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Internet Engineering Task Force (IETF) E. Lewis | |
Request for Comments: 5936 NeuStar, Inc. | |
Updates: 1034, 1035 A. Hoenes, Ed. | |
Category: Standards Track TR-Sys | |
ISSN: 2070-1721 June 2010 | |
DNS Zone Transfer Protocol (AXFR) | |
Abstract | |
The standard means within the Domain Name System protocol for | |
maintaining coherence among a zone's authoritative name servers | |
consists of three mechanisms. Authoritative Transfer (AXFR) is one | |
of the mechanisms and is defined in RFC 1034 and RFC 1035. | |
The definition of AXFR has proven insufficient in detail, thereby | |
forcing implementations intended to be compliant to make assumptions, | |
impeding interoperability. Yet today we have a satisfactory set of | |
implementations that do interoperate. This document is a new | |
definition of AXFR -- new in the sense that it records an accurate | |
definition of an interoperable AXFR mechanism. | |
Status of This Memo | |
This is an Internet Standards Track document. | |
This document is a product of the Internet Engineering Task Force | |
(IETF). It represents the consensus of the IETF community. It has | |
received public review and has been approved for publication by the | |
Internet Engineering Steering Group (IESG). Further information on | |
Internet Standards is available in Section 2 of RFC 5741. | |
Information about the current status of this document, any errata, | |
and how to provide feedback on it may be obtained at | |
http://www.rfc-editor.org/info/rfc5936. | |
Lewis & Hoenes Standards Track [Page 1] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
Copyright Notice | |
Copyright (c) 2010 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 | |
(http://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. Code Components extracted from this document must | |
include Simplified BSD License text as described in Section 4.e of | |
the Trust Legal Provisions and are provided without warranty as | |
described in the Simplified BSD License. | |
This document may contain material from IETF Documents or IETF | |
Contributions published or made publicly available before November | |
10, 2008. The person(s) controlling the copyright in some of this | |
material may not have granted the IETF Trust the right to allow | |
modifications of such material outside the IETF Standards Process. | |
Without obtaining an adequate license from the person(s) controlling | |
the copyright in such materials, this document may not be modified | |
outside the IETF Standards Process, and derivative works of it may | |
not be created outside the IETF Standards Process, except to format | |
it for publication as an RFC or to translate it into languages other | |
than English. | |
Lewis & Hoenes Standards Track [Page 2] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
Table of Contents | |
1. Introduction ....................................................4 | |
1.1. Definition of Terms ........................................4 | |
1.2. Scope ......................................................5 | |
1.3. Context ....................................................5 | |
1.4. Coverage and Relationship to Original AXFR Specification ...5 | |
2. AXFR Messages ...................................................6 | |
2.1. AXFR Query .................................................8 | |
2.1.1. Header Values .......................................8 | |
2.1.2. Question Section ...................................10 | |
2.1.3. Answer Section .....................................10 | |
2.1.4. Authority Section ..................................10 | |
2.1.5. Additional Section .................................10 | |
2.2. AXFR Response .............................................11 | |
2.2.1. Header Values ......................................12 | |
2.2.2. Question Section ...................................14 | |
2.2.3. Answer Section .....................................14 | |
2.2.4. Authority Section ..................................14 | |
2.2.5. Additional Section .................................14 | |
2.3. TCP Connection Aborts .....................................15 | |
3. Zone Contents ..................................................15 | |
3.1. Records to Include ........................................15 | |
3.2. Delegation Records ........................................16 | |
3.3. Glue Records ..............................................18 | |
3.4. Name Compression ..........................................19 | |
3.5. Occluded Names ............................................19 | |
4. Transport ......................................................20 | |
4.1. TCP .......................................................20 | |
4.1.1. AXFR Client TCP ....................................21 | |
4.1.2. AXFR Server TCP ....................................22 | |
4.2. UDP .......................................................22 | |
5. Authorization ..................................................22 | |
6. Zone Integrity .................................................23 | |
7. Backwards Compatibility ........................................24 | |
7.1. Server ....................................................24 | |
7.2. Client ....................................................25 | |
8. Security Considerations ........................................25 | |
9. IANA Considerations ............................................25 | |
10. Internationalization Considerations ...........................25 | |
11. Acknowledgments ...............................................25 | |
12. References ....................................................26 | |
12.1. Normative References .....................................26 | |
12.2. Informative References ...................................28 | |
Lewis & Hoenes Standards Track [Page 3] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
1. Introduction | |
The Domain Name System standard facilities for maintaining coherent | |
servers for a zone consist of three elements. Authoritative Transfer | |
(AXFR) is defined in "Domain Names - Concepts and Facilities" | |
[RFC1034] (referred to in this document as RFC 1034) and "Domain | |
Names - Implementation and Specification" [RFC1035] (henceforth RFC | |
1035). Incremental Zone Transfer (IXFR) is defined in "Incremental | |
Zone Transfer in DNS" [RFC1995]. A mechanism for prompt notification | |
of zone changes (NOTIFY) is defined in "A Mechanism for Prompt | |
Notification of Zone Changes (DNS NOTIFY)" [RFC1996]. The goal of | |
these mechanisms is to enable a set of DNS name servers to remain | |
coherently authoritative for a given zone. | |
This document re-specifies the AXFR mechanism as it is deployed in | |
the Internet at large, hopefully with the precision expected from | |
modern Internet Standards, and thereby updates RFC 1034 and RFC 1035. | |
1.1. Definition of Terms | |
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", | |
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this | |
document are to be interpreted as described in "Key words for use in | |
RFCs to Indicate Requirement Levels" [BCP14]. | |
Use of "newer"/"new" and "older"/"old" DNS refers to implementations | |
written after and prior to the publication of this document. | |
"General-purpose DNS implementation" refers to DNS software developed | |
for widespread use. This includes resolvers and servers freely | |
accessible as libraries and standalone processes. This also includes | |
proprietary implementations used only in support of DNS service | |
offerings. | |
"Turnkey DNS implementation" refers to custom-made, single-use | |
implementations of DNS. Such implementations consist of software | |
that employs the DNS protocol message format yet does not conform to | |
the entire range of DNS functionality. | |
The terms "AXFR session", "AXFR server", and "AXFR client" will be | |
introduced in the first paragraph of Section 2, after some more | |
context has been established. | |
Lewis & Hoenes Standards Track [Page 4] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
1.2. Scope | |
In general terms, authoritative name servers for a given zone can use | |
various means to achieve coherency of the zone contents they serve. | |
For example, there are DNS implementations that assemble answers from | |
data stored in relational databases (as opposed to master files), | |
relying on the database's non-DNS means to synchronize the database | |
instances. Some of these non-DNS solutions interoperate in some | |
fashion. However, AXFR, IXFR, and NOTIFY are the only protocol- | |
defined in-band mechanisms to provide coherence of a set of name | |
servers, and they are the only mechanisms specified by the IETF. | |
This document does not cover incoherent DNS situations. There are | |
applications of the DNS in which servers for a zone are designed to | |
be incoherent. For these configurations, a coherency mechanism as | |
described here would be unsuitable. | |
A DNS implementation is not required to support AXFR, IXFR, and | |
NOTIFY, but it should have some means for maintaining name server | |
coherency. A general-purpose DNS implementation will likely support | |
AXFR (and in the same vein IXFR and NOTIFY), but turnkey DNS | |
implementations may exist without AXFR. | |
1.3. Context | |
Besides describing the mechanisms themselves, there is the context in | |
which they operate to consider. In the initial specifications of | |
AXFR (and IXFR and NOTIFY), little consideration was given to | |
security and privacy issues. Since the original definition of AXFR, | |
new opinions have appeared on the access to an entire zone's | |
contents. In this document, the basic mechanisms will be discussed | |
separately from the permission to use these mechanisms. | |
1.4. Coverage and Relationship to Original AXFR Specification | |
This document concentrates on just the definition of AXFR. Any | |
effort to update the specification of the IXFR or NOTIFY mechanisms | |
is left to different documents. | |
The original "specification" of the AXFR sub-protocol is scattered | |
through RFC 1034 and RFC 1035. Section 2.2 of RFC 1035 (on page 5) | |
depicts the scenario for which AXFR has been designed. Section 4.3.5 | |
of RFC 1034 describes the zone synchronization strategies in general | |
and rules for the invocation of a full zone transfer via AXFR; the | |
fifth paragraph of that section contains a very short sketch of the | |
AXFR protocol; Section 5.5 of RFC 2181 has corrected a significant | |
flaw in that specification. Section 3.2.3 of RFC 1035 has assigned | |
the code point for the AXFR QTYPE (see Section 2.1.2 below for more | |
Lewis & Hoenes Standards Track [Page 5] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
details). Section 4.2 of RFC 1035 discusses how the DNS uses the | |
transport layer and briefly explains why UDP transport is deemed | |
inappropriate for AXFR; the last paragraph of Section 4.2.2 gives | |
details regarding TCP connection management for AXFR. Finally, the | |
second paragraph of Section 6.3 in RFC 1035 mandates server behavior | |
when zone data changes occur during an ongoing zone transfer using | |
AXFR. | |
This document will update the specification of AXFR. To this end, it | |
fully specifies the record formats and processing rules for AXFR, | |
largely expanding on paragraph 5 of Section 4.3.5 of RFC 1034, and it | |
details the transport considerations for AXFR, thus amending Section | |
4.2.2 of RFC 1035. Furthermore, it discusses backward-compatibility | |
issues and provides policy/management considerations, as well as | |
specific security considerations for AXFR. The goal of this document | |
is to define AXFR as it is understood by the DNS community to exist | |
today. | |
2. AXFR Messages | |
An AXFR session consists of an AXFR query message and the sequence of | |
AXFR response messages returned for it. In this document, the AXFR | |
client is the sender of the AXFR query, and the AXFR server is the | |
responder. (Use of terms such as master, slave, primary, and | |
secondary are not important for defining AXFR.) The use of the word | |
"session" without qualification refers to an AXFR session. | |
An important aspect to keep in mind is that the definition of AXFR is | |
restricted to TCP [RFC0793] (see Section 4 for details). The design | |
of the AXFR process has certain inherent features that are not easily | |
ported to UDP [RFC0768]. | |
The basic format of an AXFR message is the DNS message as defined in | |
Section 4 ("MESSAGES") of RFC 1035 [RFC1035], updated by the | |
following documents. | |
o The "Basic" DNS specification: | |
- "A Mechanism for Prompt Notification of Zone Changes | |
(DNS NOTIFY)" [RFC1996] | |
- "Dynamic Updates in the Domain Name System (DNS UPDATE)" | |
[RFC2136] | |
- "Clarifications to the DNS Specification" [RFC2181] | |
- "Extension Mechanisms for DNS (EDNS0)" [RFC2671] | |
Lewis & Hoenes Standards Track [Page 6] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
- "Secret Key Transaction Authentication for DNS (TSIG)" | |
[RFC2845] | |
- "Secret Key Establishment for DNS (TKEY RR)" [RFC2930] | |
- "Obsoleting IQUERY" [RFC3425] | |
- "Handling of Unknown DNS Resource Record (RR) Types" | |
[RFC3597] | |
- "HMAC SHA (Hashed Message Authentication Code, Secure Hash | |
Algorithm) TSIG Algorithm Identifiers" [RFC4635] | |
- "Domain Name System (DNS) IANA Considerations" [RFC5395] | |
o Further additions related to the DNS Security Extensions (DNSSEC), | |
defined in these base documents: | |
- "DNS Security Introduction and Requirements" [RFC4033] | |
- "Resource Records for the DNS Security Extensions" | |
[RFC4034] | |
- "Protocol Modifications for the DNS Security Extensions" | |
[RFC4035] | |
- "Use of SHA-256 in DNSSEC Delegation Signer (DS) Resource | |
Records (RRs)" [RFC4509] | |
- "DNS Security (DNSSEC) Hashed Authenticated Denial of | |
Existence" [RFC5155] | |
- "Use of SHA-2 Algorithms with RSA in DNSKEY and RRSIG | |
Resource Records for DNSSEC" [RFC5702] | |
- "Clarifications and Implementation Notes for DNSSECbis" | |
[DNSSEC-U] | |
These documents contain information about the syntax and semantics of | |
DNS messages. They do not interfere with AXFR but are also helpful | |
in understanding what will be carried via AXFR. | |
For convenience, the synopsis of the DNS message header from | |
[RFC5395] (and the IANA registry for DNS Parameters [DNSVALS]) is | |
reproduced here informally: | |
Lewis & Hoenes Standards Track [Page 7] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ | |
| ID | | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ | |
|QR| OpCode |AA|TC|RD|RA| Z|AD|CD| RCODE | | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ | |
| QDCOUNT/ZOCOUNT | | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ | |
| ANCOUNT/PRCOUNT | | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ | |
| NSCOUNT/UPCOUNT | | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ | |
| ARCOUNT | | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ | |
This document makes use of the field names as they appear in this | |
diagram. The names of sections in the body of DNS messages are | |
capitalized in this document for clarity, e.g., "Additional section". | |
The DNS message size limit from [RFC1035] for DNS over UDP (and its | |
extension via the EDNS0 mechanism specified in [RFC2671]) is not | |
relevant for AXFR, as explained in Section 4. The upper limit on the | |
permissible size of a DNS message over TCP is only restricted by the | |
TCP framing defined in Section 4.2.2 of RFC 1035, which specifies a | |
two-octet message length field, understood to be unsigned, and thus | |
causing a limit of 65535 octets. This limit is not changed by EDNS0. | |
Note that the TC (truncation) bit is never set by an AXFR server nor | |
considered/read by an AXFR client. | |
2.1. AXFR Query | |
An AXFR query is sent by a client whenever there is a reason to ask. | |
This might be because of scheduled or triggered zone maintenance | |
activities (see Section 4.3.5 of RFC 1034 and DNS NOTIFY [RFC1996], | |
respectively) or as a result of a command line request, say for | |
debugging. | |
2.1.1. Header Values | |
These are the DNS message header values for an AXFR query. | |
ID Selected by client; see Note a) | |
QR MUST be 0 (Query) | |
OPCODE MUST be 0 (Standard Query) | |
Lewis & Hoenes Standards Track [Page 8] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
Flags: | |
AA "n/a" -- see Note b) | |
TC "n/a" -- see Note b) | |
RD "n/a" -- see Note b) | |
RA "n/a" -- see Note b) | |
Z "mbz" -- see Note c) | |
AD "n/a" -- see Note b) | |
CD "n/a" -- see Note b) | |
RCODE MUST be 0 (No error) | |
QDCOUNT Number of entries in Question section; MUST be 1 | |
ANCOUNT Number of entries in Answer section; MUST be 0 | |
NSCOUNT Number of entries in Authority section; MUST be 0 | |
ARCOUNT Number of entries in Additional section -- see Note d) | |
Notes: | |
a) Set to any value that the client is not already using with the | |
same server. There is no specific means for selecting the value | |
in this field. (Recall that AXFR is done only via TCP connections | |
-- see Section 4, "Transport".) | |
A server MUST reply using messages that use the same message ID to | |
allow a client to have multiple queries outstanding concurrently | |
over the same TCP connection -- see Note a) in Section 2.2.1 for | |
more details. | |
b) "n/a" -- The value in this field has no meaning in the context of | |
AXFR query messages. For the client, it is RECOMMENDED that the | |
value be zero. The server MUST ignore this value. | |
c) "mbz" -- The client MUST set this bit to 0; the server MUST ignore | |
it. | |
d) The client MUST set this field to the number of resource records | |
it places into the Additional section. In the absence of explicit | |
specification of new RRs to be carried in the Additional section | |
of AXFR queries, the value MAY be 0, 1, or 2. See Section 2.1.5, | |
"Additional Section", for details on the currently applicable RRs. | |
Lewis & Hoenes Standards Track [Page 9] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
2.1.2. Question Section | |
The Question section of the AXFR query MUST conform to Section 4.1.2 | |
of RFC 1035, and contain a single resource record with the following | |
values: | |
QNAME the name of the zone requested | |
QTYPE AXFR (= 252), the pseudo-RR type for zone transfer | |
[DNSVALS] | |
QCLASS the class of the zone requested [DNSVALS] | |
2.1.3. Answer Section | |
The Answer section MUST be empty. | |
2.1.4. Authority Section | |
The Authority section MUST be empty. | |
2.1.5. Additional Section | |
Currently, two kinds of resource records are defined that can appear | |
in the Additional section of AXFR queries and responses: EDNS and DNS | |
transaction security. Future specifications defining RRs that can be | |
carried in the Additional section of normal DNS transactions need to | |
explicitly describe their use with AXFR, should that be desired. | |
The client MAY include one OPT resource record [RFC2671]. If the | |
server does not support EDNS0, the client MUST send this section | |
without an OPT resource record if there is a retry. However, the | |
protocol does not define an explicit indication that the server does | |
not support EDNS0; that needs to be inferred by the client. Often, | |
the server will return a FormErr(1) that might be related to the OPT | |
resource record. Note that, at the time of this writing, only the | |
EXTENDED-RCODE field of the OPT RR is meaningful in the context of | |
AXFR; future specifications of EDNS flags and/or EDNS options must | |
describe their usage in the context of AXFR, if applicable. | |
The client MAY include one transaction integrity and authentication | |
resource record, currently a choice of TSIG [RFC2845] or SIG(0) | |
[RFC2931]. If the server has indicated that it does not recognize | |
the resource record, and that the error is indeed caused by the | |
resource record, the client probably should not try again. Removing | |
the security data in the face of an obstacle ought to only be done | |
with full awareness of the implication of doing so. | |
Lewis & Hoenes Standards Track [Page 10] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
In general, if an AXFR client is aware that an AXFR server does not | |
support a particular mechanism, the client SHOULD NOT attempt to | |
engage the server using the mechanism (or engage the server at all). | |
A client could become aware of a server's abilities via a | |
configuration setting or via some other (as yet) undefined means. | |
The range of permissible resource records that MAY appear in the | |
Additional section might change over time. If either a change to an | |
existing resource record (like the OPT RR for EDNS) is made or a new | |
Additional section record is created, the new definitions ought to | |
include a discussion on the applicability and impact upon AXFR. | |
Future resource records residing in the Additional section might have | |
an effect that is orthogonal to AXFR, and so can ride through the | |
session as opaque data. In this case, a "wise" implementation ought | |
to be able to pass these records through without disruption. | |
2.2. AXFR Response | |
The AXFR response will consist of one or more messages. The special | |
case of a server closing the TCP connection without sending an AXFR | |
response is covered in Section 2.3. | |
An AXFR response that is transferring the zone's contents will | |
consist of a series (which could be a series of length 1) of DNS | |
messages. In such a series, the first message MUST begin with the | |
SOA resource record of the zone, and the last message MUST conclude | |
with the same SOA resource record. Intermediate messages MUST NOT | |
contain the SOA resource record. The AXFR server MUST copy the | |
Question section from the corresponding AXFR query message into the | |
first response message's Question section. For subsequent messages, | |
it MAY do the same or leave the Question section empty. | |
The AXFR protocol treats the zone contents as an unordered collection | |
(or to use the mathematical term, a "set") of RRs. Except for the | |
requirement that the transfer must begin and end with the SOA RR, | |
there is no requirement to send the RRs in any particular order or | |
grouped into response messages in any particular way. Although | |
servers typically do attempt to send related RRs (such as the RRs | |
forming an RRset, and the RRsets of a name) as a contiguous group or, | |
when message space allows, in the same response message, they are not | |
required to do so, and clients MUST accept any ordering and grouping | |
of the non-SOA RRs. Each RR SHOULD be transmitted only once, and | |
AXFR clients MUST ignore any duplicate RRs received. | |
Each AXFR response message SHOULD contain a sufficient number of RRs | |
to reasonably amortize the per-message overhead, up to the largest | |
number that will fit within a DNS message (taking the required | |
content of the other sections into account, as described below). | |
Lewis & Hoenes Standards Track [Page 11] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
Some old AXFR clients expect each response message to contain only a | |
single RR. To interoperate with such clients, the server MAY | |
restrict response messages to a single RR. As there is no standard | |
way to automatically detect such clients, this typically requires | |
manual configuration at the server. | |
To indicate an error in an AXFR response, the AXFR server sends a | |
single DNS message when the error condition is detected, with the | |
response code set to the appropriate value for the condition | |
encountered. Such a message terminates the AXFR session; it MUST | |
contain a copy of the Question section from the AXFR query in its | |
Question section, but the inclusion of the terminating SOA resource | |
record is not necessary. | |
An AXFR server may send a number of AXFR response messages free of an | |
error condition before it sends the message indicating an error. | |
2.2.1. Header Values | |
These are the DNS message header values for AXFR responses. | |
ID MUST be copied from request -- see Note a) | |
QR MUST be 1 (Response) | |
OPCODE MUST be 0 (Standard Query) | |
Flags: | |
AA normally 1 -- see Note b) | |
TC MUST be 0 (Not truncated) | |
RD RECOMMENDED: copy request's value; MAY be set to 0 | |
RA SHOULD be 0 -- see Note c) | |
Z "mbz" -- see Note d) | |
AD "mbz" -- see Note d) | |
CD "mbz" -- see Note d) | |
RCODE See Note e) | |
QDCOUNT MUST be 1 in the first message; | |
MUST be 0 or 1 in all following messages; | |
MUST be 1 if RCODE indicates an error | |
ANCOUNT See Note f) | |
NSCOUNT MUST be 0 | |
ARCOUNT See Note g) | |
Lewis & Hoenes Standards Track [Page 12] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
Notes: | |
a) Because some old implementations behave differently than is now | |
desired, the requirement on this field is stated in detail. New | |
DNS servers MUST set this field to the value of the AXFR query ID | |
in each AXFR response message for the session. AXFR clients MUST | |
be able to manage sessions resulting from the issuance of multiple | |
outstanding queries, whether AXFR queries or other DNS queries. A | |
client SHOULD discard responses that do not correspond (via the | |
message ID) to any outstanding queries. | |
Unless the client is sure that the server will consistently set | |
the ID field to the query's ID, the client is NOT RECOMMENDED to | |
issue any other queries until the end of the zone transfer. A | |
client MAY become aware of a server's abilities via a | |
configuration setting. | |
b) If the RCODE is 0 (no error), then the AA bit MUST be 1. For any | |
other value of RCODE, the AA bit MUST be set according to the | |
rules for that error code. If in doubt, it is RECOMMENDED that it | |
be set to 1. It is RECOMMENDED that the value be ignored by the | |
AXFR client. | |
c) It is RECOMMENDED that the server set the value to 0; the client | |
MUST ignore this value. | |
The server MAY set this value according to the local policy | |
regarding recursive service, but doing so might confuse the | |
interpretation of the response, as AXFR cannot be retrieved | |
recursively. A client MAY note the server's policy regarding | |
recursive service from this value, but SHOULD NOT conclude that | |
the AXFR response was obtained recursively, even if the RD bit was | |
1 in the query. | |
d) "mbz" -- The server MUST set this bit to 0; the client MUST ignore | |
it. | |
e) In the absence of an error, the server MUST set the value of this | |
field to NoError(0). If a server is not authoritative for the | |
queried zone, the server SHOULD set the value to NotAuth(9). | |
(Reminder: Consult the appropriate IANA registry [DNSVALS].) If a | |
client receives any other value in response, it MUST act according | |
to the error. For example, a malformed AXFR query or the presence | |
of an OPT resource record sent to an old server will result in a | |
FormErr(1) value. This value is not set as part of the AXFR- | |
specific response processing. The same is true for other values | |
indicating an error. | |
Lewis & Hoenes Standards Track [Page 13] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
f) The count of answer records MUST equal the number of resource | |
records in the AXFR Answer section. When a server is aware that a | |
client will only accept response messages with a single resource | |
record, then the value MUST be 1. A server MAY be made aware of a | |
client's limitations via configuration data. | |
g) The server MUST set this field to the number of resource records | |
it places into the Additional section. In the absence of explicit | |
specification of new RRs to be carried in the Additional section | |
of AXFR response messages, the value MAY be 0, 1, or 2. See | |
Section 2.1.5 above for details on the currently applicable RRs | |
and Section 2.2.5 for additional considerations specific to AXFR | |
servers. | |
2.2.2. Question Section | |
In the first response message, this section MUST be copied from the | |
query. In subsequent messages, this section MAY be copied from the | |
query, or it MAY be empty. However, in an error response message | |
(see Section 2.2), this section MUST be copied as well. The content | |
of this section MAY be used to determine the context of the message, | |
that is, the name of the zone being transferred. | |
2.2.3. Answer Section | |
The Answer section MUST be populated with the zone contents. See | |
Section 3 below on encoding zone contents. | |
2.2.4. Authority Section | |
The Authority section MUST be empty. | |
2.2.5. Additional Section | |
The contents of this section MUST follow the guidelines for the OPT, | |
TSIG, and SIG(0) RRs, or whatever other future record is possible | |
here. The contents of Section 2.1.5 apply analogously as well. | |
The following considerations specifically apply to AXFR responses: | |
If the client has supplied an EDNS OPT RR in the AXFR query and if | |
the server supports EDNS as well, it SHOULD include one OPT RR in the | |
first response message and MAY do so in subsequent response messages | |
(see Section 2.2); the specifications of EDNS options to be carried | |
in the OPT RR may impose stronger requirements. | |
Lewis & Hoenes Standards Track [Page 14] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
If the client has supplied a transaction security resource record | |
(currently a choice of TSIG and SIG(0)) and the server supports the | |
method chosen by the client, it MUST place the corresponding resource | |
record into the AXFR response message(s), according to the rules | |
specified for that method. | |
2.3. TCP Connection Aborts | |
If an AXFR client sends a query on a TCP connection and the | |
connection is closed at any point, the AXFR client MUST consider the | |
AXFR session terminated. The message ID MAY be used again on a new | |
connection, even if the question and AXFR server are the same. | |
Facing a dropped connection, a client SHOULD try to make some | |
determination as to whether the connection closure was the result of | |
network activity or due to a decision by the AXFR server. This | |
determination is not an exact science. It is up to the AXFR client | |
to react, but the implemented reaction SHOULD NOT be either an | |
endless cycle of retries or an increasing (in frequency) retry rate. | |
An AXFR server implementer should take into consideration the dilemma | |
described above when a connection is closed with an outstanding query | |
in the pipeline. For this reason, a server ought to reserve this | |
course of action for situations in which it believes beyond a doubt | |
that the AXFR client is attempting abusive behavior. | |
3. Zone Contents | |
The objective of the AXFR session is to request and transfer the | |
contents of a zone, in order to permit the AXFR client to faithfully | |
reconstruct the zone as it exists at the primary server for the given | |
zone serial number. The word "exists" here designates the externally | |
visible behavior, i.e., the zone content that is being served (handed | |
out to clients) -- not its persistent representation in a zone file | |
or database used by the server -- and that for consistency should be | |
served subsequently by the AXFR client in an identical manner. | |
Over time the definition of a zone has evolved from denoting a static | |
set of records to also cover a dynamically updated set of records, | |
and then a potentially continually regenerated set of records (e.g., | |
RRs synthesized "on the fly" from rule sets or database lookup | |
results in other forms than RR format) as well. | |
3.1. Records to Include | |
In the Answer section of AXFR response messages, the resource records | |
within a zone for the given serial number MUST appear. The | |
definition of what belongs in a zone is described in RFC 1034, | |
Lewis & Hoenes Standards Track [Page 15] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
Section 4.2, "How the database is divided into zones" (in particular | |
Section 4.2.1, "Technical considerations"), and it has been clarified | |
in Section 6 of RFC 2181. | |
Zones for which it is impractical to list the entire zone for a | |
serial number are not suitable for AXFR retrieval. A typical (but | |
not limiting) description of such a zone is a zone consisting of | |
responses generated via other database lookups and/or computed based | |
upon ever-changing data. | |
3.2. Delegation Records | |
In Section 4.2.1 of RFC 1034, this text appears (keep in mind that | |
the "should" in the quotation predates [BCP14], cf. Section 1.1): | |
The RRs that describe cuts ... should be exactly the same as the | |
corresponding RRs in the top node of the subzone. | |
There has been some controversy over this statement and the impact on | |
which NS resource records are included in a zone transfer. | |
The phrase "that describe cuts" is a reference to the NS set and | |
applicable glue records. It does not mean that the cut point and | |
apex resource records are identical. For example, the SOA resource | |
record is only found at the apex. The discussion here is restricted | |
to just the NS resource record set and glue, as these "describe | |
cuts". | |
DNSSEC resource records have special specifications regarding their | |
occurrence at a zone cut and the apex of a zone. This was first | |
described in Sections 5.3 ff. and 6.2 of RFC 2181 (for the initial | |
specification of DNSSEC), which parts of RFC 2181 now in fact are | |
historical. The current DNSSEC core document set (see second bullet | |
in Section 2 above) gives the full details for DNSSEC(bis) resource | |
record placement, and Section 3.1.5 of RFC 4035 normatively specifies | |
their treatment during AXFR; the alternate NSEC3 resource record | |
defined later in RFC 5155 behaves identically to the NSEC RR, for the | |
purpose of AXFR. | |
Informally: | |
o The DS RRSet only occurs at the parental side of a zone cut and is | |
authoritative data in the parent zone, not the secure child zone. | |
o The DNSKEY RRSet only occurs at the apex of a signed zone and is | |
part of the authoritative data of the zone it serves. | |
Lewis & Hoenes Standards Track [Page 16] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
o Independent RRSIG RRSets occur at the signed parent side of a zone | |
cut and at the apex of a signed zone; they are authoritative data | |
in the respective zone; simple queries for RRSIG resource records | |
may return both RRSets at once if the same server is authoritative | |
for the parent zone and the child zone (Section 3.1.5 of RFC 4035 | |
describes how to distinguish these RRs); this seeming ambiguity | |
does not occur for AXFR, since each such RRSIG RRset belongs to a | |
single zone. | |
o Different NSEC [RFC4034] (or NSEC3 [RFC5155]) resource records | |
equally may occur at the parental side of a zone cut and at the | |
apex of a zone; each such resource record belongs to exactly one | |
of these zones and is to be included in the AXFR of that zone. | |
One issue is that in operations there are times when the NS resource | |
records for a zone might be different at a cut point in the parent | |
and at the apex of a zone. Sometimes this is the result of an error, | |
and sometimes it is part of an ongoing change in name servers. The | |
DNS protocol is robust enough to overcome inconsistencies up to (but | |
not including) there being no parent-indicated NS resource record | |
referencing a server that is able to serve the child zone. This | |
robustness is one quality that has fueled the success of the DNS. | |
Still, the inconsistency is an error state, and steps need to be | |
taken to make it apparent (if it is unplanned). | |
Another issue is that the AXFR server could be authoritative for a | |
different set of zones than the AXFR client. It is possible that the | |
AXFR server be authoritative for both halves of an inconsistent cut | |
point and that the AXFR client is authoritative for just the parent | |
side of the cut point. | |
When facing a situation in which a cut point's NS resource records do | |
not match the authoritative set, the question arises whether an AXFR | |
server responds with the NS resource record set that is in the zone | |
being transferred or the one that is at the authoritative location. | |
The AXFR response MUST contain the cut point NS resource record set | |
registered with the zone whether it agrees with the authoritative set | |
or not. "Registered with" can be widely interpreted to include data | |
residing in the zone file of the zone for the particular serial | |
number (in zone file environments) or as any data configured to be in | |
the zone (database), statically or dynamically. | |
Lewis & Hoenes Standards Track [Page 17] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
The reasons for this requirement are: | |
1) The AXFR server might not be able to determine that there is an | |
inconsistency given local data; hence, requiring consistency would | |
mean a lot more needed work and even network retrieval of data. | |
An authoritative server ought not be required to perform any | |
queries. | |
2) By transferring the inconsistent NS resource records from a server | |
that is authoritative for both the cut point and the apex to a | |
client that is not authoritative for both, the error is exposed. | |
For example, an authorized administrator can manually request the | |
AXFR and inspect the results to see the inconsistent records. (A | |
server authoritative for both halves would otherwise always answer | |
from the more authoritative set, concealing the error.) | |
3) The inconsistent NS resource record set might indicate a problem | |
in a registration database. | |
4) This requirement is necessary to ensure that retrieving a given | |
(zone, serial) pair by AXFR yields the exact same set of resource | |
records, no matter which of the zone's authoritative servers is | |
chosen as the source of the transfer. | |
If an AXFR server were allowed to respond with the authoritative NS | |
RRset of a child zone instead of a parent-side NS RRset in the zone | |
being transferred, the set of records returned could vary depending | |
on whether or not the server happened to be authoritative for the | |
child zone as well. | |
The property that a given (zone, serial) pair corresponds to a | |
single, well-defined set of records is necessary for the correct | |
operation of incremental transfer protocols such as IXFR [RFC1995]. | |
For example, a client may retrieve a zone by AXFR from one server, | |
and then apply an incremental change obtained by IXFR from a | |
different server. If the two servers have different ideas of the | |
zone contents, the client can end up attempting to incrementally add | |
records that already exist or to delete records that do not exist. | |
3.3. Glue Records | |
As quoted in the previous section, Section 4.2.1 of RFC 1034 provides | |
guidance and rationale for the inclusion of glue records as part of | |
an AXFR response. And, as also argued in the previous section of | |
this document, even when there is an inconsistency between the | |
address in a glue record and the authoritative copy of the name | |
server's address, the glue resource record that is registered as part | |
of the zone for that serial number is to be included. | |
Lewis & Hoenes Standards Track [Page 18] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
This applies to glue records for any address family [IANA-AF]. | |
The AXFR response MUST contain the appropriate glue records as | |
registered with the zone. The interpretation of "registered with" in | |
the previous section applies here. Inconsistent glue records are an | |
operational matter. | |
3.4. Name Compression | |
Compression of names in DNS messages is described in RFC 1035, | |
Section 4.1.4, "Message compression". The issue highlighted here | |
relates to a comment made in RFC 1034, Section 3.1, "Name space | |
specifications and terminology", which says: | |
When you receive a domain name or label, you should preserve its | |
case. | |
("Should" in the quote predates [BCP14].) | |
Since the primary objective of AXFR is to enable the client to serve | |
the same zone content as the server, unlike such normal DNS responses | |
that are expected to preserve the case in the query, the actual zone | |
transfer needs to retain the case of the labels in the zone content. | |
Hence, name compression in an AXFR message SHOULD be performed in a | |
case-preserving manner, unlike how it is done for "normal" DNS | |
responses. That is, although when comparing a domain name for | |
matching, "a" equals "A", when comparing for the purposes of message | |
compression for AXFR, "a" is not equal to "A". Note that this is not | |
the usual definition of name comparison in the DNS protocol and | |
represents a new understanding of the requirement on AXFR servers. | |
Rules governing name compression of RDATA in an AXFR message MUST | |
abide by the specification in "Handling of Unknown DNS Resource | |
Record (RR) Types" [RFC3597], specifically, Section 4 on "Domain Name | |
Compression". | |
3.5. Occluded Names | |
Dynamic Update [RFC2136] operations, and in particular their | |
interaction with DNAME [RFC2672], can have a side effect of occluding | |
names in a zone. The addition of a delegation point via dynamic | |
update will render all subordinate domain names to be in a limbo, | |
still part of the zone but not available to the lookup process. The | |
addition of a DNAME resource record has the same impact. The | |
subordinate names are said to be "occluded". | |
Lewis & Hoenes Standards Track [Page 19] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
Occluded names MUST be included in AXFR responses. An AXFR client | |
MUST be able to identify and handle occluded names. The rationale | |
for this action is based on a speedy recovery if the dynamic update | |
operation was in error and is to be undone. | |
4. Transport | |
AXFR sessions are currently restricted to TCP by Section 4.3.5 of RFC | |
1034, which states: | |
Because accuracy is essential, TCP or some other reliable protocol | |
must be used for AXFR requests. | |
The restriction to TCP is also mentioned in Section 6.1.3.2 of | |
"Requirements for Internet Hosts - Application and Support" | |
[RFC1123]. | |
The most common scenario is for an AXFR client to open a TCP | |
connection to the AXFR server, send an AXFR query, receive the AXFR | |
response, and then close the connection. But variations of that most | |
simple scenario are legitimate and likely: in particular, sending a | |
query for the zone's SOA resource record first over the same TCP | |
connection, and reusing an existing TCP connection for other queries. | |
Therefore, the assumption that a TCP connection is dedicated to a | |
single AXFR session is incorrect. This wrong assumption has led to | |
implementation choices that prevent either multiple concurrent zone | |
transfers or the use of an open connection for other queries. | |
Since the early days of the DNS, operators who have sets of name | |
servers that are authoritative for a common set of zones have found | |
it desirable to be able to have multiple concurrent zone transfers in | |
progress; this way, a name server does not have to wait for one zone | |
transfer to complete before the next can begin. RFC 1035 did not | |
exclude this possibility, but legacy implementations failed to | |
support this functionality efficiently, over a single TCP connection. | |
The remaining presence of such legacy implementations makes it | |
necessary that new general-purpose client implementations still | |
provide options for graceful fallback to the old behavior in their | |
support of concurrent DNS transactions and AXFR sessions on a single | |
TCP connection. | |
4.1. TCP | |
In the original definition, there arguably is an implicit assumption | |
(probably unintentional) that a TCP connection is used for one and | |
only one AXFR session. This is evidenced in the lack of an explicit | |
requirement to copy the Question section and/or the message ID into | |
Lewis & Hoenes Standards Track [Page 20] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
responses, no explicit ordering information within the AXFR response | |
messages, and the lack of an explicit notice indicating that a zone | |
transfer continues in the next message. | |
The guidance given below is intended to enable better performance of | |
the AXFR exchange as well as provide guidelines on interactions with | |
older software. Better performance includes being able to multiplex | |
DNS message exchanges including zone transfer sessions. Guidelines | |
for interacting with older software are generally applicable to new | |
AXFR clients. In the reverse situation -- older AXFR client and | |
newer AXFR server -- the server ought to operate within the | |
specification for an older server. | |
4.1.1. AXFR Client TCP | |
An AXFR client MAY request a connection to an AXFR server for any | |
reason. An AXFR client SHOULD close the connection when there is no | |
apparent need to use the connection for some time period. The AXFR | |
server ought not have to maintain idle connections; the burden of | |
connection closure ought to be on the client. "Apparent need" for | |
the connection is a judgment for the AXFR client and the DNS client. | |
If the connection is used for multiple sessions, or if it is known | |
that sessions will be coming, or if there is other query/response | |
traffic anticipated or currently on the open connection, then there | |
is "apparent need". | |
An AXFR client can cancel the delivery of a zone only by closing the | |
connection. However, this action will also cancel all other | |
outstanding activity using the connection. There is no other | |
mechanism by which an AXFR response can be cancelled. | |
When a TCP connection is closed remotely (relative to the client), | |
whether by the AXFR server or due to a network event, the AXFR client | |
MUST cancel all outstanding sessions and non-AXFR transactions. | |
Recovery from this situation is not straightforward. If the | |
disruption was a spurious event, attempting to restart the connection | |
would be proper. If the disruption was caused by a failure that | |
proved to be persistent, the AXFR client would be wise not to spend | |
too many resources trying to rebuild the connection. Finally, if the | |
connection was dropped because of a policy at the AXFR server (as can | |
be the case with older AXFR servers), the AXFR client would be wise | |
not to retry the connection. Unfortunately, knowing which of the | |
three cases above (momentary disruption, failure, policy) applies is | |
not possible with certainty, and can only be assessed by heuristics. | |
This exemplifies the general complications for clients in connection- | |
oriented protocols not receiving meaningful error responses. | |
Lewis & Hoenes Standards Track [Page 21] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
An AXFR client MAY use an already opened TCP connection to start an | |
AXFR session. Using an existing open connection is RECOMMENDED over | |
opening a new connection. (Non-AXFR session traffic can also use an | |
open connection.) If in doing so the AXFR client realizes that the | |
responses cannot be properly differentiated (lack of matching query | |
IDs, for example) or the connection is terminated for a remote | |
reason, then the AXFR client SHOULD NOT attempt to reuse an open | |
connection with the specific AXFR server until the AXFR server is | |
updated (which is, of course, not an event captured in the DNS | |
protocol). | |
4.1.2. AXFR Server TCP | |
An AXFR server MUST be able to handle multiple AXFR sessions on a | |
single TCP connection, as well as to handle other query/response | |
transactions over it. | |
If a TCP connection is closed remotely, the AXFR server MUST cancel | |
all AXFR sessions in place. No retry activity is necessary; that is | |
initiated by the AXFR client. | |
Local policy MAY dictate that a TCP connection is to be closed. Such | |
an action SHOULD be in reaction to limits such as those placed on the | |
number of outstanding open connections. Closing a connection in | |
response to a suspected security event SHOULD be done only in extreme | |
cases, when the server is certain the action is warranted. An | |
isolated request for a zone not on the AXFR server SHOULD receive a | |
response with the appropriate response code and not see the | |
connection broken. | |
4.2. UDP | |
With the addition of EDNS0 and applications that require many small | |
zones, such as in web hosting and some ENUM scenarios, AXFR sessions | |
on UDP would now seem desirable. However, there are still some | |
aspects of AXFR sessions that are not easily translated to UDP. | |
Therefore, this document does not update RFC 1035 in this respect: | |
AXFR sessions over UDP transport are not defined. | |
5. Authorization | |
A zone administrator has the option to restrict AXFR access to a | |
zone. This was not envisioned in the original design of the DNS but | |
has emerged as a requirement as the DNS has evolved. Restrictions on | |
AXFR could be for various reasons including a desire (or in some | |
instances, having a legal requirement) to keep the bulk version of | |
the zone concealed or to prevent the servers from handling the load | |
Lewis & Hoenes Standards Track [Page 22] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
incurred in serving AXFR. It has been argued that these reasons are | |
questionable, but this document, driven by the desire to leverage the | |
interoperable practice that has evolved since RFC 1035, acknowledges | |
the factual requirement to provide mechanisms to restrict AXFR. | |
A DNS implementation SHOULD provide means to restrict AXFR sessions | |
to specific clients. | |
An implementation SHOULD allow access to be granted to Internet | |
Protocol addresses and ranges, regardless of whether a source address | |
could be spoofed. Combining this with techniques such as Virtual | |
Private Networks (VPNs) [RFC2764] or Virtual LANs has proven to be | |
effective. | |
A general-purpose implementation is RECOMMENDED to implement access | |
controls based upon "Secret Key Transaction Authentication for DNS | |
(TSIG)" [RFC2845] and/or "DNS Request and Transaction Signatures | |
( SIG(0)s )" [RFC2931]. | |
A general-purpose implementation SHOULD allow access to be open to | |
all AXFR requests. That is, an operator ought to be able to allow | |
any AXFR query to be granted. | |
A general-purpose implementation SHOULD NOT have a default policy for | |
AXFR requests to be "open to all". For example, a default could be | |
to restrict transfers to addresses selected by the DNS | |
administrator(s) for zones on the server. | |
6. Zone Integrity | |
An AXFR client MUST ensure that only a successfully transferred copy | |
of the zone data can be used to serve this zone. Previous | |
description and implementation practice has introduced a two-stage | |
model of the whole zone synchronization procedure: Upon a trigger | |
event (e.g., when polling of a SOA resource record detects a change | |
in the SOA serial number, or when a DNS NOTIFY request [RFC1996] is | |
received), the AXFR session is initiated, whereby the zone data are | |
saved in a zone file or database (this latter step is necessary | |
anyway to ensure proper restart of the server); upon successful | |
completion of the AXFR operation and some sanity checks, this data | |
set is "loaded" and made available for serving the zone in an atomic | |
operation, and flagged "valid" for use during the next restart of the | |
DNS server; if any error is detected, this data set MUST be deleted, | |
and the AXFR client MUST continue to serve the previous version of | |
the zone, if it did before. The externally visible behavior of an | |
AXFR client implementation MUST be equivalent to that of this two- | |
stage model. | |
Lewis & Hoenes Standards Track [Page 23] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
If an AXFR client rejects data obtained in an AXFR session, it SHOULD | |
remember the serial number and MAY attempt to retrieve the same zone | |
version again. The reason the same retrieval could make sense is | |
that the reason for the rejection could be rooted in an | |
implementation detail of one AXFR server used for the zone and not | |
present in another AXFR server used for the zone. | |
Ensuring that an AXFR client does not accept a forged copy of a zone | |
is important to the security of a zone. If a zone operator has the | |
opportunity, protection can be afforded via dedicated links, physical | |
or virtual via a VPN among the authoritative servers. But there are | |
instances in which zone operators have no choice but to run AXFR | |
sessions over the global public Internet. | |
Besides best attempts at securing TCP connections, DNS | |
implementations SHOULD provide means to make use of "Secret Key | |
Transaction Authentication for DNS (TSIG)" [RFC2845] and/or "DNS | |
Request and Transaction Signatures ( SIG(0)s )" [RFC2931] to allow | |
AXFR clients to verify the contents. These techniques MAY also be | |
used for authorization. | |
7. Backwards Compatibility | |
Describing backwards compatibility is difficult because of the lack | |
of specifics in the original definition. In this section, some hints | |
at building in backwards compatibility are given, mostly repeated | |
from the relevant earlier sections. | |
Backwards compatibility is not necessary, but the greater the extent | |
of an implementation's compatibility, the greater its | |
interoperability. For turnkey implementations, this is not usually a | |
concern. For general-purpose implementations, this takes on varying | |
levels of importance, depending on the implementer's desire to | |
maintain interoperability. | |
It is unfortunate that a need to fall back to older behavior cannot | |
be discovered, and thus has to be noted in a configuration file. An | |
implementation SHOULD, in its documentation, encourage operators to | |
periodically review AXFR clients and servers it has made notes about | |
repeatedly, as old software gets updated from time to time. | |
7.1. Server | |
An AXFR server has the luxury of being able to react to an AXFR | |
client's abilities, with the exception of knowing whether the client | |
can accept multiple resource records per AXFR response message. The | |
knowledge that a client is so restricted cannot be discovered; hence, | |
it has to be set by configuration. | |
Lewis & Hoenes Standards Track [Page 24] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
An implementation of an AXFR server MAY permit configuring, on a per | |
AXFR client basis, the necessity to revert to a single resource | |
record per message; in that case, the default SHOULD be to use | |
multiple records per message. | |
7.2. Client | |
An AXFR client has the opportunity to try other features (i.e., those | |
not defined by this document) when querying an AXFR server. | |
Attempting to issue multiple DNS queries over a TCP transport for an | |
AXFR session SHOULD be aborted if it interrupts the original request, | |
and SHOULD take into consideration whether the AXFR server intends to | |
close the connection immediately upon completion of the original | |
(connection-causing) zone transfer. | |
8. Security Considerations | |
This document is a clarification of a mechanism outlined in RFCs 1034 | |
and 1035 and as such does not add any new security considerations. | |
RFC 3833 [RFC3833] is devoted entirely to security considerations for | |
the DNS; its Section 4.3 delineates zone transfer security aspects | |
from the security threats addressed by DNSSEC. | |
Concerns regarding authorization, traffic flooding, and message | |
integrity are mentioned in "Authorization" (Section 5), "TCP" | |
(Section 4.1), and "Zone Integrity" (Section 6). | |
9. IANA Considerations | |
IANA has added a reference to this RFC in the AXFR (252) row of the | |
"Resource Record (RR) TYPEs" subregistry of the "Domain Name System | |
(DNS) Parameters" registry. | |
10. Internationalization Considerations | |
The AXFR protocol is transparent to the parts of DNS zone content | |
that can possibly be subject to Internationalization considerations. | |
It is assumed that for DNS labels and domain names, the issue has | |
been solved via "Internationalizing Domain Names in Applications | |
(IDNA)" [RFC3490] or its successor(s). | |
11. Acknowledgments | |
Earlier draft versions of this document have been edited by Andreas | |
Gustafsson. In his latest draft version, this acknowledgment | |
appeared: | |
Lewis & Hoenes Standards Track [Page 25] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
Many people have contributed input and commentary to earlier | |
versions of this document, including but not limited to Bob | |
Halley, Dan Bernstein, Eric A. Hall, Josh Littlefield, Kevin | |
Darcy, Robert Elz, Levon Esibov, Mark Andrews, Michael Patton, | |
Peter Koch, Sam Trenholme, and Brian Wellington. | |
Comments on later draft versions have come from these individuals: | |
Mark Andrews, Paul Vixie, Wouter Wijngaards, Iain Calder, Tony Finch, | |
Ian Jackson, Andreas Gustafsson, Brian Wellington, Niall O'Reilly, | |
Bill Manning, and other participants of the DNSEXT working group. | |
Significant comments from the IETF at large have been received from | |
Subramanian Moonesamy, Chris Lonvick, and Vijay K. Gurbani. | |
Edward Lewis served as a patiently listening sole document editor for | |
two years. | |
12. References | |
All "RFC" references below -- like all RFCs -- and information about | |
the RFC series can be obtained from the RFC Editor web site at | |
http://www.rfc-editor.org. | |
12.1. Normative References | |
[BCP14] Bradner, S., "Key words for use in RFCs to Indicate | |
Requirement Levels", BCP 14, RFC 2119, March 1997. | |
[RFC0793] Postel, J., "Transmission Control Protocol", STD 7, RFC | |
793, September 1981. | |
[RFC0768] Postel, J., "User Datagram Protocol", STD 6, RFC 768, | |
August 1980. | |
[RFC1034] Mockapetris, P., "Domain names - concepts and | |
facilities", STD 13, RFC 1034, November 1987. | |
[RFC1035] Mockapetris, P., "Domain names - implementation and | |
specification", STD 13, RFC 1035, November 1987. | |
[RFC1123] Braden, R., Ed., "Requirements for Internet Hosts - | |
Application and Support", STD 3, RFC 1123, October 1989. | |
[RFC1995] Ohta, M., "Incremental Zone Transfer in DNS", RFC 1995, | |
August 1996. | |
[RFC1996] Vixie, P., "A Mechanism for Prompt Notification of Zone | |
Changes (DNS NOTIFY)", RFC 1996, August 1996. | |
Lewis & Hoenes Standards Track [Page 26] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
[RFC2136] Vixie, P., Ed., Thomson, S., Rekhter, Y., and J. Bound, | |
"Dynamic Updates in the Domain Name System (DNS UPDATE)", | |
RFC 2136, April 1997. | |
[RFC2181] Elz, R. and R. Bush, "Clarifications to the DNS | |
Specification", RFC 2181, July 1997. | |
[RFC2671] Vixie, P., "Extension Mechanisms for DNS (EDNS0)", RFC | |
2671, August 1999. | |
[RFC2672] Crawford, M., "Non-Terminal DNS Name Redirection", RFC | |
2672, August 1999. | |
[RFC2845] Vixie, P., Gudmundsson, O., Eastlake 3rd, D., and B. | |
Wellington, "Secret Key Transaction Authentication for | |
DNS (TSIG)", RFC 2845, May 2000. | |
[RFC2930] Eastlake 3rd, D., "Secret Key Establishment for DNS (TKEY | |
RR)", RFC 2930, September 2000. | |
[RFC2931] Eastlake 3rd, D., "DNS Request and Transaction Signatures | |
( SIG(0)s )", RFC 2931, September 2000. | |
[RFC3425] Lawrence, D., "Obsoleting IQUERY", RFC 3425, November | |
2002. | |
[RFC3597] Gustafsson, A., "Handling of Unknown DNS Resource Record | |
(RR) Types", RFC 3597, September 2003. | |
[RFC4033] Arends, R., Austein, R., Larson, M., Massey, D., and S. | |
Rose, "DNS Security Introduction and Requirements", RFC | |
4033, March 2005. | |
[RFC4034] Arends, R., Austein, R., Larson, M., Massey, D., and S. | |
Rose, "Resource Records for the DNS Security Extensions", | |
RFC 4034, March 2005. | |
[RFC4035] Arends, R., Austein, R., Larson, M., Massey, D., and S. | |
Rose, "Protocol Modifications for the DNS Security | |
Extensions", RFC 4035, March 2005. | |
[RFC4509] Hardaker, W., "Use of SHA-256 in DNSSEC Delegation Signer | |
(DS) Resource Records (RRs)", RFC 4509, May 2006. | |
[RFC4635] Eastlake 3rd, D., "HMAC SHA (Hashed Message | |
Authentication Code, Secure Hash Algorithm) TSIG | |
Algorithm Identifiers", RFC 4635, August 2006. | |
Lewis & Hoenes Standards Track [Page 27] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
[RFC5155] Laurie, B., Sisson, G., Arends, R., and D. Blacka, "DNS | |
Security (DNSSEC) Hashed Authenticated Denial of | |
Existence", RFC 5155, March 2008. | |
[RFC5395] Eastlake 3rd, D., "Domain Name System (DNS) IANA | |
Considerations", BCP 42, RFC 5395, November 2008. | |
[RFC5702] Jansen, J., "Use of SHA-2 Algorithms with RSA in DNSKEY | |
and RRSIG Resource Records for DNSSEC", RFC 5702, October | |
2009. | |
12.2. Informative References | |
[DNSVALS] IANA Registry "Domain Name System (DNS) Parameters", | |
http://www.iana.org/. | |
[IANA-AF] IANA Registry "Address Family Numbers", | |
http://www.iana.org/. | |
[RFC2764] Gleeson, B., Lin, A., Heinanen, J., Armitage, G., and A. | |
Malis, "A Framework for IP Based Virtual Private | |
Networks", RFC 2764, February 2000. | |
[RFC3490] Faltstrom, P., Hoffman, P., and A. Costello, | |
"Internationalizing Domain Names in Applications (IDNA)", | |
RFC 3490, March 2003. | |
[RFC3833] Atkins, D. and R. Austein, "Threat Analysis of the Domain | |
Name System (DNS)", RFC 3833, August 2004. | |
[DNSSEC-U] Weiler, S. and D. Blacka, "Clarifications and | |
Implementation Notes for DNSSECbis", Work in Progress, | |
March 2010. | |
Lewis & Hoenes Standards Track [Page 28] | |
RFC 5936 DNS Zone Transfer Protocol (AXFR) June 2010 | |
Authors' Addresses | |
Edward Lewis | |
46000 Center Oak Plaza | |
Sterling, VA 20166 | |
US | |
EMail: [email protected] | |
Alfred Hoenes, Editor | |
TR-Sys | |
Gerlinger Str. 12 | |
Ditzingen D-71254 | |
Germany | |
EMail: [email protected] | |
Lewis & Hoenes Standards Track [Page 29] | |
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