CS代考 IETF-80 1 &

Ólafur Guðmundsson Shinkuro, Inc.
2011-03-27
DNS Tutorial @ IETF-80 1 &

Copyright By PowCoder代写 加微信 powcoder

◦ Give the audience basic understanding of DNS to be able to facilitate new uses of DNS and take advantage of DNSSEC in the protocols they specify in the IETF.
 Tutorial Focus: Big picture – Not software help
– DNS != BIND
– No gory protocol details
– Location of slides: – http://
2011-03-27
DNS Tutorial @ IETF-80 2 &

DNS Tutorial @ IETF-80 3 2011-03-27 &

DNS is global “loosely consistent” delegated database
 delegated -> contents are under local control
 loosely consistent -> shared information (within constraints)
◦ does not need to match or be up-to date.
◦ operation is global with owners of “names” responsible for
 Data on wire is binary
 Domain names are case insensitive for [A-Z][a-z],
◦ case sensitive for others ( exämple.com != exÄmple.com)
 Hostname [A..Z0..9-] RFC952
◦ Restricts names that can be used
◦ IDN provides standard encoding for names in non-US_ASCII
DNS Tutorial @ IETF-80 4 2011-03-27 &
serving up their own data.

ORG COM DE IS UK CAT
ogud ISOC DENIC
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 Domain name: any name represented in the DNS format ◦ foo.bar.example.
◦ \0231br.example.
 DNS label:
◦ each string between two “.” (unless the dot is prefixed by “\”) ◦ i.e. foo.bar is 2 labels foo\.bar is 1 label
 DNS zone:
◦ a set of names that are under the same authority
◦ example.com and ftp.example.com, www.example.com ◦ Zone can be deeper than one label, example .us, ENUM
 Delegation:
◦ Transfer of authority for/to a sub-domain  example.org is a delegation from org
 the terms parent and child will be used.
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 Resolver
◦ stub: simple, only asks questions
◦ recursive: takes simple query and makes all necessary steps to assemble the full answer,
◦ caching: A recursive resolver that stores prior results and reuses them
◦ authoritative: the servers that contain the zone file for
a zone, one Primary, one or more Secondaries,
 Some implementations perform resolver and server roles.
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 DNS is a “lookup service”
◦ Simple queries –> simple answers  No search
 no ‘best fit’ answers
◦ Limited data expansion capability  DNS reasons for success
 “holy” Q-trinity: QNAME, QCLASS, QTYPE
 Explicit transfer of authority
 Parent is authoritative for existence of delegation,  Child is authoritative for contents.
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 RR: a single Resource Record
 RRSet: all RRs of same type at a name
◦ Minimum transmission unit  Example:

◦ ogud.com. 13630 IN MX 10 mail.ogud.com.
◦ ogud.com. 13630 IN MX 90 smtp.elistx.com.
 TTL (Time To Live):
◦ The maximum time an RRSet can be cached/
reused by a non- authoritative server
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• Transport:
– UDP 512 bytes Payload, with TCP
• RFC3226increasesto1220bytes
– EDNS0 (OPT RR) (RFC2671) expands UDP payload size by mutual
agreement.
– TSIG (RFC2845) hop by hop authentication and integrity
• Retransmission: built in – Resends timed-out-query
• Possibly to a different server. 2011-03-27
111111 0123456789012345
+–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+ | ID | +–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+ |QR| Opcode |AA|TC|RD|RA| Z|AD|CD| RCODE | +–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+ | QDCOUNT ==1 | +–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+ | ANCOUNT | +–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+ | NSCOUNT | +–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+ | ARCOUNT | +–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+–+ Query section contains:
QNAME: QCLASS: 2 bytes
QTYPE: 2 bytes.
Set by query
Set by responder
DNS Tutorial @ IETF-80 10 &

+——————+—–+——+——–+—-+———–+
+ Domain name |type | class| TTL | RL | RDATA |
+——————+—–+——+——–+—-+———–+
2 2 4
 Owner name (domain name) ◦ Encoded as sequence of labels
 Eachlabelcontains
 Length (1 byte)
 Name (n bytes [1..63])
 example.com  07example03com00
 Type : MX, A, AAAA, NS …
 CLASS: IN (other classes exist, but none global)
 TTL: Time To Live in a cache
 RL: RD LENG TH: size of RDATA
 RD A TA: The contents of the RR
◦ Binary blob, no TLV (XXX Type Length Value).

DNS Tutorial @ IETF-80 2011-03-27 &

 DNS zone is loaded on authoritative servers,
◦ servers keep in sync using information in SOA RR via AXFR,
IXFR or other means.
 DNS caches only store data for a “short” time
◦ defined by TTL on RRSet.
 DNS Resolvers start at longest match on query name they have in cache when looking for data, and follow delegations until an answer or negative answer is received.
◦ Longest match := if resolver has some of the right hand side delegations it will use them rather than start all queries at the root servers.
◦ DNS transactions are fast if servers are reachable.
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 QNAME: www.dnsop.org  QCLASS: IN
 QTYPE:A
Root Server
Org Server
www.dnsop.org
www.dnsop.org
A 81.91.170.12
2011-03-27
Ask dnsop.org NS
Resolv www.dnsop.org
dnsop.org Server
er A 81.91.170.12
DNS Tutorial @ IETF-80 &

 Whole or none of RRSet will arrive, ◦ in non determined/random order.
 DNS Resolver API may apply RR type specific rules to the order the RR’s are returned.
 DNS data should reside in one place and one place only
◦ at name, or at .name
◦ zone wide defaults do not exist
 the “zone” is an artificial boundary for management purpose
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 DNS Internal types
◦ NS, SOA, DS, DNSKEY, RRSIG, NSEC, NSEC3
 Only used by DNS for its operation  Indirect RR:
◦ CNAME, DNAME
 Indirect DNS RR cause Resolver to change direction of search
 Servermusthavespecialprocessingcode  Terminal RR:
◦ Address records  A, AAAA,
◦ Informational/Data
 TXT, HINFO, KEY, SSHFP
 carryinformationtoapplications  Non Terminal RR:
◦ MX, SRV, PTR, KX, A6, NAPTR, AFSDB
 contain domain names that may lead to further queries.
◦ OPT, TSIG, TKEY, SIG(0)
 Not stored in DNS zones, only appear on wire
2011-03-27 &
DNS Tutorial @ IETF-80 15

 Some early DNS implementation hard coded RR types.
◦ Unknown RR were/are dropped by some resolvers/API’s
◦ Unknown RR were not served by authoritative servers  Implication: introduction of new RR types took long time
 Solution:
◦ RFC3597 defines that all DNS servers and resolvers MUST  support unknown RR types and rules for defining them.
 suggests a common encoding in presentation format for them.
◦ Deployment: (partial list)
 BIND-9, BIND-8.2.2, ANS, CNS, MS DNS-2003, DNSCache, NSD,
PowerDNS, Net::DNS, DNSJava, DNSpython, etc.
◦ Issue: Not all DNS APIs are aware of unknown RR types
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 Is not a default but a provisioning aid
 match ONLY non existing names
 expansion is terminated by existing names do not expand past zone boundaries
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 Record:
*.example MX 10 mail.example
◦ matches any name, below the name example !!
◦ supplies RR type to names present, that are missing MX RRs.
 Is added to the MX RRSet at a name ◦ expands only one level
 www.*.example will expand
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 Contents of a zone:
*.example. TXT “this is a wildcard”
www.example. A 127.0.0.1
jon.doe.example. A 127.0.0.2
 Name “doe.example”
exists w/o any RRtypesempty non- terminal
 Name “tina.doe.example.” will not be expanded from wildcard
 Name: “tina.eod.example.” Matched. 2011-03-27
DNS Tutorial @ IETF-80 19 &

 Packet size:
◦ 512forstandardDNS,4K+forEDNS0
 Some middle boxes restrict UDP fragmentseffective <1500 size restriction. ◦ KeepingRRSetssmallisgoodpractice.  DNS API: not really good by default ◦ Restricted to “known” types ◦ One query at a time ◦ No indication of credibility/security status  Data integrity: Cache Poisoning ◦ DNSanswercanbeforged,inparticularifquerystreamisvisible ◦ useprotectedchanneltorecursiveresolvers. ◦ KaminskiattackResolversgotmuchhardertopoison,RFC5452  Broken DNS Software: ◦ Middleboxes(firewalls,homerouters,loadbalancers) ◦ NotmodernDNSresolvers,servers  DNS name tricks ◦ NotaDNSprotocolissuebutuserinterfaceorspoofing DNS Tutorial @ IETF-80 20 2011-03-27 &  DNS Update (RFC2136): ◦ adds the ability to change DNS contents of the fly  used a lot.  SHOULDonlybeusedfor“leaf”data  Difficult to add/modify data due to operator ◦ DNS Secure Update (RFC3007) specifies how to securely delegate capability to update DNS names or name/type(s)  One RR changes whole zone is sent to secondaries ◦ Incremental Zone transfer (IXFR) (RFC1995) enables transfers of only the recently changed data  DNSanycastcloudswithover100’sofserversusethistomaintainlargezones that are updated frequently  think seconds between updates ◦ Notify (RFC1996) informs secondaries that update is available. DNS Tutorial @ IETF-80 21 2011-03-27 & DNS Tutorial @ IETF-80 22 2011-03-27 &  RFC 3833 covers the threats to DNS transport and resolution. ◦ DNS provisioning threats uncovered.  Garbage In Signed Garbage Out (GISGO)  DNSSEC is the solution in protocol space  DNSSEC is gaining traction ◦ Root is signed, ◦ 69 TLDs signed, 64 have DS in root  .org, .net, .info, .cz, .us, .nl, .se, .jp, ...  .com will add DS this week. ◦ Many more soon DNS Tutorial @ IETF-80 23 2011-03-27 &  Role: Protect DNS ◦ How done: view from 10 km.  A DNS RRSet is signed by the zone it belongs to.  DS RRSet is vouched for by parent zone.  Chain of trust DSDNSKEYDSDNSKEY  What DNSSEC does not do: ◦ Make data in DNS any more correct DNS Tutorial @ IETF-80 24 2011-03-27 &  Data integrity protection ◦ Each DNS RRSet is signed by a digital signature  RRSIG containing a signature by the zone private key, for a certain time period  Existence proof: ◦ Chain of NSEC or NSEC3 records lists all names in a zone and their RR types. (authentic proof/denial of existence)  Parent signs a fingerprint of child's Key Signing DNSKEY (DS RR) ◦ allows transition from a secure parent zone to a secure child zone. DNS Tutorial @ IETF-80 25 2011-03-27 &  Vendor support is getting better.  Modern tools allow take care of all the hard work.  Zone maintenance processes need to change due ◦ signing step for new data, ◦ Periodic resigning.  Cost benefit: signing zones may allow reduction in Certificate costs. DNS Tutorial @ IETF-80 26 2011-03-27 &  Just do it, almost nothing breaks, cost is small ◦ Just make sure you are running RECENT software. (i.e. no extended support versions)  Only configure the root key and turn on key maintenance. DNS Tutorial @ IETF-80 27 2011-03-27 & DNS answer with verifiably signed RRSet is known to be identical to what zone maintainer initially entered Widely deployed DNSSEC allows applications to retrieve important data from DNS unsigned keying info  IPSECKEY, SSHFP, DANE spoof proof service location Remote Site “authorization” Jabber.ogud.com CNAME jabber.outsourcer.example No need for protocol specific keying infrastructure other... DNS Tutorial @ IETF-80 28 2011-03-27 & DNS Tutorial @ IETF-80 29 2011-03-27 &  If your data is small (<2K)  If the naming of the application objects map into DNS names easily.  If the providers of the information are close to the names  If you need “global” access  If the information is PUBLIC DNS Tutorial @ IETF-80 30 2011-03-27 &  Private/confidential data  Access control needed  Large data  Unstructured  Naming is difficult  You need search or match capability  DNS Tutorial @ IETF-80 31 2011-03-27 &  DHCP: if data is consumed locally ◦ much better choice  Service location (see above) and also depends on if accessed via local resource or more “global” one. ◦ Enterprise vs site location ◦ No search  Distributed databases 2011-03-27 & DNS Tutorial @ IETF-80 32  New class ◦ You need to supply the root servers for it   (TLD) ◦ Talk to ICANN  Use framework like SRV or NAPTR  Reuse TXT (or some other type)  .name
 R Type
 Read RFC5507
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 Email uses port 25, ssh uses port 22, web uses port 80 …..
 What if you want to answer for many “names” with different contexts ?
 Service names free you from what port is used
◦ same service can be provided on many ports on same address but in different contexts
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 Extensively used in MS Active Directory and OS-X applications
◦ Also used by Jabber, sip and other appliations
 SRV format[RFC2782]:
◦ Priority, weight, port, host
◦ _xmpp-client._tcp.jabber.org.
 SRV 30 30 5222 hermes.jabber.org.
◦ Priority + weight provides capability for simple load balancing.  SRV works best if you have a TCP or UDP service and
want to be able to delegate and distribute
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 Role: map name to set of services represented by URI
 SRV doesn‘t help
◦ No local part
◦ No variable scheme
 Naming Authority Pointer: NAPTR
◦ preference 16
◦ service
◦ replacement
16 bit value value
character-string character-string character-string domain-name
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 NAPTR record does not stand on its own
◦ DDDS == Dynamic Delegation Discovery System  UsedinENUMandONS(theRFIDnamespace)
 These create their own name spaces  RFC 3401-3405
◦ S-NAPTR == SRV and NAPTR combined  AvoidsapplicationspecificDDDSoverhead
 RFC 3958
◦ U-NAPTR == NAPTR maps to single URI
 Avoidstherewrites  RFC 4848
 QNAME for [SU]-NAPTR not easily determined.
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 Needs careful consideration if type is used by core protocols
◦ Record type does not stand on its own, needs resolution context before it is useful
◦ RBL use A for policy information
 BUT only in non routable address space (127/8)
 TXT may appear as the obvious choice ◦ No semantics
◦ RFC 1464 sub-typing
◦ prefixing could help, but has its own problems ◦ TXT verbose for binary information,
◦ If new RRSet is large you want EDNS0 support
 Modern software does this and unknown types as well!!!!
 MORAL: Fight for local upgrades, do not force the whole Internet to work around your local issues.
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 Selector put in front of (underneath) domain name:
◦ _axfr.example.org APL 1:127.0.0.1
◦ May interfere with zone maintainer’s naming policy
◦ Prefix may end up in a different zone
◦ Wildcards will not work like expected, i.e. _prefix.*.example.org does not expand
◦ No registry for prefixes  Magic name, e.g. www
◦ Overloading of multiple names in single application server
◦ Again may conflict with naming policy
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 Full control over contents
 Application centered semantics
 Simpler for applications to parse ◦ If your specification is simple: KISS
 No collisions, smaller
 Resolution context provided
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 Fill out template from RFC 6195 and send to
 IANA will forward template to an expert and conduct a public review
 DNS expert will render decision based on guidance in RFC 6195.
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 Tailor it to your needs,
◦ Be specific
◦ Restrict flexibility (avoid being overly generic)
 Be compact, binary fields are fine  Ask the experts for help early
◦ DNSEXT and DNSOP chairs will help
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 Provide tools to
◦ convert new RR type from/to textual format to
RFC3597 portable format for zone inclusion, ◦ Provide dynamic update tool of new types.
 Good tool kits: NET::DNS, DNSJava, DNSpython  Assume software is modern !!
◦ Modern Servers: (partial list)
 BIND-9, MS DNSServer2003, NSD, PowerDNS, ANS, CNS
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 Goal: allow keying information for a TLS service to be distributed by DNS.
 Requirement:
◦ TLS requires a CERT to create connection. ◦ DNSSEC validation
 Approach:
◦ Full cert or hash of the cert
◦ _._tcp.
◦ R format, reuse by others expected
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 Goal: Allow child to signal to parent what to place in DS set
 Requirement: Parent has DS for child  Approach: Reuse DS format.
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 IETF working groups ◦ DNS EXTensions:
 http://tools.ietf.org/wg/dnsext ◦ DNS Operations:
 http://tools.ietf.org/wg/dnsop  Individual sites
◦ http://en.wikipedia.org/wiki/Domain_Name_System  DNS book list
◦ http://www.networkingbooks.org/dns
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 DNS related RFC 100+ ◦ Many obsolete
 Important ones
◦ 1034, 1035 Original specification
◦ 4033, 4034, 4035, 5155 DNSSEC
◦ 1123,2181 Clarifications
◦ 3597, 2136, 1996, 1995, 3007 Major protocol enhancements
◦ 3833 Threat Analysis for DNS ◦ 5507 DNS design choices
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 Extra information provided in background slides
 Questions &Comments
DNS Tutorial @ IETF-80 48 2011-03-27 &

 Problem:
◦ Frequently Non-terminal records proposed demand that, terminal
records be returned in answer ==> Additional section processing  Facts:
1. Additional section processing is done in servers
2. Before updated servers are deployed RRtype aware resolvers need to
3. Not all authoritative servers may have the necessary glue
4. Glue may not fit
5. Recursive resolver may have data already
6. Roundtrips are cheap, parallel is good
7. Lacy resolver writer will ASSUME additional section processing is done
 Result:
◦ Recursive Resolver has to be able to do work forever,
 Moral: Do not attempt to

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