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Versions: (draft-moskowitz-hip-arch) 00 01 02
03 RFC 4423
Network Working Group R. Moskowitz
Internet-Draft ICSAlabs, a Division of TruSecure
Expires: July 11, 2004 Corporation
P. Nikander
Ericsson Research Nomadic Lab
January 11, 2004
Host Identity Protocol Architecture
draft-ietf-hip-arch-02
Status of this Memo
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Copyright Notice
Copyright (C) The Internet Society (2004).
Abstract
This memo describes a snapshot of the reasoning behind a proposed new
namespace, the Host Identity namespace, and a new protocol layer, the
Host Identity Protocol, between the internetworking and transport
layers. Herein are presented the basics of the current namespaces,
their strengths and weaknesses, and how a new namespace will add
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completeness to them. The roles of this new namespace in the
protocols are defined. The memo describes the thinking of the
authors as of Fall 2003. The architecture may have evolved since.
This document represents one stable point in that evolution of
understanding.
Table of Contents
1. Disclaimer . . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
3. Terminology . . . . . . . . . . . . . . . . . . . . . . . . 4
3.1 Terms common to other documents . . . . . . . . . . . . . . 4
3.2 Terms specific to this and other HIP documents . . . . . . . 4
4. Background . . . . . . . . . . . . . . . . . . . . . . . . . 6
4.1 A desire for a namespace for computing platforms . . . . . . 7
5. Host Identity namespace . . . . . . . . . . . . . . . . . . 8
5.1 Host Identifiers . . . . . . . . . . . . . . . . . . . . . . 9
5.2 Storing Host Identifiers in DNS . . . . . . . . . . . . . . 9
5.3 Host Identity Tag (HIT) . . . . . . . . . . . . . . . . . . 10
5.4 Local Scope Identifier (LSI) . . . . . . . . . . . . . . . . 10
6. New stack architecture . . . . . . . . . . . . . . . . . . . 10
6.1 Transport associations and end-points . . . . . . . . . . . 11
7. End-host mobility and multi-homing . . . . . . . . . . . . . 12
7.1 Rendezvous mechanism . . . . . . . . . . . . . . . . . . . . 12
7.2 Protection against flooding attacks . . . . . . . . . . . . 13
8. HIP and IPsec . . . . . . . . . . . . . . . . . . . . . . . 13
9. HIP and NATs . . . . . . . . . . . . . . . . . . . . . . . . 14
9.1 HIP and TCP checksums . . . . . . . . . . . . . . . . . . . 15
10. Multicast . . . . . . . . . . . . . . . . . . . . . . . . . 15
11. HIP policies . . . . . . . . . . . . . . . . . . . . . . . . 15
12. Benefits of HIP . . . . . . . . . . . . . . . . . . . . . . 16
12.1 HIP's answers to NSRG questions . . . . . . . . . . . . . . 17
13. Security considerations . . . . . . . . . . . . . . . . . . 19
13.1 HITs used in ACLs . . . . . . . . . . . . . . . . . . . . . 20
13.2 Non-security considerations . . . . . . . . . . . . . . . . 21
14. IANA considerations . . . . . . . . . . . . . . . . . . . . 21
15. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . 21
16. Informative references . . . . . . . . . . . . . . . . . . . 22
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . 23
Intellectual Property and Copyright Statements . . . . . . . 24
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1. Disclaimer
The purpose of this memo is to provide a stable reference point in
the development of the Host Identity Protocol architecture. This
memo describes the thinking of the authors as of Fall 2003; their
thinking may have evolved since then. Occasionally, this memo may be
confusing or self-contradicting. That is (partially) intentional,
and reflects the snapshot nature of this memo.
2. Introduction
The Internet has two important global namespaces: Internet Protocol
(IP) addresses and Domain Name Service (DNS) names. These two
namespaces have a set of features and abstractions that have powered
the Internet to what it is today. They also have a number of
weaknesses. Basically, since they are all we have, we try and do too
much with them. Semantic overloading and functionality extensions
have greatly complicated these namespaces.
The proposed Host Identity namespace fills an important gap between
the IP and DNS namespaces. The Host Identity namespace consists of
Host Identifiers (HI). A Host Identifier is cryptographic in its
nature; it is the public key of an asymmetric key-pair. Each host
will have at least one Host Identity, but it will typically have more
than one. Each Host Identity uniquely identifies a single host,
i.e., no two hosts have the same Host Identity. The Host Identity,
and the corresponding Host Identifier, can either be public (e.g.
published in the DNS), or unpublished. Client systems will tend to
have both public and unpublished Identities.
There is a subtle but important difference between Host Identities
and Host Identifiers. An Identity refers to the abstract entity that
is identified. An Identifier, on the other hand, refers to the
concrete bit pattern that is used in the identification process.
Although the Host Identifiers could be used in many authentication
systems, such as IKEv2 [11], the presented architecture introduces a
new protocol, called the Host Identity Protocol (HIP), and a
cryptographic exchange, called the HIP base exchange [6]; see also
Section 8. The new protocol provides for limited forms of trust
between systems. It enhances mobility, multi-homing and dynamic IP
renumbering [9], aids in protocol translation / transition [6], and
reduces certain types of denial-of-service (DoS) attacks [6].
When HIP is used, the actual payload traffic between two HIP hosts is
typically, but not necessarily, protected with IPsec. The Host
Identities are used to create the needed IPsec Security Associations
(SAs) and to authenticate the hosts. When IPsec is used, the actual
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payload IP packets do not differ in any way from standard IPsec
protected IP packets.
3. Terminology
3.1 Terms common to other documents
+--------------+----------------------------------------------------+
| Term | Explanation |
+--------------+----------------------------------------------------+
| Public key | The public key of an asymmetric cryptographic key |
| | pair. Used as a publicly known identifier for |
| | cryptographic identity authentication. |
| | |
| Private key | The private or secret key of an asymmetric |
| | cryptographic key pair. Assumed to be known only |
| | to the party identified by the corresponding |
| | public key. Used by the identified party to |
| | authenticate its identity to other parties. |
| | |
| Public key | An asymmetric cryptographic key pair consisting of |
| pair | public and private keys. For example, |
| | Rivest-Shamir-Adelman (RSA) and Digital Signature |
| | Algorithm (DSA) key pairs are such key pairs. |
| | |
| End-point | A communicating entity. For historical reasons, |
| | the term 'computing platform' is used in this |
| | document as a (rough) synonym for end-point. |
+--------------+----------------------------------------------------+
3.2 Terms specific to this and other HIP documents
It should be noted that many of the terms defined herein are
tautologous, self-referential or defined through circular reference
to other terms. This is due to the succinct nature of the
definitions. See the text elsewhere in this document for more
elaborate explanations.
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+--------------+----------------------------------------------------+
| Term | Explanation |
+--------------+----------------------------------------------------+
| Computing | An entity capable of communicating and computing, |
| platform | for example, a computer. See the definition of |
| | 'End-point', above. |
| | |
| HIP base | A cryptographic protocol defined in [6]. See also |
| exchange | Section 8. |
| | |
| HIP packet | An IP packet that carries a 'Host Identity |
| | Protocol' message. |
| | |
| Host | An abstract concept assigned to a 'computing |
| Identity | platform'. See 'Host Identifier', below. |
| | |
| Host | A name space formed by all possible Host |
| Identity | Identifiers. |
| namespace | |
| | |
| Host | A protocol used to carry and authenticate Host |
| Identity | Identifiers and other information. |
| Protocol | |
| | |
| Host | A 128-bit datum created by taking a cryptographic |
| Identity Tag | hash over a Host Identifier. |
| | |
| Host | A public key used as a name for a Host Identity. |
| Identifier | |
| | |
| Local Scope | A 32-bit datum denoting a Host Identity. |
| Identifier | |
| | |
| Public Host | A published or publicly known Host Identfier used |
| Identifier | as a public name for a Host Identity, and the |
| and Identity | corresponding Identity. |
| | |
| Unpublished | A Host Identifier that is not placed in any public |
| Host | directory, and the corresponding Host Identity. |
| Identifier | Unpublished Host Identities are typically short |
| and Identity | lived in nature, being often replaced and possibly |
| | used just once. |
| | |
| Rendezvous | A mechanism used to locate mobile hosts based on |
| Mechanism | their HIT. |
+--------------+----------------------------------------------------+
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4. Background
The Internet is built from three principal components: computing
platforms (end-points), packet transport (i.e., internetworking)
infrastructure, and services (applications). The Internet exists to
service two principal components: people and robotic services
(silicon based people, if you will). All these components need to be
named in order to interact in a scalable manner. Here we concentrate
on naming computing platforms and packet transport elements.
There are two principal namespaces in use in the Internet for these
components: IP numbers, and Domain Names. Email, HTTP, and SIP
addresses are really only extensions of Domain Names.
IP numbers are a confounding of two namespaces, the names of a host's
networking interfaces and the names of the locations ('confounding'
is a term used in statistics to discuss metrics that are merged into
one with a gain in indexing, but a loss in informational value). The
names of locations should be understood as denoting routing direction
vectors, i.e., information that is used to deliver packets to their
destinations.
IP numbers name networking interfaces, and typically only when the
interface is connected to the network. Originally, IP numbers had
long-term significance. Today, the vast number of interfaces use
ephemeral and/or non-unique IP numbers. That is, every time an
interface is connected to the network, it is assigned an IP number.
In the current Internet, the transport layers are coupled to the IP
addresses. Neither can evolve separately from the other. IPng
deliberations were strongly shaped by the decision that a
corresponding TCPng would not be created.
Domain Names provide hierarchically assigned names for some computing
platforms and some services. Each hierarchy is delegated from the
level above; there is no anonymity in Domain Names.
Email, SIP and WWW addresses provide naming for humans, autonomous
applications, and documents. Email, SIP and WWW addresses are
extensions of Domain Names.
There are three critical deficiencies with the current namespaces.
Firstly, dynamic readdressing cannot be directly managed. Secondly,
anonymity is not provided in a consistent, trustable manner.
Finally, authentication for systems and datagrams is not provided.
All of these deficiencies arise because computing platforms are not
well named with the current namespaces.
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4.1 A desire for a namespace for computing platforms
An independent namespace for computing platforms could be used in
end-to-end operations independent of the evolution of the
internetworking layer and across the many internetworking layers.
This could support rapid readdressing of the internetworking layer
because of mobility, rehoming, or renumbering.
If the namespace for computing platforms is based on public-key
cryptography, it can also provide authentication services. If this
namespace is locally created without requiring registration, it can
provide anonymity.
Such a namespace (for computing platforms) and the names in it should
have the following characteristics:
o The namespace should be applied to the IP 'kernel'. The IP kernel
is the 'component' between applications and the packet transport
infrastructure.
o The namespace should fully decouple the internetworking layer from
the higher layers. The names should replace all occurrences of IP
addresses within applications (like in the Transport Control
Block, TCB). This may require changes to the current APIs. In
the long run, it is probable that some new APIs are needed.
o The introduction of the namespace should not mandate any
administrative infrastructure. Deployment must come from the
bottom up, in a pairwise deployment.
o The names should have a fixed length representation, for easy
inclusion in datagram headers and existing programming interfaces
(e.g the TCB).
o Using the namespace should be affordable when used in protocols.
This is primarily a packet size issue. There is also a
computational concern in affordability.
o The names must be statistically globally unique. 64 bits is
inadequate to make the probability of collisions sufficiently low
(1% chance of collision in a population of 640M); thus,
approximately 100 or more bits should be used.
o The names should have a localized abstraction so that it can be
used in existing protocols and APIs.
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o It must be possible to create names locally. This can provide
anonymity at the cost of making resolvability very difficult.
* Sometimes the names may contain a delegation component. This
is the cost of resolvability.
o The namespace should provide authentication services.
o The names should be long lived, but replaceable at any time. This
impacts access control lists; short lifetimes will tend to result
in tedious list maintenance or require a namespace infrastructure
for central control of access lists.
In this document, a new namespace approaching these ideas is called
the Host Identity namespace. Using Host Identities requires its own
protocol layer, the Host Identity Protocol, between the
internetworking and transport layers. The names are based on
public-key cryptography to supply authentication services. Properly
designed, it can deliver all of the above stated requirements.
5. Host Identity namespace
A name in the Host Identity namespace, a Host Identifier (HI),
represents a statistically globally unique name for naming any system
with an IP stack. This identity is normally associated with, but not
limited to, an IP stack. A system can have multiple identities, some
'well known', some unpublished or 'anonymous'. A system may
self-assert its own identity, or may use a third-party authenticator
like DNSSEC [2], PGP, or X.509 to 'notarize' the identity assertion.
It is expected that the Host Identifiers will initially be
authenticated with DNSSEC and that all implementations will support
DNSSEC as a minimal baseline.
In theory, any name that can claim to be 'statistically globally
unique' may serve as a Host Identifier. However, in the authors'
opinion, a public key of a 'public key pair' makes the best Host
Identifier. As documented in the Host Identity Protocol
specification [6], a public-key-based HI can authenticate the HIP
packets and protect them for man-in-the-middle attacks. Since
authenticated datagrams are mandatory to provide much of HIP's
denial-of-service protection, the Diffie-Hellman exchange in HIP has
to be authenticated. Thus, only public-key HI and authenticated HIP
messages are supported in practice. In this document, the
non-cryptographic forms of HI and HIP are presented to complete the
theory of HI, but they should not be implemented as they could
produce worse denial-of-service attacks than the Internet has without
Host Identity.
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5.1 Host Identifiers
Host Identity adds two main features to Internet protocols. The
first is a decoupling of the internetworking and transport layers;
see Section 6. This decoupling will allow for independent evolution
of the two layers. Additionally, it can provide end-to-end services
over multiple internetworking realms. The second feature is host
authentication. Because the Host Identifier is a public key, this
key can be used for authentication in security protocols like IPsec.
The only completely defined structure of the Host Identity is that of
a public/private key pair. In this case, the Host Identity is
referred to by its public component, the public key. Thus, the name
representing a Host Identity in the Host Identity namespace, i.e.,
the Host Identifier, is the public key. In a way, the possession of
the private key defines the Identity itself. If the private key is
possessed by more than one node, the Identity can be considered to be
a distributed one.
Architecturally, any other Internet naming convention might form a
usable base for Host Identifiers. However, non-cryptographic names
should only be used in situations of high trust - low risk. That is
any place where host authentication is not needed (no risk of host
spoofing) and no use of IPsec. However, at least for interconnected
networks spanning several operational domains, the set of
environments where the risk of host spoofing allowed by
non-cryptographic Host Identifiers is acceptable is the null set.
Hence, the current HIP documents do not specify how to use any other
types of Host Identifiers but public keys.
The actual Host Identities are never directly used in any Internet
protocols. The corresponding Host Identifiers (public keys) may be
stored in various DNS or LDAP directories as identified elsewhere in
this document, and they are passed in the HIP base exchange. A Host
Identity Tag (HIT) is used in other protocols to represent the Host
Identity. Another representation of the Host Identities, the Local
Scope Identifier (LSI), can also be used in protocols and APIs.
5.2 Storing Host Identifiers in DNS
The public Host Identifiers should be stored in DNS; the unpublished
Host Identifiers should not be stored anywhere (besides the
communicating hosts themselves). The (public) HI is stored in a new
RR type, to be defined. This RR type is likely to be quite similar
to the IPSECKEY RR [7].
Alternatively, or in addition to storing Host Identifiers in the DNS,
they may be stored in various kinds of Public Key Infrastructure
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(PKI). Such a practice may allow them to be used for purposes other
than pure host identification.
5.3 Host Identity Tag (HIT)
A Host Identity Tag is a 128-bit representation for a Host Identity.
It is created by taking a cryptographic hash over the corresponding
Host Identifier. There are two advantages of using a hash over using
the Host Identifier in protocols. Firstly, its fixed length makes
for easier protocol coding and also better manages the packet size
cost of this technology. Secondly, it presents the identity in a
consistent format to the protocol independent of the cryptographic
algorithms used.
In the HIP packets, the HITs identify the sender and recipient of a
packet. Consequently, a HIT should be unique in the whole IP
universe as long as it is being used. In the extremely rare case of
a single HIT mapping to more than one Host Identity, the Host
Identifiers (public keys) will make the final difference. If there
is more than one public key for a given node, the HIT acts as a hint
for the correct public key to use.
5.4 Local Scope Identifier (LSI)
An LSI is a 32-bit localized representation for a Host Identity. The
purpose of an LSI is to facilitate using Host Identities in existing
protocols and APIs. LSI's advantage over HIT is its size; its
disadvantage is its local scope. The generation of LSIs is defined
in the Host Identity Protocol specification [6].
Examples of how LSIs can be used include: as the address in an FTP
command and as the address in a socket call. Thus, LSIs act as a
bridge for Host Identities into IPv4-based protocols and APIs.
6. New stack architecture
One way to characterize Host Identity is to compare the proposed new
architecture with the current one. As discussed above, the IP
addresses can be seen to be a confounding of routing direction
vectors and interface names. Using the terminology from the IRTF
Name Space Research Group Report [8] and, e.g., the unpublished
Internet-Draft Endpoints and Endpoint Names [12] by Noel Chiappa, the
IP addresses currently embody the dual role of locators and end-point
identifiers. That is, each IP address names a topological location
in the Internet, thereby acting as a routing direction vector, or
locator. At the same time, the IP address names the physical network
interface currently located at the point-of-attachment, thereby
acting as a end-point name.
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In the HIP architecture, the end-point names and locators are
separated from each other. IP addresses continue to act as locators.
The Host Identifiers take the role of end-point identifiers. It is
important to understand that the end-point names based on Host
Identities are slightly different from interface names; a Host
Identity can be simultaneously reachable through several interfaces.
The difference between the bindings of the logical entities are
illustrated in Figure 1.
Service ------ Socket Service ------ Socket
| |
| |
| |
| |
End-point | End-point --- Host Identity
\ | |
\ | |
\ | |
\ | |
Location --- IP address Location --- IP address
Figure 1
6.1 Transport associations and end-points
Architecturally, HIP provides for a different binding of
transport-layer protocols. That is, the transport-layer
associations, i.e., TCP connections and UDP associations, are no
longer bound to IP addresses but to Host Identities.
It is possible that a single physical computer hosts several logical
end-points. With HIP, each of these end-points would have a distinct
Host Identity. Furthermore, since the transport associations are
bound to Host Identities, HIP provides for process migration and
clustered servers. That is, if a Host Identity is moved from one
physical computer to another, it is also possible to simultaneously
move all the transport associations without breaking them.
Similarly, if it is possible to distribute the processing of a single
Host Identity over several physical computers, HIP provides for
cluster based services without any changes at the client end-point.
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7. End-host mobility and multi-homing
HIP decouples the transport from the internetworking layer, and binds
the transport associations to the Host Identities (through actually
either the HIT or LSI). Consequently, HIP can provide for a degree
of internetworking mobility and multi-homing at a low infrastructure
cost. HIP mobility includes IP address changes (via any method) to
either party. Thus, a system is considered mobile if its IP address
can change dynamically for any reason like PPP, DHCP, IPv6 prefix
reassignments, or a NAT device remapping its translation. Likewise,
a system is considered multi-homed if it has more than one globally
routable IP address at the same time. HIP links IP addresses
together, when multiple IP addresses correspond to the same Host
Identity, and if one address becomes unusable, or a more preferred
address becomes available, existing transport associations can easily
be moved to another address.
When a node moves while communication is already on-going, address
changes are rather straightforward. The peer of the mobile node can
just accept a HIP or an integrity protected IPsec packet from any
address and ignore the source address. However, as discussed in
Section 7.2 below, a mobile node must send a HIP readdress packet to
inform the peer of the new address(es), and the peer must verify that
the mobile node is reachable through these addresses. This is
especially helpful for those situations where the peer node is
sending data periodically to the mobile node (that is re-starting a
connection after the initial connection).
7.1 Rendezvous mechanism
Making a contact to a mobile node is slightly more involved. In
order to start the HIP exchange, the initiator node has to know how
to reach the mobile node. Although infrequently moving HIP nodes
could use Dynamic DNS [1] to update their reachability information in
the DNS, an alternative to using DNS in this fashion is to use a
piece of new static infrastructure to facilitate rendezvous between
HIP nodes.
The mobile node keeps the rendezvous infrastructure continuously
updated with its current IP address(es). The mobile nodes must trust
the rendezvous mechanism to properly maintain their HIT and IP
address mappings.
The rendezvous mechanism is also needed if both of the nodes happen
to change their address at the same time, either because they are
mobile and happen to move at the same time, because one of them is
off-line for a while, or because of some other reason. In such a
case, the HIP readdress packets will cross each other in the network
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and never reach the peer node.
A separate document will specify the details of the HIP rendezvous
mechanism.
7.2 Protection against flooding attacks
Although the idea of informing about address changes by simply
sending packets with a new source address appears appealing, it is
not secure enough. That is, even if HIP does not rely on the source
address for anything (once the base exchange has been completed), it
appears to be necessary to check a mobile node's reachability at the
new address before actually sending any larger amounts of traffic to
the new address.
Blindly accepting new addresses would potentially lead to flooding
Denial-of-Service attacks against third parties [10]. In a
distributed flooding attack an attacker opens high volume HIP
connections with a large number of hosts (using unpublished HIs), and
then claims to all of these hosts that it has moved to a target
node's IP address. If the peer hosts were to simply accept the move,
the result would be a packet flood to the target node's address. To
close this attack, HIP includes an address check mechanism where the
reachability of a node is separately checked at each address before
using the address for larger amounts of traffic.
Whenever HIP is used between two hosts that fully trust each other,
the hosts may optionally decide to skip the address tests. However,
such performance optimization must be restricted to peers that are
known to be trustworthy and capable of protecting themselves from
malicious software.
8. HIP and IPsec
The preferred way of implementing HIP is to use IPsec to carry the
actual data traffic. As of today, the only completely defined method
is to use IPsec Encapsulated Security Payload (ESP) to carry the data
packets. In the future, other ways of transporting payload data may
be developed, including ones that do not use cryptographic
protection.
In practice, the HIP base exchange uses the cryptographic Host
Identifiers to set up a pair of ESP Security Associations (SAs) to
enable ESP in an end-to-end manner. This is implemented in a way
that can span addressing realms.
While it would be possible, at least in theory, to use some existing
cryptographic protocol, such as IKEv2 together with Host Identifiers,
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to establish the needed SAs, HIP defines a new protocol. There are a
number of historical reasons for this, and there are also a few
architectural reasons. First, IKE (and IKEv2) were not designed with
middle boxes in mind. As adding a new naming layer allows one to
potentially add a new forwarding layer (see Section 9, below), it is
very important that the HIP protocols are friendly towards any middle
boxes.
Second, from a conceptual point of view, the IPsec Security Parameter
Index (SPI) in ESP provides a simple compression of the HITs. This
does require per-HIT-pair SAs (and SPIs), and a decrease of policy
granularity over other Key Management Protocols, such as IKE and
IKEv2. In particular, the current thinking is limited to a situation
where, conceptually, there is only one pair of SAs between any given
pair of HITs. In other words, from an architectural point of view,
HIP only supports host-to-host (or endpoint-to-endpoint) Security
Associations. If two hosts need more pairs of parallel SAs, they
should use separate HITs for that. However, future HIP extensions
may provide for more granularity and creation of several ESP SAs
between a pair of HITs.
Since HIP is designed for host usage, not for gateways or so called
Bump-in-the-Wire (BITW) implementations, only ESP transport mode is
supported. An ESP SA pair is indexed by the SPIs and the two HITs
(both HITs since a system can have more than one HIT). The SAs need
not to be bound to IP addresses; all internal control of the SA is by
the HITs. Thus, a host can easily change its address using Mobile
IP, DHCP, PPP, or IPv6 readdressing and still maintain the SAs.
Since the transports are bound to the SA (via an LSI or a HIT), any
active transport is also maintained. Thus, real-world conditions
like loss of a PPP connection and its re-establishment or a mobile
handover will not require a HIP negotiation or disruption of
transport services [14].
Since HIP does not negotiate any SA lifetimes, all lifetimes are
local policy. The only lifetimes a HIP implementation must support
are sequence number rollover (for replay protection), and SA timeout
[6]. An SA times out if no packets are received using that SA.
Implementations may support lifetimes for the various ESP transforms.
9. HIP and NATs
Passing packets between different IP addressing realms requires
changing IP addresses in the packet header. This may happen, for
example, when a packet is passed between the public Internet and a
private address space, or between IPv4 and IPv6 networks. The
address translation is usually implemented as Network Address
Translation (NAT) [4] or NAT Protocol translation (NAT-PT) [3].
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In a network environment where identification is based on the IP
addresses, identifying the communicating nodes is difficult when NAT
is used. With HIP, the transport-layer end-points are bound to the
Host Identities. Thus, a connection between two hosts can traverse
many addressing realm boundaries. The IP addresses are used only for
routing purposes; they may be changed freely during packet traversal.
For a HIP-based flow, a HIP-aware NAT or NAT-PT system tracks the
mapping of HITs, and the corresponding IPsec SPIs, to an IP address.
The NAT system has to learn mappings both from HITs and from SPIs to
IP addresses. Many HITs (and SPIs) can map to a single IP address on
a NAT, simplifying connections on address poor NAT interfaces. The
NAT can gain much of its knowledge from the HIP packets themselves;
however, some NAT configuration may be necessary.
NAT systems cannot touch the datagrams within the IPsec envelope,
thus application-specific address translation must be done in the end
systems. HIP provides for 'Distributed NAT', and uses the HIT or the
LSI as a placeholder for embedded IP addresses.
9.1 HIP and TCP checksums
There is no way for a host to know if any of the IP addresses in an
IP header are the addresses used to calculate the TCP checksum. That
is, it is not feasible to calculate the TCP checksum using the actual
IP addresses in the pseudo header; the addresses received in the
incoming packet are not necessarily the same as they were on the
sending host. Furthermore, it is not possible to recompute the
upper-layer checksums in the NAT/NAT-PT system, since the traffic is
IPsec protected. Consequently, the TCP and UDP checksums are
calculated using the HITs in the place of the IP addresses in the
pseudo header. Furthermore, only the IPv6 pseudo header format is
used. This provides for IPv4 / IPv6 protocol translation.
10. Multicast
Back in the fall of 2003, there was little if any concrete thoughts
about how HIP might affect IP-layer or application-layer multicast.
11. HIP policies
There are a number of variables that will influence the HIP exchanges
that each host must support. All HIP implementations should support
at least 2 HIs, one to publish in DNS and an unpublished one for
anonymous usage. Although unpublished HIs will be rarely used as
responder HIs, they are likely be common for initiators. Support for
multiple HIs is recommended.
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Many initiators would want to use a different HI for different
responders. The implementations should provide for a policy of
initiator HIT to responder HIT. This policy should also include
preferred transforms and local lifetimes.
Responders would need a similar policy, describing the hosts allowed
to participate in HIP exchanges, and the preferred transforms and
local lifetimes.
12. Benefits of HIP
In the beginning, the network layer protocol (i.e., IP) had the
following four "classic" invariants:
o Non-mutable: The address sent is the address received.
o Non-mobile: The address doesn't change during the course of an
"association".
o Reversible: A return header can always be formed by reversing the
source and destination addresses.
o Omniscient: Each host knows what address a partner host can use to
send packets to it.
Actually, the fourth can be inferred from 1 and 3, but it is worth
mentioning for reasons that will be obvious soon if not already.
In the current "post-classic" world, we are intentionally trying to
get rid of the second invariant (both for mobility and for
multi-homing), and we have been forced to give up the first and the
fourth. Realm Specific IP [5] is an attempt to reinstate the fourth
invariant without the first invariant. IPv6 is an attempt to
reinstate the first invariant.
Few systems on the Internet have DNS names that are meaningful. That
is, if they have a Fully Qualified Domain Name (FQDN), that name
typically belongs to a NAT device or a dial-up server, and does not
really identify the system itself but its current connectivity.
FQDNs (and their extensions as email names) are application-layer
names; more frequently naming services than a particular system.
This is why many systems on the Internet are not registered in the
DNS; they do not have services of interest to other Internet hosts.
DNS names are references to IP addresses. This only demonstrates the
interrelationship of the networking and application layers. DNS, as
the Internet's only deployed, distributed database is also the
repository of other namespaces, due in part to DNSSEC and application
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specific key records. Although each namespace can be stretched (IP
with v6, DNS with KEY records), neither can adequately provide for
host authentication or act as a separation between internetworking
and transport layers.
The Host Identity (HI) namespace fills an important gap between the
IP and DNS namespaces. An interesting thing about the HI is that it
actually allows one to give up all but the 3rd network-layer
invariant. That is to say, as long as the source and destination
addresses in the network-layer protocol are reversible, then things
work ok because HIP takes care of host identification, and
reversibility allows one to get a packet back to one's partner host.
You do not care if the network-layer address changes in transit
(mutable) and you don't care what network-layer address the partner
is using (non-omniscient).
12.1 HIP's answers to NSRG questions
The IRTF Name Space Research Group has posed a number of evaluating
questions in their report [8]. In this section, we provide answers
to these questions.
1. How would a stack name improve the overall functionality of the
Internet?
HIP decouples the internetworking layer from the transport
layer, allowing each to evolve separately. The decoupling
makes end-host mobility and multi-homing easier, also across
IPv4 and IPv6 networks. HIs make network renumbering easier,
and they also make process migration and clustered servers
easier to implement. Furthermore, being cryptographic in
nature, they provide the basis for solving the security
problems related to end-host mobility and multi-homing.
2. What does a stack name look like?
A HI is a cryptographic public key. However, instead of using
the keys directly, most protocols use a fixed size hash of the
public key.
3. What is its lifetime?
HIP provides both stable and temporary Host Identifiers.
Stable HIs are typically long lived, with a lifetime of years
or more. The lifetime of temporary HIs depends on how long
the upper-layer connections and applications need them, and
can range from a few seconds to years.
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4. Where does it live in the stack?
The HIs live between the transport and internetworking layers.
5. How is it used on the end points
The Host Identifiers may be used directly or indirectly (in
the form of HITs or LSIs) by applications when they access
network services. Additionally, the Host Identifiers, as
public keys, are used in the built in key agreement protocol,
called the HIP base exchange, to authenticate the hosts to
each other.
6. What administrative infrastructure is needed to support it?
In some environments, it is possible to use HIP
opportunistically, without any infrastructure. However, to
gain full benefit from HIP, the HIs must be stored in the DNS
or a PKI, and a new rendezvous mechanism is needed. Such a
new rendezvous mechanism may need new infrastructure to be
deployed.
7. If we add an additional layer would it make the address list in
SCTP unnecessary?
Yes
8. What additional security benefits would a new naming scheme
offer?
HIP reduces dependency on IP addresses, making the so called
address ownership [13] problems easier to solve. In practice,
HIP provides security for end-host mobility and multi-homing.
Furthermore, since HIP Host Identifiers are public keys,
standard public key certificate infrastructures can be applied
on the top of HIP.
9. What would the resolution mechanisms be, or what characteristics
of a resolution mechanisms would be required?
For most purposes, an approach where DNS names are resolved
simultaneously to HIs and IP addresses is sufficient.
However, if it becomes necessary to resolve HIs into IP
addresses or back to DNS names, a flat resolution
infrastructure is needed. Such an infrastructure could be
based on the ideas of Distributed Hash Tables, but would
require significant new development and deployment.
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13. Security considerations
HIP takes advantage of the new Host Identity paradigm to provide
secure authentication of hosts and to provide a fast key exchange for
IPsec. HIP also attempts to limit the exposure of the host to
various denial-of-service (DoS) and man-in-the-middle (MitM) attacks.
In so doing, HIP itself is subject to its own DoS and MitM attacks
that potentially could be more damaging to a host's ability to
conduct business as usual.
Resource exhausting denial-of-service attacks take advantage of the
cost of setting up a state for a protocol on the responder compared
to the 'cheapness' on the initiator. HIP allows a responder to
increase the cost of the start of state on the initiator and makes an
effort to reduce the cost to the responder. This is done by having
the responder start the authenticated Diffie-Hellman exchange instead
of the initiator, making the HIP base exchange 4 packets long. There
are more details on this process in the Host Identity Protocol
specification [6].
HIP optionally supports opportunistic negotiation. That is, if a
host receives a start of transport without a HIP negotiation, it can
attempt to force a HIP exchange before accepting the connection.
This has the potential for DoS attacks against both hosts. If the
method to force the start of HIP is expensive on either host, the
attacker need only spoof a TCP SYN. This would put both systems into
the expensive operations. HIP avoids this attack by having the
responder send a simple HIP packet that it can pre-build. Since this
packet is fixed and easily replayed, the initiator only reacts to it
if it has just started a connection to the responder.
Man-in-the-middle attacks are difficult to defend against, without
third-party authentication. A skillful MitM could easily handle all
parts of the HIP base exchange, but HIP indirectly provides the
following protection from a MitM attack. If the responder's HI is
retrieved from a signed DNS zone or secured by some other means, the
initiator can use this to authenticate the signed HIP packets.
Likewise, if the initiator's HI is in a secure DNS zone, the
responder can retrieve it and validate the signed HIP packets.
However, since an initiator may choose to use an unpublished HI, it
knowingly risks a MitM attack. The responder may choose not to
accept a HIP exchange with an initiator using an unknown HI.
In HIP, the Security Association for IPsec is indexed by the SPI; the
source address is always ignored, and the destination address may be
ignored as well. Therefore, HIP-enabled IPsec Encapsulated Security
Payload (ESP) is IP address independent. This might seem to make it
easier for an attacker, but ESP with replay protection is already as
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well protected as possible, and the removal of the IP address as a
check should not increase the exposure of IPsec ESP to DoS attacks.
Since not all hosts will ever support HIP, ICMPv4 'Destination
Unreachable, Protocol Unreachable' and ICMPv6 'Parameter Problem,
Unrecognized Next Header' messages are to be expected and present a
DoS attack. Against an initiator, the attack would look like the
responder does not support HIP, but shortly after receiving the ICMP
message, the initiator would receive a valid HIP packet. Thus, to
protect against this attack, an initiator should not react to an ICMP
message until a reasonable time has passed, allowing it to get the
real responder's HIP packet. A similar attack against the responder
is more involved.
Another MitM attack is simulating a responder's administrative
rejection of a HIP initiation. This is a simple ICMP 'Destination
Unreachable, Administratively Prohibited' message. A HIP packet is
not used because it would either have to have unique content, and
thus difficult to generate, resulting in yet another DoS attack, or
just as spoofable as the ICMP message. Like in the previous case,
the defense against this attack is for the initiator to wait a
reasonable time period to get a valid HIP packet. If one does not
come, then the initiator has to assume that the ICMP message is
valid. Since this is the only point in the HIP base exchange where
this ICMP message is appropriate, it can be ignored at any other
point in the exchange.
13.1 HITs used in ACLs
It is expected that HITs will be used in ACLs. Future firewalls can
use HITs to control egress and ingress to networks, with an assurance
level difficult to achieve today. As discussed above in Section 8,
once a HIP session has been established, the SPI value in an IPsec
packet may be used as an index, indicating the HITs. In practice,
firewalls can inspect HIP packets to learn of the bindings between
HITs, SPI values, and IP addresses. They can even explicitly control
IPsec usage, dynamically opening IPsec ESP only for specific SPI
values and IP addresses. The signatures in HIP packets allow a
capable firewall to ensure that the HIP exchange is indeed happening
between two known hosts. This may increase firewall security.
There has been considerable bad experience with distributed ACLs that
contain public key related material, for example, with SSH. If the
owner of a key needs to revoke it for any reason, the task of finding
all locations where the key is held in an ACL may be impossible. If
the reason for the revocation is due to private key theft, this could
be a serious issue.
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A host can keep track of all of its partners that might use its HIT
in an ACL by logging all remote HITs. It should only be necessary to
log responder hosts. With this information, the host can notify the
various hosts about the change to the HIT. There has been no attempt
to develop a secure method to issue the HIT revocation notice.
HIP-aware NATs, however, are transparent to the HIP aware systems by
design. Thus, the host may find it difficult to notify any NAT that
is using a HIT in an ACL. Since most systems will know of the NATs
for their network, there should be a process by which they can notify
these NATs of the change of the HIT. This is mandatory for systems
that function as responders behind a NAT. In a similar vein, if a
host is notified of a change in a HIT of an initiator, it should
notify its NAT of the change. In this manner, NATs will get updated
with the HIT change.
13.2 Non-security considerations
The definition of the Host Identifier states that the HI need not be
a public key. It implies that the HI could be any value; for example
a FQDN. This document does not describe how to support such a
non-cryptographic HI. A non-cryptographic HI would still offer the
services of the HIT or LSI for NAT traversal. It would be possible
to carry HITs in HIP packets that had neither privacy nor
authentication. Since such a mode would offer so little additional
functionality for so much addition to the IP kernel, it has not been
defined. Given how little public key cryptography HIP requires, HIP
should only be implemented using public key Host Identities.
If it is desirable to use HIP in a low security situation where
public key computations are considered expensive, HIP can be used
with very short Diffie-Hellman and Host Identity keys. Such use
makes the participating hosts vulnerable to MitM and connection
hijacking attacks. However, it does not cause flooding dangers,
since the address check mechanism relies on the routing system and
not on cryptographic strength.
14. IANA considerations
This document has no actions for IANA.
15. Acknowledgments
For the people historically involved in the early stages of HIP, see
the Acknowledgements section in the Host Identity Protocol
specification [6].
During the later stages of this document, when the editing baton was
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transfered to Pekka Nikander, the comments from the early
implementors and others, including Jari Arkko, Tom Henderson, Petri
Jokela, Miika Komu, Mika Kousa, Andrew McGregor, Jan Melen, Tim
Shepard, Jukka Ylitalo, and Jorma Wall, were invaluable. Finally,
Lars Eggert, Spencer Dawkins and Dave Crocker provided valuable input
during the final stages of publication, most of which was
incorporated but some of which the authors decided to ignore in order
to get this document published in the first place.
16 Informative references
[1] Vixie, P., Thomson, S., Rekhter, Y. and J. Bound, "Dynamic
Updates in the Domain Name System (DNS UPDATE)", RFC 2136,
April 1997.
[2] Eastlake, D., "Domain Name System Security Extensions", RFC
2535, March 1999.
[3] Tsirtsis, G. and P. Srisuresh, "Network Address Translation -
Protocol Translation (NAT-PT)", RFC 2766, February 2000.
[4] Srisuresh, P. and K. Egevang, "Traditional IP Network Address
Translator (Traditional NAT)", RFC 3022, January 2001.
[5] Borella, M., Lo, J., Grabelsky, D. and G. Montenegro, "Realm
Specific IP: Framework", RFC 3102, October 2001.
[6] Moskowitz, R., "Host Identity Protocol", draft-ietf-hip-base-00
(work in progress), June 2004.
[7] Richardson, M., "A method for storing IPsec keying material in
DNS", draft-ietf-ipseckey-rr-10 (work in progress), April 2004.
[8] Lear, E. and R. Droms, "What's In A Name:Thoughts from the
NSRG", draft-irtf-nsrg-report-10 (work in progress), September
2003.
[9] Nikander, P., "End-Host Mobility and Multi-Homing with Host
Identity Protocol", draft-ietf-hip-mm-00 (work in progress),
October 2004.
[10] Nikander, P., "Mobile IP version 6 Route Optimization Security
Design Background", draft-ietf-mip6-ro-sec-00 (work in
progress), April 2004.
[11] Kaufman, C., "Internet Key Exchange (IKEv2) Protocol",
draft-ietf-ipsec-ikev2-14 (work in progress), June 2004.
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[12] Chiappa, J., "Endpoints and Endpoint Names: A Proposed
Enhancement to the Internet Architecture", URL
http://users.exis.net/~jnc/tech/endpoints.txt, 1999.
[13] Nikander, P., "Denial-of-Service, Address Ownership, and Early
Authentication in the IPv6 World", in Proceesings of Security
Protocols, 9th International Workshop, Cambridge, UK, April
25-27 2001, LNCS 2467, pp. 12-26, Springer, 2002.
[14] Bellovin, S., "EIDs, IPsec, and HostNAT", in Proceedings of
41th IETF, Los Angeles, CA, March 1998.
Authors' Addresses
Robert Moskowitz
ICSAlabs, a Division of TruSecure Corporation
1000 Bent Creek Blvd, Suite 200
Mechanicsburg, PA
USA
EMail: rgm@icsalabs.com
Pekka Nikander
Ericsson Research Nomadic Lab
JORVAS FIN-02420
FINLAND
Phone: +358 9 299 1
EMail: pekka.nikander@nomadiclab.com
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