor.org/info/rfc5737>.
[RFC8329]
Lopez, D., Lopez, E., Dunbar, L., Strassner, J., and R. Kumar, "Framework for Interface to Network Security Functions", RFC 8329, DOI 10.17487/RFC8329, , <https://www.rfc-editor.org/info/rfc8329>.
[RFC9000]
Iyengar, J., Ed. and M. Thomson, Ed., "QUIC: A UDP-Based Multiplexed and Secure Transport", RFC 9000, DOI 10.17487/RFC9000, , <https://www.rfc-editor.org/info/rfc9000>.
[GLOB]
"Linux Programmer's Manual - GLOB", , <https://manpages.ubuntu.com/manpages/jammy/en/man7/glob.7.html>.
[IANA-ICMP-Parameters]
Internet Assigned Numbers Authority (IANA), "Assigned Internet Protocol Numbers", , <https://www.iana.org/assignments/icmp-parameters/icmp-parameters.xhtml>.
[IANA-ICMPv6-Parameters]
Internet Assigned Numbers Authority (IANA), "Internet Control Message Procotol version 6 (ICMPv6) Parameters", , <https://www.iana.org/assignments/icmpv6-parameters/icmpv6-parameters.xhtml>.
[ISO-3166-1alpha2]
ISO, "ISO 3166-1 decoding table", <http://www.iso.org/iso/home/standards/country_codes/iso-3166-1_decoding_table.htm>.
[ISO-3166-2]
ISO, "ISO 3166-2:2007", <http://www.iso.org/iso/home/standards/country_codes.htm#2012_iso3166-2>.
[TR-29.949-3GPP]
3GPP, "Study on technical aspects on roaming end-to-end scenarios with Voice over LTE (VoLTE) IP Multimedia Subsystem (IMS) and other networks", 3GPP TR 29.949/Version 16.0.0, .
[TR-21.915-3GPP]
3GPP, "Summary of Rel-15 Work Items", 3GPP TR 21.915/Version 15.0.0, .

Appendix A. Acknowledgments

This document is a product by the I2NSF Working Group (WG) including WG Chairs (i.e., Linda Dunbar and Yoav Nir) and Diego Lopez. This document took advantage of the review and comments from the following people: Roman Danyliw, Mahdi F. Dachmehchi, Daeyoung Hyun, Jan Lindblad (YANG doctor), Tom Petch, Charlie Kaufman, Penglin Yang, and Jung-Soo Park. The authors sincerely appreciate their sincere efforts and kind help.

This work was supported by Institute of Information & Communications Technology Planning & Evaluation (IITP) grant funded by the Korea MSIT (Ministry of Science and ICT) (R-20160222-002755, Cloud based Security Intelligence Technology Development for the Customized Security Service Provisioning). This work was supported in part by the IITP (2020-0-00395-003, Standard Development of Blockchain based Network Management Automation Technology).

Appendix B. Contributors

The following are co-authors of this document:

Patrick Lingga - Department of Electrical and Computer Engineering, Sungkyunkwan University, 2066 Seo-ro Jangan-gu, Suwon, Gyeonggi-do 16419, Republic of Korea. EMail: patricklink@skku.edu

Jinyong Tim Kim - Department of Electronic, Electrical and Computer Engineering, Sungkyunkwan University, 2066 Seo-ro Jangan-gu, Suwon, Gyeonggi-do 16419, Republic of Korea. EMail: timkim@skku.edu

Hyoungshick Kim - Department of Computer Science and Engineering, Sungkyunkwan University, 2066 Seo-ro Jangan-gu, Suwon, Gyeonggi-do 16419, Republic of Korea. EMail: hyoung@skku.edu

Eunsoo Kim - Department of Electronic, Electrical and Computer Engineering, Sungkyunkwan University, 2066 Seo-ro Jangan-gu, Suwon, Gyeonggi-do 16419, Republic of Korea. EMail: eskim86@skku.edu

Seungjin Lee - Department of Electronic, Electrical and Computer Engineering, Sungkyunkwan University, 2066 Seo-ro Jangan-gu, Suwon, Gyeonggi-do 16419, Republic of Korea. EMail: jine33@skku.edu

Anil Lohiya - Juniper Networks, 1133 Innovation Way, Sunnyvale, CA 94089, US. EMail: alohiya@juniper.net

Dave Qi - Bloomberg, 731 Lexington Avenue, New York, NY 10022, US. EMail: DQI@bloomberg.net

Nabil Bitar - Nokia, 755 Ravendale Drive, Mountain View, CA 94043, US. EMail: nabil.bitar@nokia.com

Senad Palislamovic - Nokia, 755 Ravendale Drive, Mountain View, CA 94043, US. EMail: senad.palislamovic@nokia.com

Liang Xia - Huawei, 101 Software Avenue, Nanjing, Jiangsu 210012, China. EMail: Frank.Xialiang@huawei.com

Appendix C. Changes from draft-ietf-i2nsf-consumer-facing-interface-dm-24

The following changes are made from draft-ietf-i2nsf-consumer-facing-interface-dm-24:

Authors' Addresses

Jaehoon Paul Jeong (editor)
Department of Computer Science and Engineering
Sungkyunkwan University
2066 Seobu-Ro, Jangan-Gu
Suwon
Gyeonggi-Do
16419
Republic of Korea
Chaehong Chung
Department of Electronic, Electrical and Computer Engineering
Sungkyunkwan University
2066 Seobu-Ro, Jangan-Gu
Suwon
Gyeonggi-Do
16419
Republic of Korea
Tae-Jin Ahn
Korea Telecom
70 Yuseong-Ro, Yuseong-Gu
Daejeon
305-811
Republic of Korea
Rakesh Kumar
Juniper Networks
1133 Innovation Way
Sunnyvale, CA 94089
United States of America
Susan Hares
Huawei
7453 Hickory Hill
Saline, MI 48176
United States of America