Host Identity Protocol Distributed Hash Table Interface
The Boeing CompanyP.O. Box 3707SeattleWAUSAjeffrey.m.ahrenholz@boeing.com
IRTF
HIP Research GroupI-DInternet DraftThis document specifies a common interface for using the Host Identity
Protocol (HIP) with a Distributed Hash Table service to provide a
name-to-Host-Identity-Tag
lookup service and a Host-Identity-Tag-to-address lookup service.
The Host Identity Protocol (HIP)
may benefit from a lookup service based
on Distributed Hash Tables (DHTs). The Host Identity namespace is flat,
consisting of public keys, in contrast to the hierarchical Domain Name
System. These keys are hashed and prefixed to form Host Identity Tags
(HITs), which
appear as large random numbers. As the current DNS system has been
heavily optimized for address lookup, it may be worthwhile to
experiment with other services such as those defined here.
DHTs manage such data well by
applying a hash function that distributes data across a number
of servers. DHTs are also designed to be updated more frequently than
a DNS-based approach.
For an alternative method of using HITs to lookup IP addresses
using DNS, see .
One freely available implementation of a DHT is the Bamboo DHT, which
is Java-based software that has been deployed on PlanetLab
servers to form a free service named OpenDHT.
OpenDHT was available via the Internet for any program
to store and retrieve arbitrary data.
OpenDHT used a well defined XML-RPC
interface, featuring put, get, and remove operations.
OpenLookup, while not implemented as a DHT, is another deployment
of open source software compatible with
this OpenDHT interface. This document discusses
a common way for HIP to use this OpenDHT interface, so that various
HIP experimenters may employ lookup services in an interoperable
fashion.
This document is a product of the HIP research group of the IRTF.
The HIP research group reached consensus that this interface
specification should be published as an experimental RFC, based on
document review by at least six RG members including the chairs,
and based on implementation experience. This document
is not an IETF product and is not a standard.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
RFC 2119.OpenDHT was a public deployment
of Bamboo DHT servers that ran on
about 150 PlanetLab nodes, retired in July 2009.
While the Bamboo project provided the actual
software running on the servers, here we will refer only to OpenDHT,
which uses a certain defined interface for the XML-RPC calls.
Another service compatible with this interface is OpenLookup.
One can run their own Bamboo nodes to set up a private ring of servers.
OpenDHT was chosen because it was a well-known, publicly available
DHT used within the research community. Its interface features a simple,
standards-based protocol that can be easily implemented by HIP
developers. This document does not aim to dictate that only the services
and servers described here should be used, but is rather meant to act
as a starting point to gain experience with these services, choosing
tools that are readily available.
OpenDHT stores values and indexes those values by using (hash) keys.
Keys are limited to 20
bytes in length, and values can be up to 1024 bytes. Values are stored
for a certain number of seconds, up to a maximum of 604,800 seconds
(one week.) See the OpenDHT website:
Three RPC operations are supported: put, get, and rm (remove).
Put is called with key
and value parameters, causing the value to be stored using the key as
its hash index. Get is called with the key parameter, when you have a key
and want to retrieve the value. Rm is called with a hash of the value
to be removed along with a secret value, a hash of which was included
in the put operation.
The definitions below are taken from the OpenDHT users guide at
.
The put operation takes the following arguments:fieldtypeapplicationstringclient_librarystringkeybyte array, 20 bytes max.valuebyte array, 1024 bytes max.ttl_secfour-byte integer, max. value 604800secret_hashoptional SHA-1 hash of secret valueThe server replies with an integer -- 0 for "success", 1 if
it is "over capacity", and 2 indicating "try again". The return code 3
indicates "failure" and is used for a modified OpenDHT server that
performs signature and HIT verification, see
.
The get operation takes the following arguments:fieldtypeapplicationstringclient_librarystringkeybyte array, 20 bytes max.maxvalsfour-byte singed integer, max. value 2^31-1placemarkbyte array, 100 bytes max.The server replies with an array of values, and a placemark
that can be used for fetching additional values.
The rm operation takes the following arguments:fieldtypeapplicationstringclient_librarystringkeybyte array, 20 bytes max.value_hashSHA-1 hash of value to removettl_secfour-byte integer, max. value 604800secretsecret value (SHA-1 of this was used in put)The server replies with an integer -- 0 for "success", 1 if
it is "over capacity", and 2 indicating "try again".
This is the basic XML-RPC interface provided by OpenDHT. Each "field"
from the above tables are XML tags that enclose their corresponding
values. The key is a byte array used to index the record for storage and
retrieval from the DHT. The value is a byte array of the data
being stored in the DHT.
The Application and client_library fields are meta-data used only for
logging purposes. The ttl_sec field specifies the number of seconds that
the DHT should store the value. The secret_hash field allows values to
be later removed from the DHT. The maxvals and placemark fields are for
retrieving a maximum number of values and for iterating get results.
The return code of 0 "success" indicates a successful put or remove
operation. The return code of 1 "over capacity" means that a client is
using too much storage space on the server. The return value of 2
"try again" indicates that the client should retry the put operation
because a temporary problem prevented the server from
accepting the put.
In the sections that follow, specific uses for these DHT operations and
their XML fields are suggested for use with HIP.
The two lookup services described in this document use a
HIP DHT Resource Record (HDRR) defined in this section.
This record is
a wrapper around data contained in TLVs, similar to a HIP control packet.
The data contained in each HDRR differs between the two services.
The HDRR uses the same binary format as
HIP packets (defined in .)
This packet encoding is used as a convenience, even though this data
is actually a resource record stored and retrieved by the DHT servers,
not a packet sent on the wire by a HIP protocol daemon.
Note that this HDRR format is different than the HIP RR used by the
Domain Name System as defined in .
The reason it is different is that it is a different record from a
functional point of view: in DNS, the query key is a FQDN, and the
return value is a HIT, while here, the query key is a HIT.
HIP header values for the HDRR:
The Initiator HIT (Sender's HIT, SRC HIT) MUST be set to the HIT that
the host wishes to make
available using the lookup service. With the HIT lookup service,
this is the main piece of information returned by a get operation.
For the address lookup service, this HIT MUST be the same one used to
derive the HIT_KEY used as the DHT key.
The Responder HIT (Receiver's HIT, DST HIT) MUST be NULL
(all zeroes) since the data is intended for any host.
The only other TLV used with the HIT lookup service is an optional
CERT parameter containing a certificate for validating the name
that is used as the DHT key.
The CERT parameter is defined in .
The DHT server SHOULD use the certificate
to verify that the client is authorized to use the name used for the
DHT key, using the hash of the name found in the certificate.
The Common Name (CN)
field from the distinguished name (DN) of the X.509.v3 certificate
MUST be used. Which
certificates the server considers trusted is a policy issue.
The remaining parameters described here are used with the address
lookup service.
The LOCATOR parameter contains the addresses that the host wishes to
make available using the lookup service. A host MAY publish its
current preferred IPv4 and IPv6 locators, for example.
The SEQ parameter contains an unsigned 32-bit sequence number, the
Update ID. This
is typically initialized to zero and incremented by one for each new
HDRR that is published by the host. The host SHOULD retain the last
Update ID value it used for each HIT across reboots, or perform a
self lookup in the DHT. The Update ID value may be retained in the
DHT records and will determine the preferred address used by peers.
The HOST_ID parameter contains the Host Identity that corresponds with
the Sender's HIT. (The encoding of this parameter is defined in
section 5.2.8 of .)
The HOST_ID parameter and HIP_SIGNATURE parameter MUST be used with
the HDRR so that HIP clients receiving the record can
validate the sender and the included LOCATOR parameter. The HIT_KEY
used for the DHT key will also be verified against the Host Identity.
The client that receives the HDRR from the DHT response
MUST perform the signature and HIT_KEY
verification. If the signature is invalid for the given Host Identity
or the HIT_KEY used to retrieve the record does not match
the Host Identity, the DHT record
retrieved MUST be ignored. Note that for client-only verification
the DHT server does not need to be modified
The Sender's HIT in the HDRR MUST correspond with the key used
for the lookup and Host Identity verification. The Receiver's HIT MUST
be NULL (all zeroes) in the HDRR header.
When several HDRR records are returned by the server, the client
SHOULD pick the most recent record as indicated by the Update ID in the
SEQ TLV of the HDRR, and perform verification on that record. The order
in which records are returned should not be considered.
The DHT server MAY also verify the SIGNATURE and HOST_ID, with
some modifications to the Bamboo DHT software and a new return code
with the OpenDHT interface.
The signature in the put MUST be verified using the given
Host Identity (public key), and the HIT_KEY provided as the lookup key
MUST match this Host Identity according to the ORCHID generation
method defined by .
If either signature or HIT verification fails, the put MUST not be
recorded into the DHT, and the server returns a failure code.
The failure code is an additional return code not defined by OpenDHT,
with a value of 3.
This server-side verification of records could introduce a source of a
denial of service attack. The server policy could require clients to have
an active HIP association. See for
further discussion.
This draft defines a HIT lookup and address lookup service for use
with HIP. The HIT lookup uses a text name to discover a peer's HIT.
The address lookup uses a peer's HIT to discover its current addresses.
The two lookups are defined below. The abbreviated notation
refers to the HIP parameter types; for example HIP_SIG is the HIP
signature parameter defined by .
The HIT lookup service returns the Host Identity Tag of a peer given
a name.
The name SHOULD be the FQDN, hostname, or some other alias.
This HIT is found in the Sender's HIT field of the HDRR.
The HIT is
the hash of the public-key based Host Identity as described in
.
There are no security properties of the name, unlike the HIT.
An optional certificate MAY be included in the record, for validating
the name, providing some measure of security.
Which certificates to consider trusted is a policy issue.
This service is intended for use when legacy DNS servers
do not support HIP resource records, or when hosts do not have
administrative access to publish their own DNS records. Such an unmanaged
naming service may help facilitate experimentation.
The address lookup returns a locator and other validation data
in the HDRR for a given HIT. Before a HIP association can
be initiated (not in opportunistic mode), a HIP host needs to know
the peer's HIT and the current address at
which the peer is reachable. Often the HIT will be pre-configured,
available via DNS lookup using a hostname lookup
, or retrieved using the HIT lookup service
defined in this document.
With HIP mobility , IP addresses may
be used as locators and may often change. The Host
Identity and the HIT remain relatively constant and can be used to
securely identify a host, so the HIT serves as a suitable DHT key for
storing and retrieving addresses.
The address lookup service includes the peer's
Host Identity and a signature over the locators. This allows the DHT
client or server to validate the address information stored in the DHT.
These two separate lookups are defined instead of one because the
address record is expected to change more frequently, while the
name-to-HIT binding should remain relatively constant. For example,
local policy may specify checking the name-to-HIT binding on a daily
basis, while the address record is updated hourly for active peers.
Also the client
and server validation of the two records is different, with the HIT
lookup using certificates verifying the name and the address lookup using
a signature produced by the bearer of a particular Host Identity/HIT.
These services reduce the amount of pre-configuration required
at each HIP host. The address of each peer no longer
needs to be known ahead of time, if peers also participate by
publishing their addresses. If peers choose to publish their HITs
with a name, peer HITs also no longer require pre-configuration.
However, discovering an available DHT server for servicing these lookups
will require some additional configuration.
Given the SHA-1 hash of a name, a lookup returns the HIT of the peer.
The hash of a name is used because OpenDHT keys are limited to
20 bytes, so this allows for longer names.
Publish, lookup, and remove operations are defined.
HIT publishfieldvaluedata typeapplication"hip-name-hit"stringclient_library(implementation dependent)stringkeySHA-1 hash of a namebase64 encodedvalueHDRR([CERT]), with the HIT to be published contained in the
Sender's HIT field of the HDRR, and an optional certificate
for validating the name used as the keybase64 encodedttl_seclifetime for this record, value from 0-604800 secondsnumeric stringsecret_hashoptional SHA-1 hash of secret valuebase64 encodedHIT lookupfieldvaluedata typeapplication"hip-name-hit"stringclient_library(implementation dependent)stringkeySHA-1 hash of a namebase64 encodedmaxvals(implementation dependent)numeric stringplacemark(NULL, or used from server reply)base64 encodedHIT remove (optional)fieldvaluedata typeapplication"hip-name-hit"stringclient_library(implementation dependent)stringkeySHA-1 hash of a namebase64 encodedvalue_hashSHA-1 hash of HDRR (value used during publish) to removebase64 encodedttl_seclifetime for the remove should be greater than or equal to
the amount of time remaining for the recordnumeric stringsecretsecret value (SHA-1 of this was used in put)base64 encodedThe key for both HIT publish and lookup is the SHA-1 hash of the
name. The name does not necessarily need to be associated with a
valid DNS or host name. It does not need to be related to the Domain
Identifier found in HI TLV.
OpenDHT limits the keys to 20 bytes in length,
so the SHA-1 hash is used to allow arbitrary name lengths.
The value used in the publish and lookup response MUST be
the base64-encoded
HDRR containing the HIT, and MAY include an optional certificate.
The HIT MUST be stored in the Sender's HIT field in the HDRR header,
and is a 128-bit value than can
be identified as a HIT both by its length and by the
ORCHID prefix () that it starts with.
If a certificate is included in this HIT record, the name used
for the DHT key MUST be listed in the certificate.
The CERT parameter is defined in .
The Common Name (CN)
field from the distinguished name (DN) of the X.509.v3 certificate
MUST be used. The server
can hash this name to verify it matches the DHT key.
The ttl_sec field specifies
the number of seconds requested by the client that the entry should
be stored
by the DHT server, which is implementation or policy dependent.
The secret_hash is an optional field used with HIT publish
if the value will later be removed with an rm operation.
It is RECOMMENDED that clients support these rm operations for the values
they publish.
The secret_hash contains the base64 encoded SHA-1 hash of some secret
value known only to the publishing host.
A different secret value SHOULD
be used for each put because rm requests are visible on the network.
The max_vals and placemark fields used with the HIT lookup are
defined by the get XML-RPC interface.
Given a HIT, a lookup returns the IP address of the peer.
The address is contained in a LOCATOR TLV inside the HDRR, along with
other validation data.
This interface has publish, lookup, and remove operations. A summary
of these three operations is listed below. The abbreviated notation
refers to the HIP parameter types; for example HIP_SIG is the HIP
signature parameter defined by . The details
of these DHT operations is then described in greater detail.
The HDRR is defined in
.
It contains one or more locators that the peer wants to publish,
a sequence number, the peer's Host Identity, an optional certificate,
and signature over the contents.
The HIT_KEY is the last 100 bits of the HIT appended with 60 zero
bits. This is the portion of the HIT used as a DHT key. The
last 100 bits is used to avoid uneven distribution of the
stored values across the DHT servers. The first 28 bits is the
HIT's ORCHID Prefix defined by , and this
prefix is dropped because it is the same for all HITs, which would cause
this uneven distribution.
Zero padding is appended to this 100-bit value to fill the length required
by the DHT, 160 bits total.
Address publishfieldvaluedata typeapplication"hip-addr"stringclient_library(implementation dependent)stringkeyHIT_KEYbase64 encodedvalueHDRR(LOCATOR, SEQ, HOST_ID, [CERT], HIP_SIG),
with the IP address to be published contained in the
LOCATOR TLV in the HDRR, along with other validation database64 encodedttl_secamount of time HDRR should be valid,
or the lifetime of the preferred address,
a value from 0-604800 secondsnumeric stringsecret_hashoptional SHA-1 hash of secret valuebase64 encodedAddress lookupfieldvaluedata typeapplication"hip-addr"stringclient_library(implementation dependent)stringkeyHIT_KEYbase64 encodedmaxvals(implementation dependent)numeric stringplacemark(NULL, or used from server reply)base64 encodedAddress remove (optional)fieldvaluedata typeapplication"hip-addr"stringclient_library(implementation dependent)stringkeyHIT_KEYbase64 encodedvalue_hashSHA-1 hash of HDRR (value used during publish)
to removebase64 encodedttl_secold address lifetimenumeric stringsecretsecret value (SHA-1 of this was used in put)base64 encoded
The application and client_library fields are used for logging in
OpenDHT. The client_library may vary between different implementations,
specifying the name of the XML-RPC library used or the application that
directly makes XML-RPC calls.
The key used with the address lookup and with publishing the address
is the HIT_KEY as defined above, 160 bits
base64 encoded .
The value used in the publish and lookup response is the base64
encoded HDRR containing one or more LOCATORs.
The ttl_sec field used with address publish indicates the time-to-live.
This is the number of seconds for which the entry will be stored
by the DHT. The time-to-live SHOULD be set to
the number of seconds remaining in the address lifetime.
The secret_hash is an optional field that MAY be used with
address publish
if the value will later be removed with an rm operation.
The secret_hash contains the base64 encoded SHA-1 hash of some secret
value that MUST be known only to the publishing host.
Clients SHOULD include the secret_hash and remove outdated values to
reduce the amount of data the peer needs to handle.
A different secret value SHOULD
be used for each put because rm requests are visible on the network.
The max_vals and placemark fields used with address lookup are
defined by the get XML-RPC interface. The get operation needs to know the
maximum number of values to retrieve. The placemark is a value found
in the server reply that causes the get to continue to retrieve values
starting at where it left off.
Below are some suggestions of when a HIP implementation MAY want to
use the HIT and address lookup services.
To learn of a peer's HIT, a host might first consult DNS
using the peer's hostname if the DNS server supports the HIP
Resource Record defined by
. Sometimes hosts do not have
administrative authority over their DNS entries and/or the DNS
server is not able to support HIP resource records. Hosts may want
to associate other non-DNS names with their HITs. For these and
other reasons, a host MAY use the HIT publish service defined
in . The peer HIT may be learned
by performing a DHT lookup of such a name.
Once a peer HIT is learned or configured, an address lookup MAY be
performed so that the LOCATORs can be cached and immediately available
for when an association is requested. Implementations might load a list
of peer HITs on startup, resulting in several lookups that can take some
time to complete.
However, cached LOCATORs may quickly become obsolete, depending on
how often the peer changes its preferred address. Performing an address
lookup before sending the I1 may be needed. At this time the latency of
a lookup may be intolerable, and a lookup could instead be
performed after the I1 retransmission timer fires -- when no R1 reply has
been received -- to detect any change in address.
A HIP host SHOULD publish its preferred LOCATORs upon startup, so
other hosts may determine where it is reachable. The host SHOULD
periodically refresh its HDRR entry because each entry carries a
TTL and will eventually expire. Also, when there is a
change in preferred address, usually associated with sending UPDATE
packets with included locator parameters, the host SHOULD update its
HDRR with the DHT. The old HDRR SHOULD be
removed using the rm operation, if a secret value was used in the put.
Addresses from the private address space SHOULD NOT be published
to the DHT. If the host is located behind a NAT, for example, the
host could publish the address of its Rendezvous Server (RVS, from
) to the DHT if that is how
it is reachable.
In this case however, a peer could instead simply use the RVS field
of the
NATted host's HIP DNS record, which would eliminate a separate DHT lookup.
A HIP host SHOULD also publish its HIT upon startup or whenever
a new HIT is configured, for use with the HIT lookup service, if desired.
The host SHOULD first check if the name already exists in the DHT
by performing a lookup, to avoid interfering with an existing
name-to-HIT mapping. The name-to-HIT binding
needs to be refreshed periodically before the TTL expires.
When publishing data to the DHT server, care should be taken to check
the response from the server. The server may respond with an "over
capacity" code, indicating that its resources are too burdened to honor
the given size and TTL. The host SHOULD then select another server for
publishing, or reduce the TTL and retry the put operation.
The DHT put operation does not replace existing values.
If a host does not remove its old
HDRR before adding another, several entries may be present.
A client performing a lookup SHOULD determine the most recent address
based on the Update ID from the SEQ TLV of the HDRR.
The order of values returned in the server's response may not be
guaranteed. Before performing each put a host SHOULD remove
its old HDRR data using the rm operation.
In the case of the HIT lookup service, there is nothing preventing
different hosts from publishing the same name. A lookup performed
on this name will return multiple HITs that belong to different devices.
The server may enforce a policy that requires clients to include
a certificate when publishing a HIT, and only store HITs with a name
that has been authorized by some trusted certificate.
Otherwise this is an unmanaged free-for-all service,
and it is RECOMMENDED that a host simply pick another name.
Selecting an appropriate DHT server to use is not covered here.
If a particular server becomes unavailable, the connect will timeout and
some server selection algorithm SHOULD be performed, such as trying the
next server in a configured list. OpenDHT formerly provided a DNS-based
anycast service, when one performed a lookup of "opendht.nyuld.net",
it returned the two nearest OpenDHT servers.
The latency involved with the DHT put and get operations should be
considered when using these services with HIP.
The calls rely on servers that may be located across the Internet, and
may trigger communications between servers that add delay.
The DHT operations themselves may be slow to produce a response.
The maximum size of 1024 bytes for the value field will limit the
maximum size of the Host Identity and certificates
that may be used within the HDRR.
There are two classes of attacks on this information exchange between
host and DHT server: attacks on the validity of the information
provided by the DHT to the host (such as a spoofed DHT response)
and attacks on the DHT records themselves (such as polluted
records for a given key). Without the server performing some
measure of verification,
not much can be done to prevent these attacks.
For the HIT lookup based on name
(),
there are no guarantees on the validity of the HIT. Users concerned
with the validity of HITs found in the DHT SHOULD simply exchange
HITs out-of-band with peers. Including a signature will not help
here because the HIT that identifies the Host Identity for signing
is not known ahead of time. A certificate MAY be included with the
HIT which guarantees that the name used for the lookup has been
authorized by some 3rd party authority. Which certificates are
considered trusted is a local policy issue.
For the address lookup based on HIT
(), the validity of the
DHT response MUST be checked with the HOST_ID and SIGNATURE parameters
in the HDRR. A HIP initiating host SHOULD also validate the DHT response
after the R1 message is received during a HIP exchange.
The Host Identity provided in the
R1 can be hashed to obtain a HIT that MUST be checked against the
original HIT. However, a legacy OpenDHT service without server
modifications does not
prevent an attacker from polluting the DHT records for a known
HIT, thereby causing a denial-of-service attack, since server
validation is not performed.
Relying solely on client validation may be harmful.
An attacker can replay the put packets containing the signed HDRR,
possibly causing stale or invalid information to exist in the DHT.
If an attacker replays the signed put message and changes some aspect
each time, and if the server is not performing signature and HIT
validation, there could be a multitude of invalid entries stored
in the DHT. When a client retrieves these records it would need to
perform signature and HIT verification on each one, which could
cause unacceptable amounts of delay or computation.
To protect against this type of attack, the DHT server SHOULD perform
signature and HIT verification of each put operation as described
in . Another option would
be the server running HIP itself and requiring client
authentication with a HIP association before
accepting HDRR puts. Further validation would be only accepting
HIT and address records from the association bound to the same HIT.
Performing server-side verification adds to the processing burden of
the DHT server and may be a source for a denial-of-service attack.
Requiring a HIP association before accepting HDRR puts may help here.
The HIT verification is less computationally-intensive by design,
using a hash algorithm. Certificate validation (for name lookups) and
signature verification (for HDRRs) may cause unacceptable
amounts of computation. A server may rate limit the number of puts
that it allows.
The SHA-1 message digest algorithm is used in two ways in this document,
and the security of using this algorithm should be considered
within the context of .
The first use is with the OpenDHT put and remove operations,
described in ,
and the
second is to reduce the size of the name string for the HIT lookup
service in .
The first use is intended to protect the secret values used to store
records in the DHT as described by the OpenDHT interface. An attacker
would be able to remove a record, after capturing the plaintext put,
if a secret value could be found that
produces the same secret hash.
The purpose of this document is to maintain interoperable
compatibility with that
interface, which prescribes the use of SHA-1. Future revisions of that
interface should consider hash algorithm agility. The OpenDHT FAQ states
that future support for other hash algorithms is planned.
The second use of the SHA-1 algorithm is to reduce the
arbitrarily-sized name strings to fit the fixed OpenDHT key size.
No security
properties of the SHA-1 algorithm are used in this context.
This document defines a new HIP Packet Type, the HIP Distributed
Hash Table Resource Record (HDRR). This packet type is defined in
with a value of 20.
Thanks to Tom Henderson, Samu Varjonen, Andrei Gurtov, Miika Komu,
Kristian Slavov, Ken Rimey, Ari Keranen, and Martin Stiemerling for
providing comments.
Samu most notably
contributed the resolver packet and its suggested parameters, which
became the HDRR here.
Revised based on Gen-ART review. Various grammatical updates.
Included text in the Security Considerations section referring to
RFC 6194 and the use of SHA-1 with OpenDHT.
Revised based on IRSG review. Swapped sections 3 and 4, moving
HDRR introductory text to section 3. Added text on frequency of lookups,
server side denial of service, and other suggestions.
Organized references into normative and informative. Updated text on
RG consensus.
Added RFC 2119 terminology phrase in the introduction, and
incorporated RFC 2119 keywords throughout the text. Added clarification
for the first occurrence of HIP parameter abbreviations. Changed intended
status from Informational to Experimental.
Incorporated comments from Ari Keranen: added references to CERT draft
and RFC 5204. Added clarifications from OpenDHT user's guide. Simplified
description of HIT_KEY. Dropped RFC 2119 language. Added IANA
considerations. Other minor corrections and clarifications.
Document name changed to reflect acceptance as a HIPRG document.
Text added to introduction about document acceptance.
Use the HDRR format as return values for both services.
Added optional certificates for both services.
Added text about HIP-aware DHT server that validates HITs/signatures.
Added SEQ TLV to HDRR, removed text about ordering.
Relaxed statement about DNS and referenced draft-ponomarev-hip-hit2ip.
Added text describing why HDRR is different than DNS RR.
Added text about handling of source/destination HITs in HDRR.
Renamed Section 5 to "Use cases". Added failure code for put.
Removed text about
servers not honoring TTL. Added text clarifying what OpenLookup is.
Reordered Sections 3.2 and 3.1, since the HIT lookup normally occurs
before the address lookup. Added text about why two separate lookups
are defined. Added text pertaining to the OpenDHT service retiring.
Revised text about server treatment of TTL.
Added text about TTL expiration, appending zero padding, HIT value
usage. Removed text on anonymous bit. Use RFC references.
sockaddr address format changed to use HIP DHT Resource Record
containing
the HIP LOCATOR format. The HIT prefix is dropped before using it as a
key. Separate "secure" service was dropped, and signatures made
mandatory. Legacy versus hip-aware DHT servers are
distinguished. Text packet examples added.
Removed the HIT lookup service -- using the LSI as a key to return
a HIT as the value -- and added a HIT lookup service using names.
Added support for OpenDHT remove. Changed all occurrences
of "Open DHT" to "OpenDHT".
Added the Host Identity and a signature as a secure address lookup
service, with text about running a modified OpenDHT server that can
verify signed put messages based on Host Identity signatures.