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Dnssd Status Pages

Extensions for Scalable DNS Service Discovery (Concluded WG)
Int Area: Suresh Krishnan, Terry Manderson | 2013-Oct-25 — 2015-Feb-07 
Chairs
 
 


2017-11-14 charter

Extensions for Scalable DNS Service Discovery  (dnssd)
------------------------------------------------------

 Charter

 Current Status: Active

 Chairs:
     David Schinazi <dschinazi@apple.com>
     Tim Chown <tim.chown@jisc.ac.uk>

 Internet Area Directors:
     Suresh Krishnan <suresh@kaloom.com>
     Terry Manderson <terry.manderson@icann.org>

 Internet Area Advisor:
     Terry Manderson <terry.manderson@icann.org>

 Mailing Lists:
     General Discussion: dnssd@ietf.org
     To Subscribe:       https://www.ietf.org/mailman/listinfo/dnssd
     Archive:            https://mailarchive.ietf.org/arch/browse/dnssd/

Description of Working Group:

  Background
  ----------

  Zero configuration networking protocols are currently well suited to
  discover services within the scope of a single link.  In particular,
  the DNS-SD [RFC 6763] and mDNS [RFC6762] protocol suite (sometimes
  referred to using Apple Computer Inc.'s trademark, Bonjour) are
  widely used for DNS-based service discovery and host name resolution
  on a single link.

  The DNS-SD/mDNS protocol suite is used in many scenarios including
  home, campus, and enterprise networks.  However, the zero configuration
  mDNS protocol is constrained to link-local multicast scope by design,
  and therefore cannot be used to discover services on remote links.

  In a home network that consists of a single (possibly bridged) link,
  users experience the expected discovery behavior; available services
  appear because all devices share a common link.  However, in multi-link
  home networks (as envisaged by the homenet WG) or in routed campus or
  enterprise networks, devices and users can only discover services on
  the same link, which is a significant limitation.  This has led to
  calls, such as the Educause petition, to develop an appropriate service
  discovery solution to span multiple links or to perform discovery across
  a wide area, not necessarily on directly connected links.

  In addition, the "Smart Energy Profile 2 Application Protocol Standard",
  published by ZigBee Alliance and HomePlug Powerline Alliance specifies
  the DNS-SD/mDNS protocol suite as the basis for its method of zero
  configuration service discovery.  However, its use of wireless mesh
  multi-link subnets in conjunction with traditional routed networks will
  require extensions to the DNS-SD/mDNS protocols to allow operation
  across multiple links.

  The scenarios in which multi-link service discovery is required may
  be zero configuration environments, environments where administrative
  configuration is supported, or a mixture of the two.

  As demand for service discovery across wider area routed networks
  grows, some vendors are beginning to ship proprietary solutions.  It
  is thus both timely and important that efforts to develop improved,
  scalable, autonomous service discovery solutions for routed networks
  are coordinated towards producing a single, standards-based solution.

  Working Group Description
  -------------------------

  The focus of the WG is to develop a solution for extended, scalable
  DNS-SD.  This work is likely to highlight problems and challenges with
  naming protocols, as some level of coexistence will be required between
  local zero configuration name services and those forming part of the
  global DNS.  It is important that these issues are captured and
  documented for further analysis; solving those problems is however not
  within the scope of this WG.

  The WG will consider the tradeoffs between reusing/extending existing
  protocols and developing entirely new ones.  It is highly desirable
  that any new solution is backwardly compatible with existing DNS-SD/mDNS
  deployments.  Any solution developed by the dnssd WG must not conflict
  or interfere with the operation of other zero-configuration service and
  naming protocols such as uPnP or LLMNR.  Integration with such protocols
  is out of scope for this WG.

  Current zero configuration discovery protocols are constrained to
  operate within a single link, which implicitly limits the scope of
  discovery. In extending service discovery protocols to operate over
  multiple links, devices will inherently become discoverable over a
  wider area, which may introduce security or privacy concerns. The WG
  will consider such concerns when exploring the solution space for
  multi-link service discovery.

  To that end, the primary goals of the dnssd WG are as follows:

  1. To document a set of requirements for scalable, autonomous
     DNS-based service discovery in routed, multi-link networks in the
     following five scenarios:

     (A) Personal Area networks, e.g., one laptop and one printer.
         This is the simplest example of a service discovery network,
         and may or may not have external connectivity.

     (B) Home networks, as envisaged by the homenet WG, consisting of
         one or more exit routers, with one or more upstream providers
         or networks, and an arbitrary internal topology with
         heterogeneous media where routing is automatically configured.
         The home network would typically be a single zero configuration
         administrative domain with a relatively limited number of
         devices.

     (C) Wireless 'hotspot' networks, which may include wireless networks
         made available in public places, or temporary or permanent
         infrastructures targeted towards meeting or conference style
         events, e.g., as provided for IETF meetings.  In such
         environments other devices may be more likely to be 'hostile'
         to the user.

     (D) Enterprise networks, consisting of larger routed networks,
         with large numbers of devices, which may be deployments
         spanning over multiple sites with multiple upstreams, and
         one more more administrative domains (depending on internal
         administrative delegation).  The large majority of the
         forwarding and security devices are configured.  These may
         be commercial or academic networks, with differing levels
         of administrative control over certain devices on the network,
         and BYOD devices commonplace in the campus scenario.

     (E) Mesh networks such as RPL/6LoWPAN, with one or more links per
         routable prefix, which may or may not have external connectivity.
         The topology may use technologies including 802.11 wireless,
         HomePlug AV and GP, and ZigBee IP.

     In the above scenarios, the aim is to facilitate service discovery
     across the defined site.  It is also desirable that a user or device,
     when away from such a site, is still able to discover services
     within that site, e.g. a user discovering services in their home
     network while remote from it.

     It is also desirable that multiple discovery scopes are supported,
     from the point of view of either performing discovery within a
     specified scope or advertisement within a specified scope, and
     being able to discover (enumerate) the set of scopes such that
     an application could then choose to do either. It should be noted
     that scope in this sense might refer to 'building' or 'room' and thus
     might have no correlation to network topology.

  2. To develop an improved, scalable solution for service discovery
     that can operate in multi-link networks, where devices may be
     in neighboring or non-neighboring links, applicable to
     the scenarios above.  The solution will consider tradeoffs between
     reusing/extending existing protocols and developing entirely new
     protocols.

     The solution should include documentation or definition of the
     interfaces that can be implemented, separately to transport of
     the information.

  3. To document challenges and problems encountered in the coexistence
     of zero configuration and global DNS name services in such
     multi-link networks, including consideration of both the name
     resolution mechanism and the namespace.

  It is important that the dnssd WG takes input from stakeholders in
  the scenarios it is considering.  For example, the homenet WG is
  currently evaluating its own requirements for naming and service
  discovery; it is up to the homenet WG as to whether it wishes to
  recommend adoption of the solution developed in the dnssd WG, but
  coordination between the WGs is desirable.


Goals and Milestones:
  Done     - Formation of the WG
  Done     - Adopt requirements draft as WG document
  Done     - Submit requirements draft to the IESG as an Informational RFC
  Done     - Adopt wide-area service discovery solution draft as WG document
  Done     - Adopt Informational document on the problems and challenges arising for zeroconf and unicast DNS name services
  Done     - Confirm long-lived queries draft as WG document
  Done     - Submit the zeroconf and unicast DNS "problems and challenges" draft to the IESG as Informational
  Done     - Adopt privacy extensions for DNS-SD draft as a WG document
  Done     - Adopt device pairing mechanism draft as a WG document
  Done     - Submit wide-area service discovery solution draft to the IESG as Standards Track RFC
  May 2017 - Submit DNS Push draft to the IESG as Standards Track RFC
  Jul 2017 - Adopt hybrid-proxy implementation draft as WG document
  Jul 2017 - Adopt DNS-SD Advertising Proxy draft as a WG document
  Sep 2017 - Submit Privacy Extensions for DNS-SD draft to the IESG as Standards Track RFC
  Sep 2017 - Submit Device Pairing Using Short Authentication Strings draft to the IESG as Standards Track RFC
  Dec 2017 - Submit DNS-SD Advertising Proxy draft to the IESG as Standards Track RFC
  Mar 2018 - Submit DNS-SD Deployment for campus/enterprise networks draft to the IESG as a BCP document


All charter page changes, including changes to draft-list, rfc-list and milestones:



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