RFC 9199




Independent Submission                                          G. Moura
Request for Comments: 9199                            SIDN Labs/TU Delft
Category: Informational                                      W. Hardaker
ISSN: 2070-1721                                             J. Heidemann
                                      USC/Information Sciences Institute
                                                               M. Davids
                                                               SIDN Labs
                                                              March 2022


      Considerations for Large Authoritative DNS Server Operators

Abstract



   Recent research work has explored the deployment characteristics and
   configuration of the Domain Name System (DNS).  This document
   summarizes the conclusions from these research efforts and offers
   specific, tangible considerations or advice to authoritative DNS
   server operators.  Authoritative server operators may wish to follow
   these considerations to improve their DNS services.

   It is possible that the results presented in this document could be
   applicable in a wider context than just the DNS protocol, as some of
   the results may generically apply to any stateless/short-duration
   anycasted service.

   This document is not an IETF consensus document: it is published for
   informational purposes.

Status of This Memo



   This document is not an Internet Standards Track specification; it is
   published for informational purposes.

   This is a contribution to the RFC Series, independently of any other
   RFC stream.  The RFC Editor has chosen to publish this document at
   its discretion and makes no statement about its value for
   implementation or deployment.  Documents approved for publication by
   the RFC Editor are not candidates for any level of Internet Standard;
   see Section 2 of RFC 7841.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   https://www.rfc-editor.org/info/rfc9199.

Copyright Notice



   Copyright (c) 2022 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (https://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.

Table of Contents



   1.  Introduction
   2.  Background
   3.  Considerations
     3.1.  C1: Deploy Anycast in Every Authoritative Server to Enhance
           Distribution and Latency
       3.1.1.  Research Background
       3.1.2.  Resulting Considerations
     3.2.  C2: Optimizing Routing is More Important than Location
           Count and Diversity
       3.2.1.  Research Background
       3.2.2.  Resulting Considerations
     3.3.  C3: Collect Anycast Catchment Maps to Improve Design
       3.3.1.  Research Background
       3.3.2.  Resulting Considerations
     3.4.  C4: Employ Two Strategies When under Stress
       3.4.1.  Research Background
       3.4.2.  Resulting Considerations
     3.5.  C5: Consider Longer Time-to-Live Values Whenever Possible
       3.5.1.  Research Background
       3.5.2.  Resulting Considerations
     3.6.  C6: Consider the Difference in Parent and Children's TTL
           Values
       3.6.1.  Research Background
       3.6.2.  Resulting Considerations
   4.  Security Considerations
   5.  Privacy Considerations
   6.  IANA Considerations
   7.  References
     7.1.  Normative References
     7.2.  Informative References
   Acknowledgements
   Contributors

   Authors' Addresses



1.  Introduction



   This document summarizes recent research that explored the deployed
   DNS configurations and offers derived, specific, tangible advice to
   DNS authoritative server operators (referred to as "DNS operators"
   hereafter).  The considerations (C1-C6) presented in this document
   are backed by peer-reviewed research, which used wide-scale Internet
   measurements to draw their conclusions.  This document summarizes the
   research results and describes the resulting key engineering options.
   In each section, readers are pointed to the pertinent publications
   where additional details are presented.

   These considerations are designed for operators of "large"
   authoritative DNS servers, which, in this context, are servers with a
   significant global user population, like top-level domain (TLD)
   operators, run by either a single operator or multiple operators.
   Typically, these networks are deployed on wide anycast networks
   [RFC1546] [AnyBest].  These considerations may not be appropriate for
   smaller domains, such as those used by an organization with users in
   one unicast network or in a single city or region, where operational
   goals such as uniform, global low latency are less required.

   It is possible that the results presented in this document could be
   applicable in a wider context than just the DNS protocol, as some of
   the results may generically apply to any stateless/short-duration
   anycasted service.  Because the conclusions of the reviewed studies
   don't measure smaller networks, the wording in this document
   concentrates solely on discussing large-scale DNS authoritative
   services.

   This document is not an IETF consensus document: it is published for
   informational purposes.

2.  Background



   The DNS has two main types of DNS servers: authoritative servers and
   recursive resolvers, shown by a representational deployment model in
   Figure 1.  An authoritative server (shown as AT1-AT4 in Figure 1)
   knows the content of a DNS zone and is responsible for answering
   queries about that zone.  It runs using local (possibly automatically
   updated) copies of the zone and does not need to query other servers
   [RFC2181] in order to answer requests.  A recursive resolver
   (Re1-Re3) is a server that iteratively queries authoritative and
   other servers to answer queries received from client requests
   [RFC1034].  A client typically employs a software library called a
   "stub resolver" ("stub" in Figure 1) to issue its query to the
   upstream recursive resolvers [RFC1034].

           +-----+  +-----+  +-----+  +-----+
           | AT1 |  | AT2 |  | AT3 |  | AT4 |
           +-----+  +-----+  +-----+  +-----+
             ^         ^        ^        ^
             |         |        |        |
             |      +-----+     |        |
             +------| Re1 |----+|        |
             |      +-----+              |
             |         ^                 |
             |         |                 |
             |      +----+   +----+      |
             +------|Re2 |   |Re3 |------+
                    +----+   +----+
                      ^          ^
                      |          |
                      | +------+ |
                      +-| stub |-+
                        +------+

        Figure 1: Relationship between Recursive Resolvers (Re) and
                      Authoritative Name Servers (ATn)

   DNS queries issued by a client contribute to a user's perceived
   latency and affect the user experience [Singla2014] depending on how
   long it takes for responses to be returned.  The DNS system has been
   subject to repeated Denial-of-Service (DoS) attacks (for example, in
   November 2015 [Moura16b]) in order to specifically degrade the user
   experience.

   To reduce latency and improve resiliency against DoS attacks, the DNS
   uses several types of service replication.  Replication at the
   authoritative server level can be achieved with the following:

   i.    the deployment of multiple servers for the same zone [RFC1035]
         (AT1-AT4 in Figure 1);

   ii.   the use of IP anycast [RFC1546] [RFC4786] [RFC7094] that allows
         the same IP address to be announced from multiple locations
         (each of referred to as an "anycast instance" [RFC8499]); and

   iii.  the use of load balancers to support multiple servers inside a
         single (potentially anycasted) instance.  As a consequence,
         there are many possible ways an authoritative DNS provider can
         engineer its production authoritative server network with
         multiple viable choices, and there is not necessarily a single
         optimal design.

3.  Considerations



   In the next sections, we cover the specific considerations (C1-C6)
   for conclusions drawn within academic papers about large
   authoritative DNS server operators.  These considerations are
   conclusions reached from academic work that authoritative server
   operators may wish to consider in order to improve their DNS service.
   Each consideration offers different improvements that may impact
   service latency, routing, anycast deployment, and defensive
   strategies, for example.

3.1.  C1: Deploy Anycast in Every Authoritative Server to Enhance
      Distribution and Latency



3.1.1.  Research Background



   Authoritative DNS server operators announce their service using NS
   records [RFC1034].  Different authoritative servers for a given zone
   should return the same content; typically, they stay synchronized
   using DNS zone transfers (authoritative transfer (AXFR) [RFC5936] and
   incremental zone transfer (IXFR) [RFC1995]), coordinating the zone
   data they all return to their clients.

   As discussed above, the DNS heavily relies upon replication to
   support high reliability, ensure capacity, and reduce latency
   [Moura16b].  The DNS has two complementary mechanisms for service
   replication: name server replication (multiple NS records) and
   anycast (multiple physical locations).  Name server replication is
   strongly recommended for all zones (multiple NS records), and IP
   anycast is used by many larger zones such as the DNS root [AnyFRoot],
   most top-level domains [Moura16b], and many large commercial
   enterprises, governments, and other organizations.

   Most DNS operators strive to reduce service latency for users, which
   is greatly affected by both of these replication techniques.
   However, because operators only have control over their authoritative
   servers and not over the client's recursive resolvers, it is
   difficult to ensure that recursives will be served by the closest
   authoritative server.  Server selection is ultimately up to the
   recursive resolver's software implementation, and different vendors
   and even different releases employ different criteria to choose the
   authoritative servers with which to communicate.

   Understanding how recursive resolvers choose authoritative servers is
   a key step in improving the effectiveness of authoritative server
   deployments.  To measure and evaluate server deployments,
   [Mueller17b] describes the deployment of seven unicast authoritative
   name servers in different global locations and then queried them from
   more than 9000 Reseaux IP Europeens (RIPE) authoritative server
   operators and their respective recursive resolvers.

   It was found in [Mueller17b] that recursive resolvers in the wild
   query all available authoritative servers, regardless of the observed
   latency.  But the distribution of queries tends to be skewed towards
   authoritatives with lower latency: the lower the latency between a
   recursive resolver and an authoritative server, the more often the
   recursive will send queries to that server.  These results were
   obtained by aggregating results from all of the vantage points, and
   they were not specific to any vendor or version.

   The authors believe this behavior is a consequence of combining the
   two main criteria employed by resolvers when selecting authoritative
   servers: resolvers regularly check all listed authoritative servers
   in an NS set to determine which is closer (the least latent), and
   when one isn't available, it selects one of the alternatives.

3.1.2.  Resulting Considerations



   For an authoritative DNS operator, this result means that the latency
   of all authoritative servers (NS records) matter, so they all must be
   similarly capable -- all available authoritatives will be queried by
   most recursive resolvers.  Unicasted services, unfortunately, cannot
   deliver good latency worldwide (a unicast authoritative server in
   Europe will always have high latency to resolvers in California and
   Australia, for example, given its geographical distance).

   [Mueller17b] recommends that DNS operators deploy equally strong IP
   anycast instances for every authoritative server (i.e., for each NS
   record).  Each large authoritative DNS server provider should phase
   out its usage of unicast and deploy a number of well-engineered
   anycast instances with good peering strategies so they can provide
   good latency to their global clients.

   As a case study, the ".nl" TLD zone was originally served on seven
   authoritative servers with a mixed unicast/anycast setup.  In early
   2018, .nl moved to a setup with 4 anycast authoritative servers.

   The contribution of [Mueller17b] to DNS service engineering shows
   that because unicast cannot deliver good latency worldwide, anycast
   needs to be used to provide a low-latency service worldwide.

3.2.  C2: Optimizing Routing is More Important than Location Count and
      Diversity



3.2.1.  Research Background



   When selecting an anycast DNS provider or setting up an anycast
   service, choosing the best number of anycast instances [RFC4786]
   [RFC7094] to deploy is a challenging problem.  Selecting the right
   quantity and set of global locations that should send BGP
   announcements is tricky.  Intuitively, one could naively think that
   more instances are better and that simply "more" will always lead to
   shorter response times.

   This is not necessarily true, however.  In fact, proper route
   engineering can matter more than the total number of locations, as
   found in [Schmidt17a].  To study the relationship between the number
   of anycast instances and the associated service performance, the
   authors measured the round-trip time (RTT) latency of four DNS root
   servers.  The root DNS servers are implemented by 12 separate
   organizations serving the DNS root zone at 13 different IPv4/IPv6
   address pairs.

   The results documented in [Schmidt17a] measured the performance of
   the {c,f,k,l}.root-servers.net (referred to as "C", "F", "K", and "L"
   hereafter) servers from more than 7,900 RIPE Atlas probes.  RIPE
   Atlas is an Internet measurement platform with more than 12,000
   global vantage points called "Atlas probes", and it is used regularly
   by both researchers and operators [RipeAtlas15a] [RipeAtlas19a].

   In [Schmidt17a], the authors found that the C server, a smaller
   anycast deployment consisting of only 8 instances, provided very
   similar overall performance in comparison to the much larger
   deployments of K and L, with 33 and 144 instances, respectively.  The
   median RTTs for the C, K, and L root servers were all between 30-32
   ms.

   Because RIPE Atlas is known to have better coverage in Europe than
   other regions, the authors specifically analyzed the results per
   region and per country (Figure 5 in [Schmidt17a]) and show that known
   Atlas bias toward Europe does not change the conclusion that properly
   selected anycast locations are more important to latency than the
   number of sites.

3.2.2.  Resulting Considerations



   The important conclusion from [Schmidt17a] is that when engineering
   anycast services for performance, factors other than just the number
   of instances (such as local routing connectivity) must be considered.
   Specifically, optimizing routing policies is more important than
   simply adding new instances.  The authors showed that 12 instances
   can provide reasonable latency, assuming they are globally
   distributed and have good local interconnectivity.  However,
   additional instances can still be useful for other reasons, such as
   when handling DoS attacks [Moura16b].

3.3.  C3: Collect Anycast Catchment Maps to Improve Design



3.3.1.  Research Background



   An anycast DNS service may be deployed from anywhere and from several
   locations to hundreds of locations (for example, l.root-servers.net
   has over 150 anycast instances at the time this was written).
   Anycast leverages Internet routing to distribute incoming queries to
   a service's nearest distributed anycast locations measured by the
   number of routing hops.  However, queries are usually not evenly
   distributed across all anycast locations, as found in the case of
   L-Root when analyzed using Hedgehog [IcannHedgehog].

   Adding locations to or removing locations from a deployed anycast
   network changes the load distribution across all of its locations.
   When a new location is announced by BGP, locations may receive more
   or less traffic than it was engineered for, leading to suboptimal
   service performance or even stressing some locations while leaving
   others underutilized.  Operators constantly face this scenario when
   expanding an anycast service.  Operators cannot easily directly
   estimate future query distributions based on proposed anycast network
   engineering decisions.

   To address this need and estimate the query loads of an anycast
   service undergoing changes (in particular expanding), [Vries17b]
   describes the development of a new technique enabling operators to
   carry out active measurements using an open-source tool called
   Verfploeter (available at [VerfSrc]).  The results allow the creation
   of detailed anycast maps and catchment estimates.  By running
   Verfploeter combined with a published IPv4 "hit list", the DNS can
   precisely calculate which remote prefixes will be matched to each
   anycast instance in a network.  At the time of this writing,
   Verfploeter still does not support IPv6 as the IPv4 hit lists used
   are generated via frequent large-scale ICMP echo scans, which is not
   possible using IPv6.

   As proof of concept, [Vries17b] documents how Verfploeter was used to
   predict both the catchment and query load distribution for a new
   anycast instance deployed for b.root-servers.net.  Using two anycast
   test instances in Miami (MIA) and Los Angeles (LAX), an ICMP echo
   query was sent from an IP anycast address to each IPv4 /24 network
   routing block on the Internet.

   The ICMP echo responses were recorded at both sites and analyzed and
   overlaid onto a graphical world map, resulting in an Internet-scale
   catchment map.  To calculate expected load once the production
   network was enabled, the quantity of traffic received by b.root-
   servers.net's single site at LAX was recorded based on a single day's
   traffic (2017-04-12, "day in the life" (DITL) datasets [Ditl17]).  In
   [Vries17b], it was predicted that 81.6% of the traffic load would
   remain at the LAX site.  This Verfploeter estimate turned out to be
   very accurate; the actual measured traffic volume when production
   service at MIA was enabled was 81.4%.

   Verfploeter can also be used to estimate traffic shifts based on
   other BGP route engineering techniques (for example, Autonomous
   System (AS) path prepending or BGP community use) in advance of
   operational deployment.  This was studied in [Vries17b] using
   prepending with 1-3 hops at each instance, and the results were
   compared against real operational changes to validate the accuracy of
   the techniques.

3.3.2.  Resulting Considerations



   An important operational takeaway [Vries17b] provides is how DNS
   operators can make informed engineering choices when changing DNS
   anycast network deployments by using Verfploeter in advance.
   Operators can identify suboptimal routing situations in advance with
   significantly better coverage rather than using other active
   measurement platforms such as RIPE Atlas.  To date, Verfploeter has
   been deployed on an operational testbed (anycast testbed) [AnyTest]
   on a large unnamed operator and is run daily at b.root-servers.net
   [Vries17b].

   Operators should use active measurement techniques like Verfploeter
   in advance of potential anycast network changes to accurately measure
   the benefits and potential issues ahead of time.

3.4.  C4: Employ Two Strategies When under Stress



3.4.1.  Research Background



   DDoS attacks are becoming bigger, cheaper, and more frequent
   [Moura16b].  The most powerful recorded DDoS attack against DNS
   servers to date reached 1.2 Tbps by using Internet of Things (IoT)
   devices [Perlroth16].  How should a DNS operator engineer its anycast
   authoritative DNS server to react to such a DDoS attack?  [Moura16b]
   investigates this question using empirical observations grounded with
   theoretical option evaluations.

   An authoritative DNS server deployed using anycast will have many
   server instances distributed over many networks.  Ultimately, the
   relationship between the DNS provider's network and a client's ISP
   will determine which anycast instance will answer queries for a given
   client, given that the BGP protocol maps clients to specific anycast
   instances using routing information.  As a consequence, when an
   anycast authoritative server is under attack, the load that each
   anycast instance receives is likely to be unevenly distributed (a
   function of the source of the attacks); thus, some instances may be
   more overloaded than others, which is what was observed when
   analyzing the root DNS events of November 2015 [Moura16b].  Given the
   fact that different instances may have different capacities
   (bandwidth, CPU, etc.), making a decision about how to react to
   stress becomes even more difficult.

   In practice, when an anycast instance is overloaded with incoming
   traffic, operators have two options:

   *  They can withdraw its routes, pre-prepend its AS route to some or
      all of its neighbors, perform other traffic-shifting tricks (such
      as reducing route announcement propagation using BGP communities
      [RFC1997]), or communicate with its upstream network providers to
      apply filtering (potentially using FlowSpec [RFC8955] or the DDoS
      Open Threat Signaling (DOTS) protocol [RFC8811] [RFC9132]
      [RFC8783]).  These techniques shift both legitimate and attack
      traffic to other anycast instances (with hopefully greater
      capacity) or block traffic entirely.

   *  Alternatively, operators can become degraded absorbers by
      continuing to operate, knowing dropping incoming legitimate
      requests due to queue overflow.  However, this approach will also
      absorb attack traffic directed toward its catchment, hopefully
      protecting the other anycast instances.

   [Moura16b] describes seeing both of these behaviors deployed in
   practice when studying instance reachability and RTTs in the DNS root
   events.  When withdraw strategies were deployed, the stress of
   increased query loads were displaced from one instance to multiple
   other sites.  In other observed events, one site was left to absorb
   the brunt of an attack, leaving the other sites to remain relatively
   less affected.

3.4.2.  Resulting Considerations



   Operators should consider having both an anycast site withdraw
   strategy and an absorption strategy ready to be used before a network
   overload occurs.  Operators should be able to deploy one or both of
   these strategies rapidly.  Ideally, these should be encoded into
   operating playbooks with defined site measurement guidelines for
   which strategy to employ based on measured data from past events.

   [Moura16b] speculates that careful, explicit, and automated
   management policies may provide stronger defenses to overload events.
   DNS operators should be ready to employ both common filtering
   approaches and other routing load-balancing techniques (such as
   withdrawing routes, prepending Autonomous Systems (ASes), adding
   communities, or isolating instances), where the best choice depends
   on the specifics of the attack.

   Note that this consideration refers to the operation of just one
   anycast service point, i.e., just one anycasted IP address block
   covering one NS record.  However, DNS zones with multiple
   authoritative anycast servers may also expect loads to shift from one
   anycasted server to another, as resolvers switch from one
   authoritative service point to another when attempting to resolve a
   name [Mueller17b].

3.5.  C5: Consider Longer Time-to-Live Values Whenever Possible



3.5.1.  Research Background



   Caching is the cornerstone of good DNS performance and reliability.
   A 50 ms response to a new DNS query may be considered fast, but a
   response of less than 1 ms to a cached entry is far faster.  In
   [Moura18b], it was shown that caching also protects users from short
   outages and even significant DDoS attacks.

   Time-to-live (TTL) values [RFC1034] [RFC1035] for DNS records
   directly control cache durations and affect latency, resilience, and
   the role of DNS in Content Delivery Network (CDN) server selection.
   Some early work modeled caches as a function of their TTLs [Jung03a],
   and recent work has examined cache interactions with DNS [Moura18b],
   but until [Moura19b], no research had provided considerations about
   the benefits of various TTL value choices.  To study this, Moura et
   al. [Moura19b] carried out a measurement study investigating TTL
   choices and their impact on user experiences in the wild.  They
   performed this study independent of specific resolvers (and their
   caching architectures), vendors, or setups.

   First, they identified several reasons why operators and zone owners
   may want to choose longer or shorter TTLs:

   *  Longer TTLs, as discussed, lead to a longer cache life, resulting
      in faster responses.  In [Moura19b], this was measured this in the
      wild, and it showed that by increasing the TTL for the .uy TLD
      from 5 minutes (300 s) to 1 day (86,400 s), the latency measured
      from 15,000 Atlas vantage points changed significantly: the median
      RTT decreased from 28.7 ms to 8 ms, and the 75th percentile
      decreased from 183 ms to 21 ms.

   *  Longer caching times also result in lower DNS traffic:
      authoritative servers will experience less traffic with extended
      TTLs, as repeated queries are answered by resolver caches.

   *  Longer caching consequently results in a lower overall cost if the
      DNS is metered: some providers that offer DNS as a Service charge
      a per-query (metered) cost (often in addition to a fixed monthly
      cost).

   *  Longer caching is more robust to DDoS attacks on DNS
      infrastructure.  DNS caching was also measured in [Moura18b], and
      it showed that the effects of a DDoS on DNS can be greatly
      reduced, provided that the caches last longer than the attack.

   *  Shorter caching, however, supports deployments that may require
      rapid operational changes: an easy way to transition from an old
      server to a new one is to simply change the DNS records.  Since
      there is no method to remotely remove cached DNS records, the TTL
      duration represents a necessary transition delay to fully shift
      from one server to another.  Thus, low TTLs allow for more rapid
      transitions.  However, when deployments are planned in advance
      (that is, longer than the TTL), it is possible to lower the TTLs
      just before a major operational change and raise them again
      afterward.

   *  Shorter caching can also help with a DNS-based response to DDoS
      attacks.  Specifically, some DDoS-scrubbing services use the DNS
      to redirect traffic during an attack.  Since DDoS attacks arrive
      unannounced, DNS-based traffic redirection requires that the TTL
      be kept quite low at all times to allow operators to suddenly have
      their zone served by a DDoS-scrubbing service.

   *  Shorter caching helps DNS-based load balancing.  Many large
      services are known to rotate traffic among their servers using
      DNS-based load balancing.  Each arriving DNS request provides an
      opportunity to adjust the service load by rotating IP address
      records (A and AAAA) to the lowest unused server.  Shorter TTLs
      may be desired in these architectures to react more quickly to
      traffic dynamics.  Many recursive resolvers, however, have minimum
      caching times of tens of seconds, placing a limit on this form of
      agility.

3.5.2.  Resulting Considerations



   Given these considerations, the proper choice for a TTL depends in
   part on multiple external factors -- no single recommendation is
   appropriate for all scenarios.  Organizations must weigh these trade-
   offs and find a good balance for their situation.  Still, some
   guidelines can be reached when choosing TTLs:

   *  For general DNS zone owners, [Moura19b] recommends a longer TTL of
      at least one hour and ideally 4, 8, or 24 hours.  Assuming planned
      maintenance can be scheduled at least a day in advance, long TTLs
      have little cost and may even literally provide cost savings.

   *  For TLD and other public registration operators (for example, most
      ccTLDs and .com, .net, and .org) that host many delegations (NS
      records, DS records, and "glue" records), [Moura19b] demonstrates
      that most resolvers will use the TTL values provided by the child
      delegations while some others will choose the TTL provided by the
      parent's copy of the record.  As such, [Moura19b] recommends
      longer TTLs (at least an hour or more) for registry operators as
      well for child NS and other records.

   *  Users of DNS-based load balancing or DDoS-prevention services may
      require shorter TTLs: TTLs may even need to be as short as 5
      minutes, although 15 minutes may provide sufficient agility for
      many operators.  There is always a tussle between using shorter
      TTLs that provide more agility and using longer TTLs that include
      all the benefits listed above.

   *  Regarding the use of A/AAAA and NS records, the TTLs for A/AAAA
      records should be shorter than or equal to the TTL for the
      corresponding NS records for in-bailiwick authoritative DNS
      servers, since [Moura19b] finds that once an NS record expires,
      their associated A/AAAA will also be requeried when glue is
      required to be sent by the parents.  For out-of-bailiwick servers,
      A, AAAA, and NS records are usually all cached independently, so
      different TTLs can be used effectively if desired.  In either
      case, short A and AAAA records may still be desired if DDoS
      mitigation services are required.

3.6.  C6: Consider the Difference in Parent and Children's TTL Values



3.6.1.  Research Background



   Multiple record types exist or are related between the parent of a
   zone and the child.  At a minimum, NS records are supposed to be
   identical in the parent (but often are not), as are corresponding IP
   addresses in "glue" A/AAAA records that must exist for in-bailiwick
   authoritative servers.  Additionally, if DNSSEC [RFC4033] [RFC4034]
   [RFC4035] [RFC4509] is deployed for a zone, the parent's DS record
   must cryptographically refer to a child's DNSKEY record.

   Because some information exists in both the parent and a child, it is
   possible for the TTL values to differ between the parent's copy and
   the child's.  [Moura19b] examines resolver behaviors when these
   values differed in the wild, as they frequently do -- often, parent
   zones have de facto TTL values that a child has no control over.  For
   example, NS records for TLDs in the root zone are all set to 2 days
   (48 hours), but some TLDs have lower values within their published
   records (the TTLs for .cl's NS records from their authoritative
   servers is 1 hour).  [Moura19b] also examines the differences in the
   TTLs between the NS records and the corresponding A/AAAA records for
   the addresses of a name server.  RIPE Atlas nodes are used to
   determine what resolvers in the wild do with different information
   and whether the parent's TTL is used for cache lifetimes ("parent-
   centric") or the child's ("child-centric").

   [Moura19b] found that roughly 90% of resolvers follow the child's
   view of the TTL, while 10% appear parent-centric.  Additionally, it
   found that resolvers behave differently for cache lifetimes for in-
   bailiwick vs. out-of-bailiwick NS/A/AAAA TTL combinations.
   Specifically, when NS TTLs are shorter than the corresponding address
   records, most resolvers will requery for A/AAAA records for the in-
   bailiwick resolvers and switch to new address records even if the
   cache indicates the original A/AAAA records could be kept longer.  On
   the other hand, the inverse is true for out-of-bailiwick resolvers:
   if the NS record expires first, resolvers will honor the original
   cache time of the name server's address.

3.6.2.  Resulting Considerations



   The important conclusion from this study is that operators cannot
   depend on their published TTL values alone -- the parent's values are
   also used for timing cache entries in the wild.  Operators that are
   planning on infrastructure changes should assume that an older
   infrastructure must be left on and operational for at least the
   maximum of both the parent and child's TTLs.

4.  Security Considerations



   This document discusses applying measured research results to
   operational deployments.  Most of the considerations affect mostly
   operational practice, though a few do have security-related impacts.

   Specifically, C4 discusses a couple of strategies to employ when a
   service is under stress from DDoS attacks and offers operators
   additional guidance when handling excess traffic.

   Similarly, C5 identifies the trade-offs with respect to the
   operational and security benefits of using longer TTL values.

5.  Privacy Considerations



   This document does not add any new, practical privacy issues, aside
   from possible benefits in deploying longer TTLs as suggested in C5.
   Longer TTLs may help preserve a user's privacy by reducing the number
   of requests that get transmitted in both client-to-resolver and
   resolver-to-authoritative cases.

6.  IANA Considerations



   This document has no IANA actions.

7.  References



7.1.  Normative References



   [RFC1034]  Mockapetris, P., "Domain names - concepts and facilities",
              STD 13, RFC 1034, DOI 10.17487/RFC1034, November 1987,
              <https://www.rfc-editor.org/info/rfc1034>.

   [RFC1035]  Mockapetris, P., "Domain names - implementation and
              specification", STD 13, RFC 1035, DOI 10.17487/RFC1035,
              November 1987, <https://www.rfc-editor.org/info/rfc1035>.

   [RFC1546]  Partridge, C., Mendez, T., and W. Milliken, "Host
              Anycasting Service", RFC 1546, DOI 10.17487/RFC1546,
              November 1993, <https://www.rfc-editor.org/info/rfc1546>.

   [RFC1995]  Ohta, M., "Incremental Zone Transfer in DNS", RFC 1995,
              DOI 10.17487/RFC1995, August 1996,
              <https://www.rfc-editor.org/info/rfc1995>.

   [RFC1997]  Chandra, R., Traina, P., and T. Li, "BGP Communities
              Attribute", RFC 1997, DOI 10.17487/RFC1997, August 1996,
              <https://www.rfc-editor.org/info/rfc1997>.

   [RFC2181]  Elz, R. and R. Bush, "Clarifications to the DNS
              Specification", RFC 2181, DOI 10.17487/RFC2181, July 1997,
              <https://www.rfc-editor.org/info/rfc2181>.

   [RFC4786]  Abley, J. and K. Lindqvist, "Operation of Anycast
              Services", BCP 126, RFC 4786, DOI 10.17487/RFC4786,
              December 2006, <https://www.rfc-editor.org/info/rfc4786>.

   [RFC5936]  Lewis, E. and A. Hoenes, Ed., "DNS Zone Transfer Protocol
              (AXFR)", RFC 5936, DOI 10.17487/RFC5936, June 2010,
              <https://www.rfc-editor.org/info/rfc5936>.

   [RFC7094]  McPherson, D., Oran, D., Thaler, D., and E. Osterweil,
              "Architectural Considerations of IP Anycast", RFC 7094,
              DOI 10.17487/RFC7094, January 2014,
              <https://www.rfc-editor.org/info/rfc7094>.

   [RFC8499]  Hoffman, P., Sullivan, A., and K. Fujiwara, "DNS
              Terminology", BCP 219, RFC 8499, DOI 10.17487/RFC8499,
              January 2019, <https://www.rfc-editor.org/info/rfc8499>.

   [RFC8783]  Boucadair, M., Ed. and T. Reddy.K, Ed., "Distributed
              Denial-of-Service Open Threat Signaling (DOTS) Data
              Channel Specification", RFC 8783, DOI 10.17487/RFC8783,
              May 2020, <https://www.rfc-editor.org/info/rfc8783>.

   [RFC8955]  Loibl, C., Hares, S., Raszuk, R., McPherson, D., and M.
              Bacher, "Dissemination of Flow Specification Rules",
              RFC 8955, DOI 10.17487/RFC8955, December 2020,
              <https://www.rfc-editor.org/info/rfc8955>.

   [RFC9132]  Boucadair, M., Ed., Shallow, J., and T. Reddy.K,
              "Distributed Denial-of-Service Open Threat Signaling
              (DOTS) Signal Channel Specification", RFC 9132,
              DOI 10.17487/RFC9132, September 2021,
              <https://www.rfc-editor.org/info/rfc9132>.

7.2.  Informative References



   [AnyBest]  Woodcock, B., "Best Practices in DNS Service-Provision
              Architecture", Version 1.2, March 2016,
              <https://meetings.icann.org/en/marrakech55/schedule/mon-
              tech/presentation-dns-service-provision-07mar16-en.pdf>.

   [AnyFRoot] Woolf, S., "Anycasting f.root-servers.net", January 2003,
              <https://archive.nanog.org/meetings/nanog27/presentations/
              suzanne.pdf>.

   [AnyTest]  Tangled, "Tangled Anycast Testbed",
              <http://www.anycast-testbed.com/>.

   [Ditl17]   DNS-OARC, "2017 DITL Data", April 2017,
              <https://www.dns-oarc.net/oarc/data/ditl/2017>.

   [IcannHedgehog]
              "hedgehog", commit b136eb0, May 2021,
              <https://github.com/dns-stats/hedgehog>.

   [Jung03a]  Jung, J., Berger, A., and H. Balakrishnan, "Modeling TTL-
              based Internet Caches", ACM 2003 IEEE INFOCOM,
              DOI 10.1109/INFCOM.2003.1208693, July 2003,
              <http://www.ieee-infocom.org/2003/papers/11_01.PDF>.

   [Moura16b] Moura, G.C.M., Schmidt, R. de O., Heidemann, J., de Vries,
              W., Müller, M., Wei, L., and C. Hesselman, "Anycast vs.
              DDoS: Evaluating the November 2015 Root DNS Event", ACM
              2016 Internet Measurement Conference,
              DOI 10.1145/2987443.2987446, November 2016,
              <https://www.isi.edu/~johnh/PAPERS/Moura16b.pdf>.

   [Moura18b] Moura, G.C.M., Heidemann, J., Müller, M., Schmidt, R. de
              O., and M. Davids, "When the Dike Breaks: Dissecting DNS
              Defenses During DDoS", ACM 2018 Internet Measurement
              Conference, DOI 10.1145/3278532.3278534, October 2018,
              <https://www.isi.edu/~johnh/PAPERS/Moura18b.pdf>.

   [Moura19b] Moura, G.C.M., Hardaker, W., Heidemann, J., and R. de O.
              Schmidt, "Cache Me If You Can: Effects of DNS Time-to-
              Live", ACM 2019 Internet Measurement Conference,
              DOI 10.1145/3355369.3355568, October 2019,
              <https://www.isi.edu/~hardaker/papers/2019-10-cache-me-
              ttls.pdf>.

   [Mueller17b]
              Müller, M., Moura, G.C.M., Schmidt, R. de O., and J.
              Heidemann, "Recursives in the Wild: Engineering
              Authoritative DNS Servers", ACM 2017 Internet Measurement
              Conference, DOI 10.1145/3131365.3131366, November 2017,
              <https://www.isi.edu/%7ejohnh/PAPERS/Mueller17b.pdf>.

   [Perlroth16]
              Perlroth, N., "Hackers Used New Weapons to Disrupt Major
              Websites Across U.S.", October 2016,
              <https://www.nytimes.com/2016/10/22/business/internet-
              problems-attack.html>.

   [RFC4033]  Arends, R., Austein, R., Larson, M., Massey, D., and S.
              Rose, "DNS Security Introduction and Requirements",
              RFC 4033, DOI 10.17487/RFC4033, March 2005,
              <https://www.rfc-editor.org/info/rfc4033>.

   [RFC4034]  Arends, R., Austein, R., Larson, M., Massey, D., and S.
              Rose, "Resource Records for the DNS Security Extensions",
              RFC 4034, DOI 10.17487/RFC4034, March 2005,
              <https://www.rfc-editor.org/info/rfc4034>.

   [RFC4035]  Arends, R., Austein, R., Larson, M., Massey, D., and S.
              Rose, "Protocol Modifications for the DNS Security
              Extensions", RFC 4035, DOI 10.17487/RFC4035, March 2005,
              <https://www.rfc-editor.org/info/rfc4035>.

   [RFC4509]  Hardaker, W., "Use of SHA-256 in DNSSEC Delegation Signer
              (DS) Resource Records (RRs)", RFC 4509,
              DOI 10.17487/RFC4509, May 2006,
              <https://www.rfc-editor.org/info/rfc4509>.

   [RFC8811]  Mortensen, A., Ed., Reddy.K, T., Ed., Andreasen, F.,
              Teague, N., and R. Compton, "DDoS Open Threat Signaling
              (DOTS) Architecture", RFC 8811, DOI 10.17487/RFC8811,
              August 2020, <https://www.rfc-editor.org/info/rfc8811>.

   [RipeAtlas15a]
              RIPE Network Coordination Centre (RIPE NCC), "RIPE Atlas:
              A Global Internet Measurement Network", October 2015,
              <http://ipj.dreamhosters.com/wp-
              content/uploads/issues/2015/ipj18-3.pdf>.

   [RipeAtlas19a]
              RIPE Network Coordination Centre (RIPE NCC), "RIPE Atlas",
              <https://atlas.ripe.net>.

   [Schmidt17a]
              Schmidt, R. de O., Heidemann, J., and J. Kuipers, "Anycast
              Latency: How Many Sites Are Enough?", PAM 2017 Passive and
              Active Measurement Conference,
              DOI 10.1007/978-3-319-54328-4_14, March 2017,
              <https://www.isi.edu/%7ejohnh/PAPERS/Schmidt17a.pdf>.

   [Singla2014]
              Singla, A., Chandrasekaran, B., Godfrey, P., and B. Maggs,
              "The Internet at the Speed of Light", 13th ACM Workshop on
              Hot Topics in Networks, DOI 10.1145/2670518.2673876,
              October 2014,
              <http://speedierweb.web.engr.illinois.edu/cspeed/papers/
              hotnets14.pdf>.

   [VerfSrc]  "Verfploeter Source Code", commit f4792dc, May 2019,
              <https://github.com/Woutifier/verfploeter>.

   [Vries17b] de Vries, W., Schmidt, R. de O., Hardaker, W., Heidemann,
              J., de Boer, P-T., and A. Pras, "Broad and Load-Aware
              Anycast Mapping with Verfploeter", ACM 2017 Internet
              Measurement Conference, DOI 10.1145/3131365.3131371,
              November 2017,
              <https://www.isi.edu/%7ejohnh/PAPERS/Vries17b.pdf>.

Acknowledgements



   We would like to thank the reviewers of this document who offered
   valuable suggestions as well as comments at the IETF DNSOP session
   (IETF 104): Duane Wessels, Joe Abley, Toema Gavrichenkov, John
   Levine, Michael StJohns, Kristof Tuyteleers, Stefan Ubbink, Klaus
   Darilion, and Samir Jafferali.

   Additionally, we would like thank those acknowledged in the papers
   this document summarizes for helping produce the results: RIPE NCC
   and DNS OARC for their tools and datasets used in this research, as
   well as the funding agencies sponsoring the individual research.

Contributors

   This document is a summary of the main considerations of six research
   papers written by the authors and the following people who
   contributed substantially to the content and should be considered
   coauthors; this document would not have been possible without their
   hard work:

   *  Ricardo de O. Schmidt

   *  Wouter B. de Vries

   *  Moritz Mueller

   *  Lan Wei

   *  Cristian Hesselman

   *  Jan Harm Kuipers

   *  Pieter-Tjerk de Boer

   *  Aiko Pras

Authors' Addresses



   Giovane C. M. Moura
   SIDN Labs/TU Delft
   Meander 501
   6825 MD Arnhem
   Netherlands
   Phone: +31 26 352 5500
   Email: giovane.moura@sidn.nl


   Wes Hardaker
   USC/Information Sciences Institute
   PO Box 382
   Davis, CA 95617-0382
   United States of America
   Phone: +1 (530) 404-0099
   Email: ietf@hardakers.net


   John Heidemann
   USC/Information Sciences Institute
   4676 Admiralty Way
   Marina Del Rey, CA 90292-6695
   United States of America
   Phone: +1 (310) 448-8708
   Email: johnh@isi.edu


   Marco Davids
   SIDN Labs
   Meander 501
   6825 MD Arnhem
   Netherlands
   Phone: +31 26 352 5500
   Email: marco.davids@sidn.nl