The exhaustive documentation of IPv4 addresses usage in currently
deployed IETF documented standards has now been broken into seven
documents conforming to current IETF main areas, i.e., Applications,
Internet, Operations and Management, Routing, Sub-IP, and Transport.
A general overview of the documentation, as well as followed
methodology and historical perspective can be found in [1]. This
document represents one of the seven blocks, and its scope is limited
to surveying possible IPv4 dependencies in IETF Application Area
documented Standards.
The remainder sections are organized as follows. Sections 3, 4, 5,
and 6 describe, respectively, the raw analysis of Internet Standards
[2]:
Full, Draft, and Proposed Standards, and Experimental RFCs. For each
section, standards are analysed by their RFC number, in sequential
order, i.e., from RFC 1 to RFC 3200. Exceptions to this are some
RFCs above RFC 3200. They have been included, given that they
obsoleted RFCs within the range 1-3200. Also, the comments presented
for each RFC are raw in their nature, i.e., each RFC is simply
analysed in terms of possible IPv4 addressing dependencies. Finally,
Section 7 presents a global overview of the data described in the
previous sections, and suggests possible future steps.
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Internet Full Standards have attained the highest level of maturity
on the standards track process. They are commonly referred to as
"Standards", and represent fully technical mature specifications that
are widely implemented and used throughout the Internet.
There are no IPv4 dependencies in this specification.
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Section 4.1.2 (TRANSFER PARAMETER COMMANDS) describes the port
command using the following format:
"A port command would be:
PORT h1,h2,h3,h4,p1,p2
where h1 is the high order 8 bits of the internet host
address."
This is a clear reference to an IPv4 address. In sections 4.2.1 and
4.2.2, on reply codes, the code:
"227 Entering Passive Mode (h1,h2,h3,h4,p1,p2)"
also needs to be reworked for IPv6 addressing. Also, Section 5.3.2
(FTP COMMAND ARGUMENTS) contains:
"<host-number> ::= <number>,<number>,<number>,<number>
<port-number> ::= <number>,<number>
<number> ::= any decimal integer 1 through 255"
This needs to be solved to transition to IPv6.
There are no IPv4 dependencies in this specification.
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Draft Standards is the nomenclature given to specifications that are
on the penultimate maturity level of the IETF standards track
process. They are considered to be final specifications, which may
only experience changes to solve specific problems found. A
specification is only considered to be a Draft Standard if there are
at least two known independent and interoperable implementations.
Hence, Draft Standards are usually quite mature and widely used.
There are no IPv4 dependencies in this specification.
4.4. RFC 1305: Network Time Protocol (Version 3) Specification,
Implementation
Section 3.2.1 (Common Variables) provides the following variable
definitions:
"Peer Address (peer.peeraddr, pkt.peeraddr), Peer Port
(peer.peerport, pkt.peerport): These are the 32-bit Internet
address and 16-bit port number of the peer.
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Host Address (peer.hostaddr, pkt.hostaddr), Host Port
(peer.hostport, pkt.hostport): These are the 32-bit Internet
address and 16-bit port number of the host. They are included
among the state variables to support multi-homing."
Section 3.4.3 (Receive Procedure) defines the following procedure:
"The source and destination Internet addresses and ports in the IP
and UDP headers are matched to the correct peer. If there is no
match a new instantiation of the protocol machine is created and
the association mobilized."
Section 3.6 (Access Control Issues) proposes a simple authentication
scheme in the following way:
"If a more comprehensive trust model is required, the design can
be based on an access-control list with each entry consisting of a
32-bit Internet address, 32-bit mask and three-bit mode. If the
logical AND of the source address (pkt.peeraddr) and the mask in
an entry matches the corresponding address in the entry and the
mode (pkt.mode) matches the mode in the entry, the access is
allowed; otherwise an ICMP error message is returned to the
requestor. Through appropriate choice of mask, it is possible to
restrict requests by mode to individual addresses, a particular
subnet or net addresses, or have no restriction at all. The
access-control list would then serve as a filter controlling which
peers could create associations."
Appendix B Section 3 (B.3 Commands) defines the following command:
"Set Trap Address/Port (6): The command association identifier,
status and data fields are ignored. The address and port number
for subsequent trap messages are taken from the source address and
port of the control message itself. The initial trap counter for
trap response messages is taken from the sequence field of the
command. The response association identifier, status and data
fields are not significant. Implementations should include sanity
timeouts which prevent trap transmissions if the monitoring
program does not renew this information after a lengthy interval."
The address clearly assumes the IPv4 version. Also, there are
numerous places in sample code and in algorithms that use the above
mentioned variables. It seems that there is no reason to modify the
actual protocol. A small number of textual changes and an update to
implementations, so they can understand both IPv4 and IPv6 addresses,
will suffice to have a NTP version that works on both network layer
protocols.
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There are no IPv4 dependencies in this specification.
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Section "Blocksize Option Specification" gives the following example:
"For example:
+-------+--------+---+--------+---+--------+---+--------+---+
| 1 | foobar | 0 | octet | 0 | blksize| 0 | 1428 | 0 |
+-------+--------+---+--------+---+--------+---+--------+---+
is a Read Request, for the file named "foobar", in octet (binary)
transfer mode, with a block size of 1428 octets (Ethernet MTU,
less the TFTP, UDP and IP header lengths)."
Clearly, the given blocksize example would not work with IPv6 header
sizes, but it has no practical implications, since larger blocksizes
are also available.
4.15. RFC 2349: TFTP Timeout Interval and Transfer Size Options
There are no IPv4 dependencies in this specification.
Syntax
Section 3.2.2. (Server-based Naming Authority) states:
"The host is a domain name of a network host, or its IPv4 address
as a set of four decimal digit groups separated by ".". Literal
IPv6 addresses are not supported.
...
Note: A suitable representation for including a literal IPv6
address as the host part of a URL is desired, but has not yet been
determined or implemented in practice."
Section 3.2.2 (http URL) states:
"The "http" scheme is used to locate network resources via the
HTTP protocol. This section defines the scheme-specific syntax
and semantics for http URLs.
http_URL = "http:" "//" host [ ":" port ] [ abs_path [ "?" query ]]
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If the port is empty or not given, port 80 is assumed. The
semantics are that the identified resource is located at the
server listening for TCP connections on that port of that host,
and the Request-URI for the resource is abs_path (section 5.1.2).
The use of IP addresses in URLs SHOULD be avoided whenever
possible (see RFC 1900 [24])."
The text is version neutral, but it is unclear whether individual
implementations will support IPv6 addresses. In fact, the use of the
":"separator in IPv6 addresses will cause misinterpretation when
parsing URI's. There are other discussions regarding a server
recognizing its own IP addresses, spoofing DNS/IP address
combinations, as well as issues regarding multiple HTTP servers
running on a single IP interface. Again, the text is version
neutral, but clearly, such statements represent implementation
issues.
4.19. RFC 3191: Minimal GSTN address format in Internet Mail
There are no IPv4 dependencies in this specification.
4.20. RFC 3192: Minimal FAX address format in Internet Mail
There are no IPv4 dependencies in this specification.
There are no IPv4 dependencies in this specification.
4.25. RFC 3464: An Extensible Message Format for Delivery Status
Notifications
There are no IPv4 dependencies in this specification.
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Proposed Standards represent initial level documents in the IETF
standards track process. They are stable in terms of design, but do
not require the existence of implementations. In several cases,
these specifications are simply proposed as solid technical ideas, to
be analysed by the Internet community, but are never implemented or
advanced in the IETF standards process.
There are no IPv4 dependencies in this specification.
5.9. RFC 927: TACACS user identification Telnet option
There are no IPv4 dependencies in this specification.
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There are no IPv4 dependencies in this specification.
5.11. RFC 946: Telnet terminal location number option
Section "TTYLOC Number" states:
"The TTYLOC number is a 64-bit number composed of two (2) 32-bit
numbers: The 32-bit official ARPA Internet host address (may be
any one of the addresses for multi-homed hosts) and a 32-bit
number representing the terminal on the specified host. The host
address of [0.0.0.0] is defined to be "unknown", the terminal
number of FFFFFFFF (hex, r or-1 in decimal) is defined to be
"unknown" and the terminal number of FFFFFFFE (hex, or -2 in
decimal) is defined to be "detached" for processes that are not
attached to a terminal."
The clear reference to 32-bit numbers, and to the use of literal
addresses in the form [0.0.0.0] is clearly an IPv4-dependency. Thus,
the text above needs to be re-written.
There are no IPv4 dependencies in this specification.
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Since this document defines a gateway for interaction between FTAM
and FTP, the only possible IPv4 dependencies are associated with FTP,
which has already been investigated above, in section 3.16.
Message Bodies
There are no IPv4 dependencies in this specification.
5.27. RFC 1496: Rules for downgrading messages from X.400/88 to
X.400/84 when MIME content-types are present in the messages
There are no IPv4 dependencies in this specification.
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Section 3.1. (Common Internet Scheme Syntax) states:
"host
The fully qualified domain name of a network host, or its IP
address as a set of four decimal digit groups separated by ".".
Fully qualified domain names take the form as described in
Section 3.5 of RFC 1034 [13] and Section 2.1 of RFC 1123 [4]: a
sequence of domain labels separated by ".", each domain label
starting and ending with an alphanumerical character and
possibly also containing "-" characters. The rightmost domain
label will never start with a digit, though, which
syntactically distinguishes all domain names from the IP
addresses."
Clearly, this is only valid when using IPv4 addresses. Later in
Section 5. (BNF for specific URL schemes), there is the following
text:
"; URL schemeparts for ip based protocols:
ip-schemepart = "//" login [ "/" urlpath ]
login = [ user [ ":" password ] "@" ] hostport
hostport = host [ ":" port ]
host = hostname | hostnumber"
Again, this also has implications in terms of IP-version neutrality.
MacMIME
There are no IPv4 dependencies in this specification.
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There are no IPv4 dependencies in this specification.
5.36. RFC 1913: Architecture of the WHOIS++ Index Service
Section 6.5. (Query referral) makes the following statement:
"When referrals are included in the body of a response to a query,
each referral is listed in a separate SERVER-TO-ASK block as shown
below.
# SERVER-TO-ASK
Version-number: // version number of index software, used to insure
// compatibility
Body-of-Query: // the original query goes here
Server-Handle: // WHOIS++ handle of the referred server
Host-Name: // DNS name or IP address of the referred server
Port-Number: // Port number to which to connect, if different from the
// WHOIS++ port number"
The syntax used does not present specific IPv4 dependencies, but
implementations should be modified to check, in incoming packets,
which IP version was used by the original request, so they can
determine whether or not to return an IPv6 address.
Section 4 (Caching) states the following:
"A client can cache all information it gets from a server for some
time. For example records, IP-addresses of Whois++ servers, the
Directory of Services server etc.
A client can itself choose for how long it should cache the
information.
The IP-address of the Directory of Services server might not
change for a day or two, and neither might any other information."
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Also, subsection 4.1. (Caching a Whois++ servers hostname) contains:
"An example of cached information that might change is the cached
hostname, IP-address and portnumber which a client gets back in a
servers-to-ask response. That information is cached in the server
since the last poll, which might occurred several weeks ago.
Therefore, when such a connection fails, the client should fall
back to use the serverhandle instead, which means that it contacts
the Directory of Services server and queries for a server with
that serverhandle. By doing this, the client should always get
the last known hostname.
An algorithm for this might be:
response := servers-to-ask response from server A
IP-address := find ip-address for response.hostname in DNS
connect to ip-address at port response.portnumber
if connection fails {
connect to Directory of Services server
query for host with serverhandle response.serverhandle
response := response from Directory of Services server
IP-address := find ip-address for response.hostname in DNS
connect to ip-address at port response.portnumber
if connection fails {
exit with error message
}
}
Query this new server"
The paragraph does not contain IPv4 specific syntax. Hence, IPv6
compliance will be implementation dependent.
5.38. RFC 1985: SMTP Service Extension for Remote Message
Queue Starting
There are no IPv4 dependencies in this specification.
5.39. RFC 2017: Definition of the URL MIME External-Body
Access-Type
There are no IPv4 dependencies in this specification.
5.40. RFC 2034: SMTP Service Extension for Returning Enhanced
Error Codes
There are no IPv4 dependencies in this specification.
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Section 3 (Description of the VEMMI scheme) states:
"The VEMMI URL scheme is used to designate multimedia interactive
services conforming to the VEMMI standard (ITU/T T.107 and ETS 300
709).
A VEMMI URL takes the form:
vemmi://<host>:<port>/<vemmiservice>;
<attribute>=<value>
as specified in Section 3.1. of RFC 1738. If :<port> is omitted,
the port defaults to 575 (client software may choose to ignore the
optional port number in order to increase security). The
<vemmiservice> part is optional and may be omitted."
IPv4 dependencies may relate to the possibility of the <host> portion
containing an IPv4 address, as defined in RFC 1738 (see section 5.31.
above). Once the problem is solved in the context of RFC 1738, this
issue will be automatically solved.
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Section 7. (Service Type Request Message Format) and Section 9.
(Service Registration Message Format) have an 80-bit field from
addr-spec (see below) which cannot support IPv6 addresses. Also,
Section 20.1. (Previous Responders' Address Specification) states:
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"The previous responders' Address Specification is specified as
<Previous Responders' Address Specification> ::=
<addr-spec> |
<addr-spec>, <Previous Responders' Address Specification>
i.e., a list separated by commas with no intervening white space.
The Address Specification is the address of the Directory Agent or
Service Agent which supplied the previous response. The format
for Address Specifications in Service Location is defined in
section 20.4. The comma delimiter is required between each
<addr-spec>. The use of dotted decimal IP address notation should
only be used in environments which have no Domain Name Service."
Later, in Section 20.4. (Address Specification in Service Location)
there is also the following reference to addr-spec:
"The address specification used in Service Location is:
<addr-spec> ::= [<user>:<password>@]<host>[:<port>]
<host> ::= Fully qualified domain name |
dotted decimal IP address notation
When no Domain Name Server is available, SAs and DAs must use
dotted decimal conventions for IP addresses. Otherwise, it is
preferable to use a fully qualified domain name wherever possible
as renumbering of host addresses will make IP addresses invalid
over time."
The whole Section 21. (Protocol Requirements) defines the
requirements for each of the elements of this protocol. Several IPv4
statements are made, but the syntax used is sufficiently neutral to
apply to the use of IPv6.
Section 22. (Configurable Parameters and Default Values) states:
"There are several configuration parameters for Service Location.
Default values are chosen to allow protocol operation without the
need for selection of these configuration parameters, but other
values may be selected by the site administrator. The
configurable parameters will allow an implementation of Service
Location to be more useful in a variety of scenarios.
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Multicast vs. Broadcast
All Service Location entities must use multicast by default.
The ability to use broadcast messages must be configurable
for UAs and SAs. Broadcast messages are to be used in
environments where not all Service Location entities have
hardware or software which supports multicast.
Multicast Radius
Multicast requests should be sent to all subnets in a site.
The default multicast radius for a site is 32. This value
must be configurable. The value for the site's multicast
TTL may be obtained from DHCP using an option which is
currently unassigned."
Once again, nothing here precludes IPv6, Section 23.
(Non-configurable Parameters) states:
"IP Port number for unicast requests to Directory Agents:
UDP and TCP Port Number: 427
Multicast Addresses
Service Location General Multicast Address: 224.0.1.22
Directory Agent Discovery Multicast Address: 224.0.1.35
A range of 1024 contiguous multicast addresses for use as Service
Specific Discovery Multicast Addresses will be assigned by IANA."
Clearly, the statements above require specifications related to the
use of IPv6 multicast addresses with equivalent functionality.
The specification has IPv4 dependencies, as RFC 1738, which is
integral to the document, is not IPv6 aware.
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Section 6. (Formal Syntax) presents the following statement:
"referral_response_code = "[" "REFERRAL" 1*(SPACE <url>) "]"; See
[RFC-1738] for <url> definition"
The above presents dependencies on RFC 1738 URL definitions, which
have already been mentioned in this document, section 5.31.
5.62. RFC 2218: A Common Schema for the Internet White Pages
Service
There are no IPv4 dependencies in this specification.
Section 4.1. (LOGIN and AUTHENTICATE Referrals) provides the
following example:
"Example: C: A001 LOGIN MIKE PASSWORD
S: A001 NO [REFERRAL IMAP://MIKE@SERVER2/] Specified
user is invalid on this server. Try SERVER2."
Even though the syntax "user@SERVER2" is presented often, there are
no specifications related to the format of "SERVER2". Hence, it is
up to individual implementations to determine acceptable values for
the hostname. This may or not include explicit IPv6 addresses.
5.64. RFC 2227: Simple Hit-Metering and Usage-Limiting for
HTTP
There are no IPv4 dependencies in this specification.
There are no IPv4 dependencies in this specification.
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5.68. RFC 2247: Using Domains in LDAP/X.500 Distinguished
Names
There are no IPv4 dependencies in this specification.
UTF-8 String Representation of Distinguished Names
Section 7.1. (Disclosure) states:
"Distinguished Names typically consist of descriptive information
about the entries they name, which can be people, organizations,
devices or other real-world objects. This frequently includes
some of the following kinds of information:
- the common name of the object (i.e., a person's full name)
- an email or TCP/IP address
- its physical location (country, locality, city, street address)
- organizational attributes (such as department name or
affiliation)"
This section requires the caveat "Without putting any limitations on
the version of the IP address.", to avoid ambiguity in terms of IP
version.
5.72. RFC 2254: The String Representation of LDAP Search Filters
There are no IPv4 dependencies in this specification.
The specification has IPv4 dependencies, as RFC 1738, which is
integral to the document, is not IPv6 aware.
5.74. RFC 2256: A Summary of the X.500(96) User Schema for use
with LDAPv3
There are no IPv4 dependencies in this specification.
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5.75. RFC 2293: Representing Tables and Subtrees in the X.500
Directory
There are no IPv4 dependencies in this specification.
5.76. RFC 2294: Representing the O/R Address hierarchy in the
X.500 Directory Information Tree
There are no IPv4 dependencies in this specification.
5.77. RFC 2298: An Extensible Message Format for Message
Disposition Notifications
There are no IPv4 dependencies in this specification.
Appendix B, part 2.0.1 (Mandatory Common Part) states:
"Cache Key
This is a database lookup key that uniquely identifies a piece
of data which the originator of a CSA Record wishes to
synchronize with its peers for a given "Protocol ID/Server
Group ID" pair. This key will generally be a small opaque byte
string which SCSP will associate with a given piece of data in
a cache. Thus, for example, an originator might assign a
particular 4 byte string to the binding of an IP address with
that of an ATM address. Generally speaking, the originating
server of a CSA record is responsible for generating a Cache
Key for every element of data that the given server originates
and which the server wishes to synchronize with its peers in
the SG."
The statement above is simply meant as an example. Hence, any IPv4
possible dependency of this protocol is an implementation issue.
There are no IPv4 dependencies in this specification.
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There are no IPv4 dependencies in this specification.
5.84. RFC 2369: The Use of URLs as Meta-Syntax for Core Mail
List Commands and their Transport through Message Header Fields
There are no IPv4 dependencies in this specification.
5.85. RFC 2371: Transaction Internet Protocol Version 3.0
In section 7. (TIP Transaction Manager Identification and Connection
Establishment):
"The <hostport> component comprises:
<host>[:<port>]
where <host> is either a <dns name> or an <ip address>; and <port>
is a decimal number specifying the port at which the transaction
manager (or proxy) is listening for requests to establish TIP
connections. If the port number is omitted, the standard TIP port
number (3372) is used.
A <dns name> is a standard name, acceptable to the domain name
service. It must be sufficiently qualified to be useful to the
receiver of the command.
An <ip address> is an IP address, in the usual form: four decimal
numbers separated by period characters."
This section has to be re-written to become IP-version neutral.
Besides adding a reference to the use of IPv6 addresses, the "host"
field should only be defined as a "dns name". However, if the use of
literal IP addresses is to be included, the format specified in RFC
2372 has to be followed.
Later in section 8. (TIP Uniform Resource Locators):
"A TIP URL takes the form:
tip://<transaction manager address>?<transaction string>
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where <transaction manager address> identifies the TIP transaction
manager (as defined in Section 7 above); and <transaction string>
specifies a transaction identifier, which may take one of two
forms (standard or non-standard):
i. "urn:" <NID> ":" <NSS>
A standard transaction identifier, conforming to the proposed
Internet Standard for Uniform Resource Names (URNs), as
specified by RFC2141; where <NID> is the Namespace Identifier,
and <NSS> is the Namespace Specific String. The Namespace ID
determines the syntactic interpretation of the Namespace
Specific String. The Namespace Specific String is a sequence
of characters representing a transaction identifier (as defined
by <NID>). The rules for the contents of these fields are
specified by [6] (valid characters, encoding, etc.).
This format of <transaction string> may be used to express
global transaction identifiers in terms of standard
representations. Examples for <NID> might be <iso> or <xopen>.
e.g.,
tip://123.123.123.123/?urn:xopen:xid
Note that Namespace Ids require registration. See [7] for
details on how to do this."
There are other references in section 8, regarding the use of literal
IP addresses. Therefore, this section also needs to be re-written,
and special care should be taken to avoid the use of IP (either IPv4
or IPv6) literal addresses. However, if such use is exemplified, the
format specified in RFC 2732 has to be respected.
Section 3. (POP Scheme) states:
"A POP URL is of the general form:
pop://<user>;auth=<auth>@<host>:<port>
Where <user>, <host>, and <port> are as defined in RFC 1738, and
some or all of the elements, except "pop://" and <host>, may be
omitted."
RFC 1738 (please refer to section 5.31) has a potential IPv4
limitation. Hence, RFC 2384 will only be IPv6 compliant when RFC
1738 becomes properly updated.
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There are no IPv4 dependencies in this specification.
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This RFC documents an IPv6 extension and hence, it is not considered
in the context of the current discussion.
5.99. RFC 2445: Internet Calendaring and Scheduling Core Object
Specification (iCalendar)
Section 4.8.4.7 (Unique Identifier) states:
"Property Name: UID
Purpose: This property defines the persistent, globally unique
identifier for the calendar component.
Value Type: TEXT
Property Parameters: Non-standard property parameters can be
specified on this property.
Conformance: The property MUST be specified in the "VEVENT",
"VTODO", "VJOURNAL" or "VFREEBUSY" calendar components.
Description: The UID itself MUST be a globally unique identifier.
The generator of the identifier MUST guarantee that the identifier
is unique. There are several algorithms that can be used to
accomplish this. The identifier is RECOMMENDED to be the
identical syntax to the [RFC 822] addr-spec. A good method to
assure uniqueness is to put the domain name or a domain literal IP
address of the host on which the identifier was created on the
right hand side of the "@", and on the left hand side, put a
combination of the current calendar date and time of day (i.e.,
formatted in as a DATE-TIME value) along with some other currently
unique (perhaps sequential) identifier available on the system
(for example, a process id number). Using a date/time value on
the left hand side and a domain name or domain literal on the
right hand side makes it possible to guarantee uniqueness since no
two hosts should be using the same domain name or IP address at
the same time. Though other algorithms will work, it is
RECOMMENDED that the right hand side contain some domain
identifier (either of the host itself or otherwise) such that the
generator of the message identifier can guarantee the uniqueness
of the left hand side within the scope of that domain."
Although the above does not explicitly state the use of IPv4
addresses, it addresses the explicit use of RFC 822 (obsoleted by RFC
2822). To become IPv6 compliant it should follow the guidelines for
RFC 2822 (see section 5.129).
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There are no IPv4 dependencies in this specification.
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Section 8.1. (Service Request) contains the following:
"
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Service Location header (function = SrvRqst = 1) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| length of <PRList> | <PRList> String \
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| length of <service-type> | <service-type> String \
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| length of <scope-list> | <scope-list> String \
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| length of predicate string | Service Request <predicate> \
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| length of <SLP SPI> string | <SLP SPI> String \
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
...
<PRList> is the Previous Responder List. This <string-list>
contains dotted decimal notation IP (v4) addresses, and is
iteratively multicast to obtain all possible results (see Section
6.3). UAs SHOULD implement this discovery algorithm. SAs MUST
use this to discover all available DAs in their scope, if they are
not already configured with DA addresses by some other means."
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And later:
"A SA silently drops all requests which include the SA's address
in the <PRList>. An SA which has multiple network interfaces MUST
check if any of the entries in the <PRList> equal any of its
interfaces. An entry in the PRList which does not conform to an
IPv4 dotted decimal address is ignored: The rest of the <PRList>
is processed normally and an error is not returned."
To become IPv6 compliant, this protocol requires a new version.
Section 2.1. (Service URL Syntax) defines:
"The ABNF for a service: URL is:
hostnumber = ipv4-number
ipv4-number = 1*3DIGIT 3("." 1*3DIGIT)"
This document presents many other references to hostnumber, which
requires an update to support IPv6.
5.117. RFC 2640: Internationalization of the File Transfer Protocol
There are no IPv4 dependencies in this specification.
Indexing Protocol
There are no IPv4 dependencies in this specification.
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The specification discusses A records at length, and the MX record
handling with the different combinations of A and AAAA records and
IPv4/IPv6-only nodes might cause several kinds of failure modes.
Section 3.4.1 (Addr-spec specification) contains:
"The domain portion identifies the point to which the mail is
delivered. In the dot-atom form, this is interpreted as an
Internet domain name (either a host name or a mail exchanger name)
as described in [STD3, STD13, STD14]. In the domain-literal form,
the domain is interpreted as the literal Internet address of the
particular host. In both cases, how addressing is used and how
messages are transported to a particular host is covered in the
mail transport document [RFC2821]. These mechanisms are outside
of the scope of this document.
The local-part portion is a domain dependent string. In
addresses, it is simply interpreted on the particular host as a
name of a particular mailbox."
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Literal IP addresses should be avoided. However, in case they are
used, there should be a reference to the format described in RFC
2732.
Expressions
There are no IPv4 dependencies in this specification.
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5.138. RFC 2919: List-Id: A Structured Field and Namespace for
the Identification of Mailing Lists
There are no IPv4 dependencies in this specification.
This document includes several references to host IP addresses, but
there is no explicit mention to a particular protocol version. A
caveat similar to "Without putting any limitations on the version of
the IP address." should be added, so that there will remain no doubts
about possible IPv4 dependencies.
Section 6.2.1. (DNS Server Address) states:
"The dnsServerAddress element represents the IP address of the
Domain Name Service (DNS) server which should be used when
connected to this POP.
The address is represented in the form of a string in dotted-
decimal notation (e.g., 192.168.101.1).
Syntax:
<!-- Domain Name Server IP address -->
<!ELEMENT dnsServerAddress (#PCDATA)>
<!ATTLIST dnsServerAddress
value NOTATION (IPADR) #IMPLIED>"
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Additionally, it is stated in Section 6.2.9. (Default Gateway
Address):
"The defaulttGatewayAddress element represents the address of the
default gateway which should be used when connected to this POP.
The address is represented in the form of a string in dotted-
decimal notation (e.g., 192.168.101.1).
Syntax:
<!-- Default Gateway IP address (in dotted decimal notation) -->
<!ELEMENT defaultGatewayAddress (#PCDATA)>
<!ATTLIST defaultGatewayAddress
value NOTATION (IPADR) #IMPLIED>"
It should be straightforward to implement elements that are IPv6
aware.
There are no IPv4 dependencies in this specification.
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5.152. RFC 3111: Service Location Protocol Modifications for IPv6
This is an IPv6 related document and is not discussed in this
document.
5.153. RFC 3302: Tag Image File Format (TIFF) - image/tiff MIME
Sub-type Registration
There are no IPv4 dependencies in this specification.
Part Four: The Uniform Resource Identifiers (URI)
Resolution Application
This specification has no explicit dependency on IPv4. However, when
referring to the URI format specified in RFC 2396 (see section 4.3.
flags, first paragraph), a reference to RFC 2732 should be also
added.
5.155. RFC 3501: Internet Message Access Protocol - Version 4rev1
There are no IPv4 dependencies in this specification.
Experimental RFCs belong to the category of "non-standard"
specifications. This group involves specifications considered "off-
track", e.g., specifications that haven't yet reach an adequate
standardization level, or that have been superseded by more recent
specifications.
Experimental RFCs represent specifications that are currently part of
some research effort, and that are often propriety in nature, or used
in limited arenas. They are documented to the Internet community in
order to allow potential interoperability or some other potential
useful scenario. In a few cases, they are presented as alternatives
to the mainstream solution of an acknowledged problem.
Section 3.1 (Request Messages) contains:
"<Who-Anywhere-Provides?>
This message parallels the <Who-Provides?> message with the
"third-party" variant described above. The confirming host is
required to return at least its own IP address (if it provides the
named resource) as well as the IP addresses of any other hosts it
believes may provide the named resource. The confirming host
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though, may never return an IP address for a resource which is the
same as an IP address listed with the resource name in the request
message. In this case it must treat the resource as if it was
unsupported at that IP address and omit it from any reply list.
<Does-Anyone-Provide?>
This message parallels the <Do-You-Provide?> message again with
the "third-party" variant described above. As before, the
confirming host is required to return its own IP address as well
as the IP addresses of any other hosts it believes may provide the
named resource and is prohibited from returning the same IP
address in the reply resource specifier as was listed in the
request resource specifier. As in the <Do-You-Provide?> case and
for the same reason, this message also may not be broadcast."
Throughout this section, there are several other references to IP
address. To avoid ambiguity, a reference to IPv6 addressing should
be added.
Section 4.1. (Resource Lists) presents the following qualifier
format:
"In addition, resource specifiers in all <Who-Anywhere-Provides?>,
<Does-Anyone-Provide?> and <They-Provide> messages also contain an
additional qualifier following the <Protocol-ID>. This qualifier
has the format
+--------+--------+--------+--------+---//---+
| | |
|IPLength| IP-Address-List |
| | |
+--------+--------+--------+--------+---//---+
where
<IPLength>
is the number of IP addresses containing in the following <IP-
Address-List> (the <IP-Address-List> field thus occupies the
last 4*<IPLength> octets in its resource specifier). In
request messages, this is the maximum number of qualifying
addresses which may be included in the corresponding reply
resource specifier. Although not particularly useful, it may
be 0 and in that case provides no space for qualifying the
resource name with IP addresses in the returned specifier. In
reply messages, this is the number of qualifying addresses
known to provide the resource. It may not exceed the number
specified in the corresponding request specifier. This field
may not be 0 in a reply message unless it was supplied as 0 in
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the request message and the confirming host would have returned
one or more IP addresses had any space been provided.
<IP-Address-List>
is a list of four-octet IP addresses used to qualify the
resource specifier with respect to those particular addresses.
In reply messages, these are the IP addresses of the confirming
host (when appropriate) and the addresses of any other hosts
known to provide that resource (subject to the list length
limitations). In request messages, these are the IP addresses
of hosts for which resource information may not be returned.
In such messages, these addresses should normally be
initialized to some "harmless" value (such as the address of
the querying host) unless it is intended to specifically
exclude the supplied addresses from consideration in any reply
messages."
This section requires re-writing considering the 128-bit length of
IPv6 addresses, and will clearly impact implementations.
There are no IPv4 dependencies in this specification.
6.5. RFC 1165: Network Time Protocol (NTP) over the OSI Remote
Operations Service
The only dependency this protocol presents is included in Appendix A
(ROS Header Format):
"ClockIdentifier ::= CHOICE {
referenceClock[0] PrintableString,
inetaddr[1] OCTET STRING,
psapaddr[2] OCTET STRING
}"
6.6. RFC 1176: Interactive Mail Access Protocol: Version 2
There are no IPv4 dependencies in this specification.
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Section "Protocol Specification" provides the following example, for
the Initial Handshake:
"The ticket server replies with a "This is Your Ticket" (TIYT)
packet containing the ticket. Figure 2 shows the format of this
packet.
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 'T' | 'I' | 'Y' | 'T' |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| "ticket" |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| BLKSZ (by default 512) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| FILSZ |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| IP address of CFDP server (network order) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| client UDP port# (cfdpcln) | server UDP port# (cfdpsrv) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Fig. 2: "This Is Your Ticket" packet."
This protocol assumes IPv4 multicast, but could be converted to IPv6
multicast with a little effort.
This protocol specifies a protocol that assumes IPv4, but does not
actually have any limitations which would limit its operation in an
IPv6 environment.
There are no IPv4 dependencies in this specification.
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There are only two specific IPv4 addressing references. The first is
presented in Section 6.2. (Command Response):
"203 RPL_TRACEUNKNOWN
"???? <class> [<client IP address in dot form>]""
The second appears in Section 8.12 (Configuration File):
"In specifying hostnames, both domain names and use of the 'dot'
notation (127.0.0.1) should both be accepted."
After correcting the above, IPv6 support can be added
straightforwardly.
6.14. RFC 1465: Routing Coordination for X.400 MHS Services
Within a Multi Protocol / Multi Network Environment Table
Format V3 for Static Routing
There are no IPv4 dependencies in this specification.
6.15. RFC 1505: Encoding Header Field for Internet Messages
There are no IPv4 dependencies in this specification.
6.16. RFC 1528: Principles of Operation for the TPC.INT Subdomain:
Remote Printing -- Technical Procedures
There are no IPv4 dependencies in this specification.
6.17. RFC 1608: Representing IP Information in the X.500
Directory
There are no IPv4 dependencies in this specification.
6.18. RFC 1609: Charting Networks in the X.500 Directory
There are no IPv4 dependencies in this specification.
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There are no IPv4 dependencies in this specification.
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6.29. RFC 1986: Experiments with a Simple File Transfer Protocol
for Radio Links using Enhanced Trivial File Transfer Protocol
This protocol is IPv4 dependent, as can be seen from the segment
presented below, taken from Section 2. (PROTOCOL DESCRIPTION):
"Table 3: ETFTP Data Encapsulation
+------------+------------+------------+------------+-----------+
|Ethernet(14)| | |ETFTP/ | |
|SLIP(2) |IP(20) |UDP(8) |NETBLT(24) |DATA(1448) |
|AX.25(20) | | | | |
+------------+------------+------------+------------+-----------+"
There are no IPv4 dependencies in this specification.
6.36. RFC 2162: MaXIM-11 - Mapping between X.400 / Internet
mail and Mail-11 mail
There are no IPv4 dependencies in this specification.
6.37. RFC 2169: A Trivial Convention for using HTTP in URN
Resolution
There are no IPv4 dependencies in this specification.
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Information Service
This protocol assumes IPv4 addressing in its schema, as shown in
Section 3. (Attribute definitions):
"( nisSchema.1.19 NAME 'ipHostNumber'
DESC 'IP address as a dotted decimal, eg. 192.168.1.1,
omitting leading zeros'
EQUALITY caseIgnoreIA5Match
SYNTAX 'IA5String{128}' )
( nisSchema.1.20 NAME 'ipNetworkNumber'
DESC 'IP network as a dotted decimal, eg. 192.168,
omitting leading zeros'
EQUALITY caseIgnoreIA5Match
SYNTAX 'IA5String{128}' SINGLE-VALUE )
( nisSchema.1.21 NAME 'ipNetmaskNumber'
DESC 'IP netmask as a dotted decimal, eg. 255.255.255.0,
omitting leading zeros'
EQUALITY caseIgnoreIA5Match
SYNTAX 'IA5String{128}' SINGLE-VALUE )"
The document does try to provide some IPv6 support as in Section 5.4.
(Interpreting Hosts and Networks):
"Hosts with IPv6 addresses MUST be written in their "preferred" form
as defined in section 2.2.1 of [RFC1884], such that all components of
the address are indicated and leading zeros are omitted. This
provides a consistent means of resolving ipHosts by address."
However, the defined format mentioned above has been replaced, hence
it is no longer valid.
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There are no IPv4 dependencies in this specification.
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This specification claims to be both IPv4 and IPv6 aware, but in
Section 2.8. (An HTCP/0.0 AUTH has the following structure), it makes
the following statement:
"SIGNATURE is a COUNTSTR [3.1] which holds the HMAC-MD5 digest
(see [RFC 2104]), with a B value of 64, of the
following elements, each of which is digested in its
"on the wire" format, including transmitted padding
if any is covered by a field's associated LENGTH:
IP SRC ADDR [4 octets]
IP SRC PORT [2 octets]
IP DST ADDR [4 octets]
IP DST PORT [2 octets]
HTCP MAJOR version number [1 octet]
HTCP MINOR version number [1 octet]
SIG-TIME [4 octets]
SIG-EXPIRE [4 octets]
HTCP DATA [variable]
KEY-NAME (the whole COUNTSTR [3.1]) [variable]"
The given SIGNATURE calculation should be expanded to support IPv6 16
byte addresses.
This protocol is both IPv4 and IPv6 aware and needs no changes.
6.55. RFC 3018: Unified Memory Space Protocol Specification
In section 3.4 (Address Formats), there are explicit references to
IPv4 addressing:
"The following address format numbers are definite for nodes,
immediately connected to the global IPv4 network:
N 4-0-0 (4)
N 4-0-1 (4-1)
N 4-0-2 (4-2)
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The appropriate formats of 128-bit addresses:
Octets:
+0 +1 +2 +3
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
0: |0 1 0 0|0 0|0 0| Free |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
4: | Free |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
8: | Free | IP address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
12:| IP address | Local memory address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
0: |0 1 0 0|0 0|0 1| Free |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
4: | Free |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
8: | Free | IP address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
12:| IP address | Local memory address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
0: |0 1 0 0|0 0|1 0| Free |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
4: | Free |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
8: | IP address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
12:| Local memory address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Free
It is not used by the protocol.
IP address
It sets the node address in the global IPv4 network."
This section needs to be re-written, so that the specification
becomes IPv6 compliant.
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This protocol is both IPv4 and IPv6 aware, and thus requires no
changes.
6.57. RFC 3088: OpenLDAP Root Service An experimental LDAP
referral service
Section 5. (Using the Service) states:
"The service supports LDAPv3 and LDAPv2+ [LDAPv2+] clients over
TCP/IPv4. Future incarnations of this service may support
TCP/IPv6 or other transport/internet protocols."
This survey contemplates 257 RFCs, having 34 (12.84%) been identified
as having some form of IPv4 dependency. Results are broken down as
follows:
Standards: 1 out of 20 or 5.00%
Draft Standards: 4 out of 25 or 16.00%
Proposed Standards: 19 out of 155 or 12.26%
Experimental RFCs: 10 out of 57 or 17.54%
Of the 33 identified, the majority simply require minor actions, such
as adding a caveat to IPv6 addressing that would avoid ambiguity, or
re-writing a section to avoid IP-version dependent syntax. The
remaining instances are documented below. The authors have attempted
to organize the results in a format that allows easy referencing by
other protocol designers.
7.2.1. RFC 1305: Network Time Protocol (version 3): Specification,
Implementation and Analysis
As documented in Section 4.4. above, there are too many specific
references to the use of 32-bit IPv4 addresses. An updated
specification to support NTP over IPv6 is needed. However, there has
been some work related with this issue, as an already expired
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work in progress, allegedly documents. Also, there is at least one
IPv6 NTP implementation.
URI's allow the literal use of IPv4 addresses but have no specific
recommendations on how to represent literal IPv6 addresses. This
problem has already been addressed in [3].
HTTP allows the literal use of IPv4 addresses, but has no specific
recommendations on how to represent literal IPv6 addresses. This
problem has already been addressed in [3].
There is a dependency in the definition of the TTYLOC Number which
would require an updated version of the protocol. However, since
this functionality is of marginal value today, an updated version
might not make sense.
URL's with IPv4 dependencies have already been addressed in [3].
Note that these dependencies affect other specifications as well,
such as RFC 2122, RFC 2192, RFC 2193, RFC 2255, RFC 2371, and RFC
2384. All of these protocols have to revisited, and are not
described separately in this memo.
The problems of this specification have already been addressed in
[4].
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Some textual updates and clarifications to MX processing would likely
be useful. The operational scenarios and guidelines to avoid the
problems have been described in [6].
The packet format of this protocol depends on IPv4, and would require
updating to add IPv6 support. However, the protocol is not believed
to be in use, so such an update may not be warranted.
This document tries to provide IPv6 support but it relies on an
outdated format for IPv6 addresses. Thus, there is the need for an
IPv6 compliant version.
Phil would like to acknowledge the support of the Internet Society in
the research and production of this document. Additionally, Phil
would like to thank his partner in all ways, Wendy M. Nesser.
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This document provides an exhaustive documentation of current IETF
documented standards IPv4 address dependencies. Such process does
not have security implications in itself.
[1] Nesser, II, P. and A. Bergstrom, Editor, "Introduction to the
Survey of IPv4 Addresses in Currently Deployed IETF Standards",
RFC 3789, June 2004.
[2] Bradner, S., "The Internet Standards Process - version 3", BCP 9,
RFC 2026, October 1996.
[3] Hinden, R., Carpenter, B. and L. Masinter, "Format for Literal
IPv6 Addresses in URL's", RFC 2732, December 1999.
[4] Guttman, E., "Service Location Protocol Modifications for IPv6",
RFC 3111, May 2001.
[5] Allman, M., Ostermann, S. and C. Metz, "FTP Extensions for IPv6
and NATs", RFC 2428, September 1998.
[6] Hagino, J. and M. Nakamura, "SMTP operational experience in mixed
IPv4/IPv6 environements", Work in Progress.
Sofia & Nesser II Informational [Page 48]
RFC 3895 IPv4 Addresses in the IETF Application Area June 2004
Rute Sofia
FCCN
Av. Brasil, 101
1700 Lisboa, Portugal
Phone: +351 91 2507372
EMail: rsofia@zmail.pt
Philip J. Nesser II
Principal
Nesser & Nesser Consulting
13501 100th Ave NE, #5202
Kirkland, WA 98034
Phone: +1 425 481 4303
Fax: +1 425 482 9721
EMail: phil@nesser.com
Sofia & Nesser II Informational [Page 49]
RFC 3895 IPv4 Addresses in the IETF Application Area June 2004
Copyright (C) The Internet Society (2004). This document is subject
to the rights, licenses and restrictions contained in BCP 78, and
except as set forth therein, the authors retain all their rights.
This document and the information contained herein are provided on an
"AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS
OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE INTERNET
ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED,
INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE
INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
Intellectual Property
The IETF takes no position regarding the validity or scope of any
Intellectual Property Rights or other rights that might be claimed to
pertain to the implementation or use of the technology described in
this document or the extent to which any license under such rights
might or might not be available; nor does it represent that it has
made any independent effort to identify any such rights. Information
on the procedures with respect to rights in RFC documents can be
found in BCP 78 and BCP 79.
Copies of IPR disclosures made to the IETF Secretariat and any
assurances of licenses to be made available, or the result of an
attempt made to obtain a general license or permission for the use of
such proprietary rights by implementers or users of this
specification can be obtained from the IETF on-line IPR repository at
http://www.ietf.org/ipr.
The IETF invites any interested party to bring to its attention any
copyrights, patents or patent applications, or other proprietary
rights that may cover technology that may be required to implement
this standard. Please address the information to the IETF at ietf-
ipr@ietf.org.
Acknowledgement
Funding for the RFC Editor function is currently provided by the
Internet Society.
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