Network Working Group
Internet Engineering Task Force (IETF)                       J. Peterson
Internet-Draft
Request for Comments: 8396                                    T. McGarry
Intended status:
Category: Informational                                    NeuStar, Inc.
Expires: September 6, 2018                                 March 5,
ISSN: 2070-1721                                                 May 2018

           Modern

 Managing, Ordering, Distributing, Exposing, and Registering Telephone
     Numbers (MODERN): Problem Statement, Use Cases, and Framework
               draft-ietf-modern-problem-framework-04.txt

Abstract

   The functions of the public switched telephone network Public Switched Telephone Network (PSTN) are
   rapidly migrating to the Internet.  This is generating new
   requirements for many traditional elements of the PSTN, including
   telephone numbers
   Telephone Numbers (TNs).  TNs no longer serve simply as telephone
   routing addresses: they are now identifiers which that may be used by
   Internet-based services for a variety of purposes including session
   establishment, identity verification, and service enablement.  This
   problem statement examines how the existing tools for allocating and
   managing telephone numbers do not align with the use cases of the
   Internet environment, environment and proposes a framework for Internet-based
   services relying on TNs.

Status of This Memo

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   Internet-Drafts are working documents not an Internet Standards Track specification; it is
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   This Internet-Draft will expire on September 6, 2018.
   https://www.rfc-editor.org/info/rfc8396.

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Table of Contents

   1.  Problem Statement . . . . . . . . . . . . . . . . . . . . . .   2
   2.  Definitions . . . . . . . . . . . . . . . . . . . . . . . . .   4
     2.1.  Actors  . . . . . . . . . . . . . . . . . . . . . . . . .   5
     2.2.  Data Types  . . . . . . . . . . . . . . . . . . . . . . .   7
     2.3.  Data Management Architectures . . . . . . . . . . . . . .   8
   3.  Framework . . . . . . . . . . . . . . . . . . . . . . . . . .   9
   4.  Use Cases . . . . . . . . . . . . . . . . . . . . . . . . . .  11
     4.1.  Acquisition . . . . . . . . . . . . . . . . . . . . . . .  11
       4.1.1.  Acquiring TNs from Registrar  . . . . . . . . . . . .  12
       4.1.2.  Acquiring TNs from CSPs . . . . . . . . . . . . . . .  13
     4.2.  Management  . . . . . . . . . . . . . . . . . . . . . . .  14
       4.2.1.  Management of Administrative Data . . . . . . . . . .  14
         4.2.1.1.  Managing Data at a Registrar  . . . . . . . . . .  14
         4.2.1.2.  Managing Data at a CSP  . . . . . . . . . . . . .  15
       4.2.2.  Management of Service Data  . . . . . . . . . . . . .  15
         4.2.2.1.  CSP to other Other CSPs . . . . . . . . . . . . . . . .  15
         4.2.2.2.  User to CSP . . . . . . . . . . . . . . . . . . .  16
       4.2.3.  Managing Change . . . . . . . . . . . . . . . . . . .  16
         4.2.3.1.  Changing the CSP for an Existing Service  . . . .  16
         4.2.3.2.  Terminating a Service . . . . . . . . . . . . . .  17
     4.3.  Retrieval . . . . . . . . . . . . . . . . . . . . . . . .  17
       4.3.1.  Retrieval of Public Data  . . . . . . . . . . . . . .  18
       4.3.2.  Retrieval of Semi-restricted Administrative Data  . .  18
       4.3.3.  Retrieval of Semi-restricted Service Data . . . . . .  18
       4.3.4.  Retrieval of Restricted Data  . . . . . . . . . . . .  19
   5.  Acknowledgments . .  IANA Considerations . . . . . . . . . . . . . . . . . . . . .  19  20
   6.  IANA  Privacy Considerations  . . . . . . . . . . . . . . . . . . . . .  20
   7.  Privacy  Security Considerations . . . . . . . . . . . . . . . . . . .  20
   8.  Security Considerations  Informative References  . . . . . . . . . . . . . . . . . . .  20
   9.  Informative References  21
   Acknowledgments . . . . . . . . . . . . . . . . . . .  21 . . . . . .  22
   Authors' Addresses  . . . . . . . . . . . . . . . . . . . . . . .  23  22

1.  Problem Statement

   The challenges of utilizing telephone numbers Telephone Numbers (TNs) on the Internet
   have been known for some time.  Internet telephony provided the first
   use case for routing telephone numbers on the Internet in a manner
   similar to how calls are routed in the public switched telephone
   network Public Switched Telephone
   Network (PSTN).  As the Internet had no service for discovering the
   endpoints associated with telephone numbers, ENUM [3] [RFC6116] created a DNS-
   based
   DNS-based mechanism for resolving TNs in an IP environment, by defining
   procedures for translating TNs into URIs for use URIs, as used by
   protocols such as SIP [2]. [RFC3261].  The resulting database was designed
   to function in a manner similar to the systems that route calls in
   the PSTN.  Originally, it was envisioned that ENUM would be deployed
   as a global hierarchical
   service, though service; however, in practice, it has only
   been deployed piecemeal by various parties.  Most notably, ENUM is
   used as an internal network
   function, function and is rarely used between
   service provider networks.  The original ENUM concept of a single
   root, e164.arpa, proved to be politically and practically
   challenging, and less centralized models have thus flourished.
   Subsequently, the DRINKS [4] Data for Reachability of Inter-/Intra-NetworK SIP
   (DRINKS) framework [RFC6461] showed ways that service providers might
   provision information about TNs at an ENUM service or similar
   Internet-based directory.  These technologies have also generally
   tried to preserve the features and architecture familiar to the PSTN
   numbering environment.

   Over time, Internet telephony has encompassed functions that differ
   substantially from traditional PSTN routing and management,
   especially as non-traditional providers have begun to utilize
   numbering resources.  An increasing number of enterprises, over-the-
   top voice-over-IP Voice over IP (VoIP) providers, text messaging services, and
   related non-carrier services have become heavy users of telephone
   numbers.  An enterprise, for example, can deploy an IP PBX Private Branch
   Exchange (PBX) that receives a block of telephone numbers from a
   carrier and then then, in turn
   distribute turn, distributes those numbers to new IP
   telephones when they associate with the PBX.  Internet services offer
   users portals where they can allocate new telephone numbers on the
   fly, assign multiple "alias" telephone numbers to a single line
   service, implement various mobility or find-me-follow-me
   applications, and so on.  Peer-to-peer telephone networks have
   encouraged experiments with distributed databases for telephone
   number routing and even allocation.

   This dynamic control over telephone numbers has few precedents in the
   traditional PSTN outside of number portability.  Number portability
   allows the capability of a user to choose and change their service
   provider while retaining their TN; it has been implemented in many
   countries;
   countries either for all telephony services or for subsets such as
   mobile. (e.g.,
   mobile).  However, TN administration processes rooted in PSTN
   technology and policies dictate that this be an exception process made number porting fraught with problems and
   delays.  Originally, processes were built to associate a specific TN
   to a specific service provider and never change it.  With number
   portability, the industry had to build new
   infrastructure, infrastructure and new
   administrative functions and processes to change the association of
   the TN from one service provider to another.  Thanks to the
   increasing sophistication of consumer mobile devices as Internet
   endpoints as well as telephones, users now associate TNs with many
   Internet applications other than telephony.  This has generated new
   interest in models similar to those in place for administering
   freephone (non-geographic toll free (non-geographic, toll-free numbers) services in the United
   States, where a user purchases a number through a sort of number
   registrar and controls its administration (such as routing) on their
   own, typically using Internet services to directly make changes to
   the service associated with telephone numbers.

   Most TNs today are assigned to specific geographies, at both an
   international level and within national numbering plans.  Numbering
   practices today are tightly coupled with the manner that service
   providers interconnect, interconnect as well as with how TNs are routed and
   administered: the PSTN was carefully designed to delegate switching
   intelligence geographically.  In interexchange carrier routing in
   North America, for example, calls to a particular TN are often handed
   off to the terminating service provider close to the geography where
   that TN is assigned.  But the overwhelming success of mobile
   telephones has increasingly eroded the connection between numbers and
   regions.  Furthermore, the topology of IP networks is not anchored to
   geography in the same way that the telephone network is.  In an
   Internet environment, establishing a network architecture for routing
   TNs could depend little on geography, relying instead on network
   topologies or other architectural features.  Adapting TNs to the
   Internet requires more security, richer datasets datasets, and more complex
   query and response capabilities than previous efforts have provided.

   This document attempts to create a common understanding of the
   problem statement related to allocating, managing, and resolving TNs
   in an IP environment, which is the focus of the IETF MODERN (Managing, Managing,
   Ordering, Distributing, Exposing, and Registering telephone Numbers)
   working group. Numbers
   (MODERN) Working Group.  It outlines a framework and lists motivating
   use cases for creating IP-based mechanisms for TNs.  It is important
   to acknowledge at the outset that there are various evolving
   international and national policies and processes related to TNs, and
   any solutions need to be flexible enough to account for variations in
   policy and requirements.

2.  Definitions

   This section provides definitions for actors, data types types, and data
   management architectures as they are discussed in this document.
   Different numbering spaces may instantiate these roles and concepts
   differently: practices that apply to non-geographic freephone
   numbers, for example, may not apply to geographic numbers, and
   practices that exist under one Numbering Authority may not be
   permitted under another.  The purpose of this framework is to
   identify the characteristics of protocol tools that will satisfy the
   diverse requirements for telephone number acquisition, management,
   and retrieval on the Internet.

2.1.  Actors

   The following roles of actors are defined in this document: document.

   Numbering Authority:  A regulatory body within a region that manages
      that regions region's TNs.  The Numbering Authority decides national
      numbering policy for the nation, region, or other domain for which
      it has authority, including what TNs can be allocated, which are
      reserved, and which entities may obtain TNs.

   Registry:  An entity that administers the allocation of TNs based on
      a Numbering Authority's policies.  Numbering authorities Authorities can act
      as the Registries themselves, or they can outsource the function
      to other entities.  Traditional registries are single entities
      with sole authority and responsibility for specific numbering
      resources, though distributed registries (see Section 2.3) are
      also in the scope of this framework.

   Credential Authority:  An entity that distributes credentials, such
      as certificates that attest the authority of assignees (defined
      below) and delegates.  This document assumes that one of or more
      credential authorities
      Credential Authorities may be trusted by actors in any given
      regulatory environment; policies for establishing such trust
      anchors are outside the scope of this document.

   Registrar:  An entity that distributes the telephone numbers
      administered by a Registry; typically, there are many Registrars
      that can distribute numbers from a single Registry, though
      Registrars may serve multiple Registries as well.  A Registrar has
      business relationships with number assignees and collects
      administrative information from them.

   Communication Service Provider (CSP):  A provider of communications
      services, communication
      service where those services can be identified by TNs.  This
      includes both traditional telephone carriers or enterprises as
      well as service providers with no presence on the PSTN who use
      TNs.  This framework does not assume that any single CSP provides
      all the communications communication service related to a particular TN.

   Service Enabler:  An entity that works with CSPs to enable
      communication service to a User; User: perhaps a vendor, a service
      bureau, or a third-party integrator.

   User:  An individual reachable through a communications service; communication service:
      usually a customer of a communication service provider. Communication Service Provider.

   Government Entity:  An entity that, due to legal powers deriving from
      national policy, has privileged access to information about number
      administration under certain conditions.

   Note that an individual, organization, or other entity may act in one
   or more of the roles above; for example, a company may be a CSP and
   also a Registrar.  Although Numbering Authorities are listed as
   actors, they are unlikely to actually participate in the protocol
   flows themselves, though themselves; however, in some situations situations, a Numbering Authority
   and Registry may be the same administrative entity.

   All actors that are recipients of numbering resources, be they a CSP,
   Service Enabler, or User, can also be said to have a relationship to
   a Registry of either an assignee or delegate: delegate.

   Assignee:  An actor that is assigned a TN directly by a Registrar; an
      assignee always has a direct relationship with a Registrar.

   Delegate:  An actor that is delegated a TN from an assignee or
      another delegate, delegate who does not necessarily have a direct
      relationship with a Registrar.  Delegates may delegate one or more
      of their TN assignment(s) to one or more subdelegates from further downstream
      subdelegates.
      downstream.

   As an example, consider a case where a Numbering Authority also acts
   as a Registry, and it issues blocks of 10,000 TNs to CSPs, which CSPs that, in
   this case case, also act as Registrars.  CSP/Registrars would then be
   responsible for distributing numbering resources to Users and other
   CSPs.  In this case, an enterprise deploying IP PBXs also acts as a
   CSP, and it acquires number blocks for its enterprise seats in chunks
   of 100 from a CSP acting as a Registrar with whom the enterprise has
   a business relationship.  The enterprise is is, in this case case, the
   assignee, as it receives numbering resources directly from a
   Registrar.  As it doles out individual numbers to its Users, the
   enterprise delegates its own numbering resources to those Users and
   their communications communication endpoints.  The overall ecosystem might look as
   follows.

                 +---------+
                 |Numbering|
                 |Authority|Registry
                 +----+----+
                      |
                      V 10,000 TNs
                 +---------+
                 |   CSP   |Registrar
                 +----+----+
                      |
                      V  100 TNs
                 +---------+
                 |   PBX   |Assignee
                 +---------+
                      |
                      V    1 TN
                 +---------+
                 |  User   |Delegate
                 +---------+

                   Figure 1: Chain of Number Assignment

2.2.  Data Types

   The following data types are defined in this document: document.

   Administrative Data:  assignment  Assignment data related to the TN and the
      relevant actors; it includes TN status (assigned, unassigned,
      etc.), contact data for the assignee or delegate, and typically
      does not require real-time access as this data is not required for
      ordinary call or session establishment.

   Service Data:  data  Data necessary to enable service for the TN; it
      includes addressing data and service features.  Since this data is
      necessary to complete calls, it must be obtained in real time.

   Administrative and service data can fit into three access categories:

   Public:  Anyone can access public data.  Such data might include a
      list of which numbering resources (unallocated number ranges) are
      available for acquisition from the Registry.

   Semi-restricted:  Only a subset of actors can access semi-restricted
      data.  For example example, CSPs may be able to access other CSP's service
      data in some closed environment.

   Restricted:  Only a small subset of actors can access restricted
      data.  For example example, a Government Entity may be able access contact
      information for a User.

   While it might appear there are really only two categories, public
   and restricted based (based on requestor, the requestor), the distinction between semi-
   restricted
   semi-restricted and restricted is helpful for the use cases below.

2.3.  Data Management Architectures

   This framework generally assumes that administrative and service data
   is maintained by CSPs, Registrars, and Registries.  The terms
   "registrar" and "registry" are familiar from DNS operations, and
   indeed the DNS provides an obvious inspiration for the relationships
   between those entities described here.  Protocols for transferring
   names between registries and registrars have been standardized in the
   DNS space for some time (see [14]). [RFC3375]).  Similarly, the division
   between service data acquired by resolving names with the DNS
   protocol vs. versus administrative data about names acquired through
   WHOIS [15] [RFC3912]  is directly analogous to the distinction between
   service and administrative data described in Section 2.2.  The major
   difference between the data management architecture of the DNS and
   this framework is that the distinction between the CSP and User, due
   to historical policies of the telephone network, will often not
   exactly correspond to the distinction between a name service and a
   registrant in the DNS world - -- a User in the telephone network is
   today at least rarely in a direct relationship with a Registrar
   comparable to that of a DNS registrant.

   The role of a Registry described here is a "thin" one, where the
   Registry manages basic allocation information for the numbering
   space, such as information about whether or not the number is
   assigned, and if assigned, by which Registrar.  It is the Registrar
   that
   that, in turn turn, manages detailed administrative data about those
   assignments, such as contact or billing information for the assignee.
   In some models, CSPs and Registrars will be combined (the same
   administrative entity), and in others the Registry and Registrar may
   similarly be composed.  Typically, service data resides largely at
   the CSP itself, though in some models a "thicker" Registry may itself
   contain a pointer to the servicing CSP for a number or number block.
   In addition to traditional centralized Registries, this framework
   also supports environments where the same data is being managed by
   multiple administrative entities, entities and stored in many locations.  A
   distributed registry system is discussed further in [19]. [DRIP].  To
   support those use cases, it is important to distinguish the
   following:

   Data store: Store:  A Data Store data store is a service that stores and enables access
      to administrative and/or service data.

   Reference Address:  A Reference Address reference address is a URL that dereferences to
      the location of the data store.

   Distributed data stores: Data Stores:  In a Distributed Data Store, distributed data store, administrative
      or service data can be stored with multiple actors.  For example,
      CSPs could provision their service data to multiple other CSPs.

   Distributed Registries:  Multiple Registries can manage the same
      numbering resource.  In these architectures, actors could interact
      with one or multiple Registries.  The Registries would update each
      other when change occurs.  The Registries have to ensure that data
      remains consistent, e.g. e.g., that the same TN is not assigned to two
      different actors.

3.  Framework

   The framework outlined in this document requires three Internet-based
   mechanisms for managing and resolving telephone numbers (TNs) TNs in an IP environment.
   These mechanisms will likely reuse existing protocols for sharing
   structured data; it is unlikely that new protocol development work
   will be required, though new information models specific to the data
   itself will be a major focus of framework development.  Likely
   candidates for reuse here include work done in DRINKS [4] [RFC6461] and WEIRDS [12],
   Web Extensible Internet Registration Data Service (WEIRDS) [RFC7482],
   as well as the TeRI [16] framework. Telephone-Related Information (TeRI) framework
   [TERI-INFO].

   These protocol mechanisms are scoped in a way that makes them likely
   to apply to a broad range of future policies for number
   administration.  It is not the purpose of this framework to dictate
   number policy, policy but instead to provide tools that will work with
   policies as they evolve going forward.  These mechanisms therefore mechanisms, therefore,
   do not assume that number administration is centralized, centralized nor that
   number allocations are restricted to any category of service
   providers, though these tools must and will work in environments with
   those properties.

   The three mechanisms are:

   Acquisition:  a  A protocol mechanism for acquiring TNs, including an
      enrollment process.

   Management:  a  A protocol mechanism for associating data with TNs.

   Retrieval:  a  A protocol mechanism for retrieving data about TNs.

   The acquisition mechanism will enable actors to acquire TNs for use
   with a communications communication service by requesting numbering resources from a
   service operated by a Registrar, CSP CSP, or similar actor.  TNs may be
   requested either on a number-by-number basis, basis or as inventory blocks.
   Any actor who grants numbering resources will retain metadata about
   the assignment, including the responsible organization or individual
   to whom numbers have been assigned.

   The management mechanism will let actors provision data associated
   with TNs.  For example, if a User has been assigned a TN, they may
   select a CSP to provide a particular service associated with the TN,
   or a CSP may assign a TN to a User upon service activation.  In
   either case, a mechanism is needed to provision data associated with
   the TN at that CSP, CSP and to extend those data sets as CSPs (and even
   Users) require.

   The retrieval mechanism will enable actors to learn information about
   TNs.  For real-time service data, this typically involves sending a
   request to a CSP; for other information, an actor may need to send a
   request to a Registry rather than a CSP.  Different parties may be
   authorized to receive different information about TNs.

   As an example, a CSP might use the acquisition interface to acquire a
   chunk of numbers from a Registrar.  Users might then provision
   administrative data associated with those numbers at the CSP through
   the management interface, interface and query for service data relating to those
   numbers through the retrieval interface of the CSP.

               +--------+
               |Registry|
               +---+----+
                   |
                   V
              +---------+
              |Registrar|
              +---------+
                    \
                     \\
           Acquisition \\
                         \\+-------+
                           \  CSP  |
                           +---+---+
                            A     A
                            |     |
                 Management |     | Retrieval
                            |     |
                            |     |
                    +-------++   ++-------+
                    |  User  |   |  User  |
                    +--------+   +--------+
                   (delegate)    (caller)
                    (Delegate)    (Caller)

                 Figure 2: Example of the Three Interfaces

4.  Use Cases

   The high-level use cases in this section will provide an overview of
   the expected operation of the three interfaces in the MODERN problem
   space:
   space.

4.1.  Acquisition

   There are various scenarios for how TNs can be acquired by the
   relevant actors, that is, a CSP, Service Enabler, and a User.  There
   are three actors from which numbers can be acquired: a Registrar, a
   CSP
   CSP, and a User (presumably one who is delegating to another party).
   It is assumed either that Registrars are either the same entity as
   Registries,
   Registries or that Registrars have established business relationships
   with Registries that enable them to distribute the numbers that the
   Registries administer.  In these use cases, a User may acquire TNs
   either from a CSP or CSP, a Registry, or from an intermediate delegate.

4.1.1.  Acquiring TNs from Registrar

   The most traditional number acquisition use case is one where a CSP,
   such as a carrier, requests a block of numbers from a Registrar to
   hold as inventory or assign to customers.

   Through some out-of-band business process, a CSP develops a
   relationship with a Registrar.  The Registrar maintains a profile of
   the CSP and assesses whether or not CSPs meet the policy restrictions
   for acquiring TNs.  The CSP may then request TNs from within a
   specific pool of numbers in the authority of the Registry; Registry, such as
   region, mobile, wireline, or freephone.  The Registrar must
   authenticate and authorize the CSP, CSP and then either grant or deny a
   request.  When an assignment occurs, the Registry creates and stores
   administrative information related to the assignment assignment, such as TN
   status and Registrar contact information, and removes the specific
   TN(s) from the pool of those that are available for assignment.  As a
   part of the acquisition and assignment process, the Registry provides
   to the Registrar any tokens or other material needed by a Credential
   Authority to issue credentials (for example, STIR Secure Telephone
   Identity Revisited (STIR) certificates [17]) [RFC8226]) used to attest the
   assignment for future transactions.  Depending on the policies of the
   Numbering Authorities, Registrars may be required to log these
   operations.

   Before it is eligible to receive TN assignments, per the policy of a
   Numbering Authority, the CSP may need to have submitted (again,
   through some out-of-band process) additional qualifying information
   such as the current utilization rate or a demand forecast.

   There are two scenarios under which a CSP requests resources; resources: either
   they are requesting inventory, inventory or they are requesting for a specific
   User or delegate.  For the purpose of status information, TNs
   assigned to a User are always considered assigned, not inventory.
   The CSP will associate service information for that TN, e.g., TN (e.g., a
   service address, address) and make it available to other CSPs to enable
   interconnection.  The CSP may need to update the Registrar regarding
   this service activation; this is part of the "TN status" maintained
   by the Registrar.

   There are also use cases in which a User can acquire a TN directly
   from a Registrar.  Today, a user User wishing to acquire a freephone
   number may browse the existing inventory through one or more
   Registrars, comparing their prices and services.  Each such Registrar
   either is a CSP, CSP or has a business relationship with one or more CSPs
   to provide services for that freephone number.  In this case, the
   User must establish some business relationship directly with a
   Registrar, similarly similar to how such functions are conducted today when
   Users purchase domain names.  In this use case, after receiving a
   number assignment from the Registrar, a User will then obtain
   communications
   communication service from a CSP, CSP and provide to the CSP the TN to be
   used for that service.  The CSP will associate service information
   for that TN, e.g., TN (e.g., the service address, address) and make it available to
   other CSPs to enable interconnection.  The user User will also need to
   inform the Registrar about this relationship.

4.1.2.  Acquiring TNs from CSPs

   Today, a User typically acquires a TN from a CSP when signing up for
   communications
   a communication service or turning on a new device.  In this use
   case, the User becomes the delegate of the CSP.  A reseller or a
   service bureau might also acquire a block of numbers from a CSP to be
   issued to Users.

   Consider a case where a User creates or has a relationship with the
   CSP,
   CSP and subscribes to a communications communication service which that includes the use
   of a TN.  The CSP collects and stores administrative data about the
   User.  The CSP then activates the User on their network and creates
   any necessary service data to enable connectivity with other CSPs.
   The CSP could also update public or privileged databases accessible
   by other Actors. actors.  The CSP provides any tokens or other material
   needed by a Credential Authority to issue credentials to the User
   (for example, a STIR certificate [17]) [RFC8226]) to prove the assignment
   for future transactions.  Such credentials could be delegated from
   the one provided by the Credential Authority to the CSP to continue
   the chain of assignment.  CSPs may be required to log such
   transactions,
   transactions if required by the policy of the Numbering Authority.

   Virtually

   Virtually, the same flow would work for a reseller: it would form a
   business relationship with the CSP, at which point the CSP would
   collect and store administrative data about the reseller and give the
   reseller any material needed for the reseller to acquire credentials
   for the numbers.  A user User might then then, in turn turn, acquire numbers from
   the reseller: in this case, the delegate re-delegating redelegating the TNs would
   be performing functions done by the CSP, e.g., CSP (e.g., providing any
   credentials,
   credentials or collecting administrative data, data or creative service
   data.
   data).

   The CSP could assign a TN from its existing inventory or it could
   acquire a new TN from the Registrar as part of the assignment
   process.  If it assigns it from its existing inventory, it would
   remove the specific TN from the pool of those available for
   assignment.  It may also update the Registrar about the assignment so
   the Registrar has current assignment data.  If a reseller or delegate
   CSP is acquiring the numbers, it may have the same obligations to
   provide utilization data to the Registry as the assignee, per
   Section 4.1.1.

4.2.  Management

   The management protocol mechanism is needed to associate
   administrative and service data with TNs, TNs and may be used to refresh
   or rollover associated credentials.

4.2.1.  Management of Administrative Data

   Administrative data is primarily related to the status of the TN, its
   administrative contacts, and the actors involved in providing service
   to the TN.  Protocol interactions for administrative data will
   therefore predominantly occur between CSPs and Users to the
   Registrar, Registrar
   or between Users and delegate CSPs to the CSP.

   Some administrative data may be private, private and would thus require
   special handling in a distributed data store model.  Access to it
   does not require real-time performance therefore performance; therefore, local caches are
   not
   necessary.  And it necessary, and the data will include sensitive information such
   as user User and contact data.

   Some of the data could lend itself to being publicly available, such
   as CSP and TN assignment status.  In that case case, it would be deemed
   public information for the purposes of the retrieval interface.

4.2.1.1.  Managing Data at a Registrar

   After a CSP acquires a TN or block of TNs from the Registrar (per
   Section 4.1.1 above), 4.1.1), it then provides administrative data to the Registrar
   as a step in the acquisition process.  The Registrar will
   authenticate the CSP and determine if the CSP is authorized to
   provision the administrative data for the TNs in question.  The
   Registry will update the status of the TN, i.e., that it is
   unavailable for assignment.  The Registrar will also maintain
   administrative data provided by the CSP.

   Changes to this administrative data will not be frequent.  Examples
   of changes would be terminating service (see Section 4.2.3.2),
   changing the name or address of a User or organization, or changing a
   CSP or delegate.  Changes should be authenticated by a credential to
   prove administrative responsibility for the TN.

   In some cases, such as the freephone system in North America today,
   the User has a direct relationship with the Registrar.  Naturally,
   these users Users could provision administrative data associated with their
   TNs directly to the Registrar, Registrar just as a freephone provider today
   maintains account and billing data.  While delegates may not
   ordinarily have a direct relationship to a Registrar, some
   environments as (as an optimization optimization) might want to support a model where
   the delegate updates the Registrar directly on changes, as opposed to
   sending that data to the CSP or through the CSP to the Registrar.  As
   stated already, the protocol should enable Users to acquire TNs
   directly from a Registrar, which Registrar may or may not also act as a CSP.
   In these cases cases, the updates would be similar to that those described in
   Section 4.2.1.1.

   In a distributed Registry model, TN status, e.g., status (e.g., allocated,
   assigned, available, unavailable, or unavailable) would need to be provided to
   other Registries in real-time. real time.  Other administrative data could be
   sent to all Registries Registries, or other Registries could get a reference
   address to the host Registry's data store.

4.2.1.2.  Managing Data at a CSP

   After a User acquires a TN or block of TNs from a CSP, the User will
   provide administrative data to the CSP.  The CSP commonly acts as a
   Registrar in this case, case by maintaining the administrative data and
   only
   notifies notifying the Registry of the change in TN status.  In this
   case, the Registry maintains a reference address (see Section 2.3) to
   the CSP/
   Registrar's CSP/Registrar's administrative data store so relevant actors have
   the ability to access the data.  Alternatively, a CSP could send the
   administrative data to an external Registrar to store.  If there is a
   delegate between the CSP and user, User, they will have to ensure there is
   a mechanism for the delegate to update the CSP as change occurs.

4.2.2.  Management of Service Data

   Service data is data required by an originating or intermediate CSP
   to enable communications communication service to a User: User; a SIP URI is an example of
   one service data element commonly used to route communications. communication.  CSPs
   typically create and manage service data, however, it is possible
   that delegates and Users could as well.  For most use cases involving
   individual Users, it is anticipated that lower-level service
   information changes (such as an end-user device receiving a new IP
   address) would be communicated to CSPs via existing protocols.  For
   example, the baseline SIP REGISTER [2] [RFC3261] method, even for bulk
   operations [13], [RFC6140], would likely be used rather than through any
   new interfaces defined by MODERN.

4.2.2.1.  CSP to other Other CSPs

   After a User enrolls for service with a CSP, in the case where the
   CSP was assigned the TN by a Registrar, the CSP will then create a
   service address such as a SIP URI and associate it with the TN.  The
   CSP needs to update this data to enable service interoperability.
   There are multiple ways that this update can occur, though most
   commonly service data is exposed through the retrieval interface (see
   Section 4.3).  For certain deployment architectures, like a
   distributed data store model, CSPs may need to provision data
   directly to other CSPs.

   If the CSP is assigning a TN from its own inventory inventory, it may not need
   to perform service data updates as change occurs because the existing
   service data associated with inventory may be sufficient once the TN
   is put in service.  They would however would, however, likely update the Registry
   on the change in status.

4.2.2.2.  User to CSP

   Users could also associate service data to their TNs at the CSP.  An
   example is would be a User acquires acquiring a TN from the Registrar (as
   described in Section 4.1.1) and wants wanting to provide that TN to the CSP
   so the CSP can enable service.  In this case, once the user User provides
   the number to the CSP, the CSP would update the Registry or other
   actors as outlined in Section 4.2.2.1.

4.2.3.  Managing Change

   This section will address some special management use cases that were
   not covered above.

4.2.3.1.  Changing the CSP for an Existing Service

   Consider the case where a User who subscribes to a communications
   service, and communication
   service (and who received their TN from that CSP, CSP) wishes to retain
   the same TN but move their service to a different CSP.

   In the simplest scenario, where there's an authoritative combined
   Registry/Registrar that maintains service data, the User could
   provide their credential to the new CSP and let the CSP initiate the
   change in service.  The new CSP could then provide the new service
   data with the User's credential to the Registry/Registrar, which then
   makes the change.  The old credential is revoked and a new one is
   provided.  The new CSP or the Registrar would send a notification to
   the old CSP, CSP so they can disable service.  The old CSP will undo any
   delegations to the User, including contacting the Credential
   Authority to revoke any cryptographic credentials (e.g., STIR
   certificates [17]) [RFC8226]) previously granted to the User.  Any service
   data maintained by the CSP must be removed, and and, similarly, the CSP
   must delete any such information it provisioned in the Registry.

   In a model similar to common practice in environments today, the User
   could alternatively provide their credential to the old CSP, and the
   old CSP initiates would initiate the change in service.  Or, a User could go
   directly to a Registrar to initiate a port.  This framework should
   support all of these potential flows.

   Note that in cases with a distributed Registry that maintained
   service data, the Registry would also have to update the other
   Registries of the change.

4.2.3.2.  Terminating a Service

   Consider a case where a user User who subscribes to a communications
   service, and communication
   service (and who received their TN from the CSP, CSP) wishes to terminate
   their service.  At this time, the CSP will undo any delegations to
   the User, which may involve contacting the Credential Authority to
   revoke any cryptographic credentials (e.g., STIR certificates [17])
   [RFC8226]) previously granted to the User.  Any service data
   maintained by the CSP must be removed, and similarly, the CSP must
   delete any such information it provisioned in the Registrar.
   However, per the policy of the Numbering Authority, Registrars and
   CSPs may be required to preserve historical data that will be
   accessible to Government Entities or others through audits, even if
   it is no longer retrievable through service interfaces.

   The TN will change state from assigned to unassigned, and the CSP
   will update the Registry.  Depending on policies policies, the TN could go
   back into the Registry, CSP, or delegate's pool of available TNs and
   would likely enter an ageing aging process.

   In an alternative use case, a User who received their own TN
   assignment directly from a Registrar terminates their service with a
   CSP.  At this time, the User might terminate their assignment from
   the Registrar, Registrar and return the TN to the Registry for re-assignment. reassignment.
   Alternatively, they could retain the TN and elect to assign it to
   some other service at a later time.

4.3.  Retrieval

   Retrieval of administrative or service data will be subject to access
   restrictions based on the category of the specific data: public,
   semi-restricted
   semi-restricted, or restricted.  Both administrative and service data
   can have data elements that fall into each of these categories.  It
   is expected that the majority of administrative data will fall into
   the semi-restricted category: access to this information may require
   some form of authorization, though service data crucial to
   reachability will need to be accessible.  In some environments, it's
   possible that none of the service data necessary to initiate communications
   communication will be useful to an entity on the public Internet, say, or
   that all that service data will have dependencies on the origination
   point of for calls.

   The retrieval protocol mechanism for semi-restricted and restricted
   data needs a way for the receiver of the request to identify the
   originator of the request and what is being requested.  The receiver
   of the request will process that request based on this information.

4.3.1.  Retrieval of Public Data

   Either administrative or service data may be made publicly available
   by the authority that generates and provisions it.  Under most
   circumstances, a CSP wants its communications communication service to be publicly
   reachable through TNs, so the retrieval interface supports public
   interfaces that permit clients to query for service data about a TN.
   Some service data may however may, however, require that the client be authorized
   to receive it, per the use case in Section 4.3.3 below. 4.3.3.

   Public data can simply be posted on websites or made available
   through a publicly available API.  Public data hosted by a CSP may
   have a reference address at the Registry.

4.3.2.  Retrieval of Semi-restricted Administrative Data

   Consider a case in which a CSP is having service problems completing
   calls to a specific TN, so it wants to contact the CSP serving that
   TN.  The Registry authorizes the originating CSP to access this
   information.  It initiates a query to the Registry, the Registry
   verifies the requestor and the requested data data, and the Registry
   responds with the serving CSP and contact data.  However, CSPs might
   not want to make those administrative contact points public data:
   they are willing to share them with other CSPs for troubleshooting
   purposes, but not to make them available to general communication.

   Alternatively

   Alternatively, that information could be part of a distributed data
   store and not stored at a monolithic Registry.  In that case, the CSP
   has the data in a local distributed data store store, and it initiates the
   query to the local data store.  The local data store responds with
   the CSP and contact data.  No verification is necessary because it
   was done when the CSP was authorized to receive the data store.

4.3.3.  Retrieval of Semi-restricted Service Data

   Consider a case where a User on a CSP's network calls a TN.  The CSP
   initiates a query for service data associated with the TN to complete
   the call, call and will receive special service data because the CSP
   operates in a closed environment where different CSPs receive
   different responses, and only participating CSPs can initiate
   communications.
   communication.  This service data would be flagged as semi-
   restricted.  The query and response have real-time performance
   requirements in that environment.

   Semi-restricted service data also works in a distributed data store
   model,
   model where each CSP distributes its updated service data to all
   other CSPs.  The originating CSP has the service data in its local
   data store and queries it.  The local data store responds with the
   service data.  The service data in the response can be a reference
   address to a data store maintained by the serving CSP, CSP or it can be
   the service address itself.  In the case where the response gives a
   reference address, a subsequent query would go to the serving CSP,
   who would would, in turn turn, authorize the requestor for the requested data
   and respond appropriate. appropriately.  In the case case, where the original response
   contains the service address, the requestor would use that service
   address as the destination for the call.

   In some environments, aspects of the service data may reside at the
   Registry itself (for example, the assigned CSP for a TN), and thus TN); thus, the
   query may be sent to the Registry.  The Registry verifies the
   requestor and the requested data and responds with the service data,
   such as a SIP URI containing the domain of the assigned CSP.

4.3.4.  Retrieval of Restricted Data

   A Government Entity wishes to access information about a particular
   User,
   User who subscribes to a communications communication service.  The entity that
   operates the Registry on behalf of the Numbering Authority in this
   case has some pre-defined predefined relationship with the Government Entity.
   When the CSP acquired TNs from the Numbering Authority, it was a
   condition of that assignment that the CSP provide access for
   Government Entities to telephone numbering data when certain
   conditions apply.  The required data may reside either in the CSP or
   in the Registrar.

   For a case where the CSP delegates a number to the User, the CSP
   might provision the Registrar (or itself, if the CSP is composed with
   a Registrar) with information relevant to the User.  At such a time
   as the Government Entity needs information about that User, the
   Government Entity may contact the Registrar or CSP to acquire the
   necessary data.  The interfaces necessary for this will be the same
   as those described in Section 4.3; the Government Entity will be
   authenticated,
   authenticated and an authorization decision will be made by the
   Registrar or CSP under the policy dictates established by the
   Numbering Authority.

5.  Acknowledgments

   We would like to thank Henning Schulzrinne and Adam Roach for their
   contributions to this problem statement and framework, and to thank
   Pierce Gorman for detailed comments.

6.  IANA Considerations

   This memo includes document has no instructions for the IANA.

7. IANA actions.

6.  Privacy Considerations

   This framework defines two categories of information about telephone
   numbers: service data and administrative data.  Service data
   describes how telephone numbers map to particular services and
   devices that provide real-time communication for users.  As such,
   service data could potentially leak resource locations and even
   lower-layer network addresses associated with these services, and in
   rare cases, with end-user devices.  Administrative data more broadly
   characterizes who the administrative entities are behind telephone
   numbers, which will often identify CSPs, CSPs but in some layers of the
   architecture could include personally identifying information Personally Identifiable Information (PII),
   even WHOIS-style information, about the end users behind identifiers.
   This could conceivably encompass the sorts of data that carriers and
   similar CSPs today keep about their customers for billing purposes,
   like real names and postal addresses.  The exact nature of
   administrative data is not defined by this framework, and it is
   anticipated that the protocols that will perform this function will
   be extensible for different use cases, so at this point, it is
   difficult to characterize exactly how much PII might end up being
   housed by these services.

   As such, if an attacker were to compromise the registrar services
   that maintains administrative data in this architecture which maintain administrative data, architecture, and in some
   cases even service data, this could leak PII about end users.  These
   interfaces, and the systems that host them, are a potentially
   attractive target for hackers and need to be hardened accordingly.
   Protocols that are selected to fulfill these functions must provide
   the security features described in [Sec Cons]. Section 7.

   Finally, this framework recognizes that that, in many jurisdictions,
   certain government agencies have a legal right to access service and
   administrative data maintained by CSPs.  This access is typically
   aimed at identifying the users behind communications identifiers the communication identifier in
   order to enforce regulatory policy.  Those legal entities already
   have the power to access the existing data held by CSPs in many
   jurisdictions, though potentially though, potentitally, the administrative data
   associated with this framework could be richer information.

8.

7.  Security Considerations

   The acquisition, management, and retrieval of administrative and
   service data associated with telephone numbers raises a number of
   security issues.

   Any mechanism that allows an individual or organization to acquire
   telephone numbers will require a means of mutual authentication, of
   integrity protection, and of confidentiality.  A Registry as defined
   in this document will surely want to authenticate the source of an
   acquisition request as a first step in the authorization process to
   determine whether or not the resource will be granted.  Integrity of
   both the request and response is essential to ensuring that tampering
   does not allow attackers to block acquisitions, or worse, to
   commandeer resources.  Confidentiality is essential to preventing
   eavesdroppers from learning about allocations, including the
   personally identifying information associated with the administrative
   or technical contracts for allocations.

   A management interface for telephone numbers has similar
   requirements.  Without proper authentication and authorization
   mechanisms in place, an attack could use the management interface to
   disrupt service data or administrative data, which could deny service
   to users, enable new impersonation attacks, prevent billing systems
   from operating properly, and cause similar system failures.

   Finally, a retrieval interfaces interface has its own needs for mutual
   authentication, integrity protection, and for confidentiality.  Any CSP
   sending a request to retrieve service data associated with a number
   will want to know that it is reaching the proper authority, that the
   response from that authority has not been tampered with in transit, and
   and, in most cases cases, the CSP will not want to reveal to eavesdroppers
   the number it is requesting or the response that it has received.
   Similarly, any service answering such a query will want to have a
   means of authenticating the source of the query, query and of protecting the
   integrity and confidentiality of its responses.

9.

8.  Informative References

   [1]        Peterson, J. and

   [DRIP]     Wendt, C. Jennings, "Enhancements for
              Authenticated Identity Management in the Session
              Initiation and H. Bellur, "Distributed Registry Protocol (SIP)", RFC 4474,
              DOI 10.17487/RFC4474, August 2006,
              <https://www.rfc-editor.org/info/rfc4474>.

   [2]
              (DRiP)", Work in Progress, draft-wendt-modern-drip-02,
              July 2017.

   [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, June 2002,
              <https://www.rfc-editor.org/info/rfc3261>.

   [3]

   [RFC3375]  Hollenbeck, S., "Generic Registry-Registrar Protocol
              Requirements", RFC 3375, DOI 10.17487/RFC3375, September
              2002, <https://www.rfc-editor.org/info/rfc3375>.

   [RFC3912]  Daigle, L., "WHOIS Protocol Specification", RFC 3912,
              DOI 10.17487/RFC3912, September 2004,
              <https://www.rfc-editor.org/info/rfc3912>.

   [RFC6116]  Bradner, S., Conroy, L., and K. Fujiwara, "The E.164 to
              Uniform Resource Identifiers (URI) Dynamic Delegation
              Discovery System (DDDS) Application (ENUM)", RFC 6116,
              DOI 10.17487/RFC6116, March 2011,
              <https://www.rfc-editor.org/info/rfc6116>.

   [4]

   [RFC6140]  Roach, A., "Registration for Multiple Phone Numbers in the
              Session Initiation Protocol (SIP)", RFC 6140,
              DOI 10.17487/RFC6140, March 2011,
              <https://www.rfc-editor.org/info/rfc6140>.

   [RFC6461]  Channabasappa, S., Ed., "Data for Reachability of Inter-
              /Intra-NetworK SIP (DRINKS) Use Cases and Protocol
              Requirements", RFC 6461, DOI 10.17487/RFC6461, January
              2012, <https://www.rfc-editor.org/info/rfc6461>.

   [5]        Watson, M., "Short Term Requirements for Network Asserted
              Identity", RFC 3324, DOI 10.17487/RFC3324, November 2002,
              <https://www.rfc-editor.org/info/rfc3324>.

   [6]        Jennings, C., Peterson, J., and M. Watson, "Private
              Extensions to the Session Initiation Protocol (SIP) for
              Asserted Identity within Trusted Networks", RFC 3325,
              DOI 10.17487/RFC3325, November 2002,
              <https://www.rfc-editor.org/info/rfc3325>.

   [7]        Hoffman, P. and J. Schlyter, "The DNS-Based Authentication
              of Named Entities (DANE) Transport Layer Security (TLS)
              Protocol: TLSA", RFC 6698, DOI 10.17487/RFC6698, August
              2012, <https://www.rfc-editor.org/info/rfc6698>.

   [8]        Elwell, J., "Connected Identity in the Session Initiation
              Protocol (SIP)", RFC 4916, DOI 10.17487/RFC4916, June
              2007, <https://www.rfc-editor.org/info/rfc4916>.

   [9]        Schulzrinne, H., "The tel URI for Telephone Numbers",
              RFC 3966, DOI 10.17487/RFC3966, December 2004,
              <https://www.rfc-editor.org/info/rfc3966>.

   [10]       Rosenberg, J. and C. Jennings, "The Session Initiation
              Protocol (SIP) and Spam", RFC 5039, DOI 10.17487/RFC5039,
              January 2008, <https://www.rfc-editor.org/info/rfc5039>.

   [11]       Peterson, J., Jennings, C., and R. Sparks, "Change Process
              for the Session Initiation Protocol (SIP) and the Real-
              time Applications and Infrastructure Area", BCP 67,
              RFC 5727, DOI 10.17487/RFC5727, March 2010,
              <https://www.rfc-editor.org/info/rfc5727>.

   [12]

   [RFC7482]  Newton, A. and S. Hollenbeck, "Registration Data Access
              Protocol (RDAP) Query Format", RFC 7482,
              DOI 10.17487/RFC7482, March 2015,
              <https://www.rfc-editor.org/info/rfc7482>.

   [13]       Roach, A., "Registration for Multiple Phone Numbers in the
              Session Initiation Protocol (SIP)", RFC 6140,
              DOI 10.17487/RFC6140, March 2011,
              <https://www.rfc-editor.org/info/rfc6140>.

   [14]       Hollenbeck, S., "Generic Registry-Registrar Protocol
              Requirements", RFC 3375, DOI 10.17487/RFC3375, September
              2002, <https://www.rfc-editor.org/info/rfc3375>.

   [15]       Daigle, L., "WHOIS Protocol Specification", RFC 3912,
              DOI 10.17487/RFC3912, September 2004,
              <https://www.rfc-editor.org/info/rfc3912>.

   [16]       Peterson, J., "An Architecture and Information Model for
              Telephone-Related Information (TeRI)", draft-peterson-
              modern-teri-03 (work in progress), July 2017.

   [17]

   [RFC8226]  Peterson, J. and S. Turner, "Secure Telephone Identity
              Credentials: Certificates", RFC 8226,
              DOI 10.17487/RFC8226, February 2018,
              <https://www.rfc-editor.org/info/rfc8226>.

   [18]       Barnes, M., Jennings, C., Rosenberg,

   [TERI-INFO]
              Peterson, J., and M. Petit-
              Huguenin, "Verification Involving PSTN Reachability:
              Requirements and "An Architecture Overview", draft-jennings-
              vipr-overview-06 (work in progress), December 2013.

   [19]       Wendt, C. and H. Bellur, "Distributed Registry Protocol
              (DRiP)", draft-wendt-modern-drip-02 (work Information Model for
              Telephone-Related Information (TeRI)", Work in progress),
              July 2017.

   [20]       Rosenberg, J. Progress,
              draft-peterson-modern-teri-04, March 2018.

Acknowledgments

   We would like to thank Henning Schulzrinne and H. Schulzrinne, "Session Initiation
              Protocol (SIP): Locating SIP Servers", RFC 3263,
              DOI 10.17487/RFC3263, June 2002,
              <https://www.rfc-editor.org/info/rfc3263>. Adam Roach for their
   contributions to this problem statement and framework; we would also
   like to thank Pierce Gorman for detailed comments.

Authors' Addresses
   Jon Peterson
   Neustar, Inc.
   1800 Sutter St Suite 570
   Concord, CA  94520
   US
   United States of America

   Email: jon.peterson@neustar.biz

   Tom McGarry
   Neustar, Inc.
   1800 Sutter St Suite 570
   Concord, CA  94520
   US
   United States of America

   Email: tom.mcgarry@neustar.biz