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IETF RFC 3972
Cryptographically Generated Addresses (CGA)
Last modified on Friday, March 11th, 2005
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Network Working Group T. Aura
Request for Comments: 3972 Microsoft Research
Category: Standards Track March 2005
Cryptographically Generated Addresses (CGA)
Status of This Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
Copyright Notice
Copyright © The Internet Society (2004).
Abstract
This document describes a method for binding a public signature key
to an IPv6 address in the Secure Neighbor Discovery (SEND) protocol.
Cryptographically Generated Addresses (CGA) are IPv6 addresses for
which the interface identifier is generated by computing a
cryptographic one-way hash function from a public key and auxiliary
parameters. The binding between the public key and the address can
be verified by re-computing the hash value and by comparing the hash
with the interface identifier. Messages sent from an IPv6 address
can be protected by attaching the public key and auxiliary parameters
and by signing the message with the corresponding private key. The
protection works without a certification authority or any security
infrastructure.
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RFC 3972 Cryptographically Generated Addresses March 2005
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 2
2. CGA Format . . . . . . . . . . . . . . . . . . . . . . . . . . 3
3. CGA Parameters and Hash Values . . . . . . . . . . . . . . . . 5
4. CGA Generation . . . . . . . . . . . . . . . . . . . . . . . . 6
5. CGA Verification . . . . . . . . . . . . . . . . . . . . . . . 9
6. CGA Signatures . . . . . . . . . . . . . . . . . . . . . . . . 10
7. Security Considerations . . . . . . . . . . . . . . . . . . . 12
7.1. Security Goals and Limitations . . . . . . . . . . . . . 12
7.2. Hash Extension . . . . . . . . . . . . . . . . . . . . . 13
7.3. Privacy Considerations . . . . . . . . . . . . . . . . . 15
7.4. Related Protocols . . . . . . . . . . . . . . . . . . . 15
8. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 16
9. References . . . . . . . . . . . . . . . . . . . . . . . . . . 17
9.1. Normative References . . . . . . . . . . . . . . . . . . 17
9.2. Informative References . . . . . . . . . . . . . . . . . 18
Appendices . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
A. Example of CGA Generation. . . . . . . . . . . . . . . . . 20
B. Acknowledgements . . . . . . . . . . . . . . . . . . . . . 21
Author's Address . . . . . . . . . . . . . . . . . . . . . . . . . 21
Full Copyright Statements. . . . . . . . . . . . . . . . . . . . . 22
1. Introduction
This document specifies a method for securely associating a
cryptographic public key with an IPv6 address in the Secure Neighbor
Discovery (SEND) protocol [RFC 3971]. The basic idea is to generate
the interface identifier (i.e., the rightmost 64 bits) of the IPv6
address by computing a cryptographic hash of the public key. The
resulting IPv6 address is called a cryptographically generated
address (CGA). The corresponding private key can then be used to
sign messages sent from the address. An introduction to CGAs and
their application to SEND can be found in [Aura03] and [AAKMNR02].
This document specifies:
o how to generate a CGA from the cryptographic hash of a public key
and auxiliary parameters,
o how to verify the association between the public key and the CGA,
and
o how to sign a message sent from the CGA, and how to verify the
signature.
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RFC 3972 Cryptographically Generated Addresses March 2005
To verify the association between the address and the public key, the
verifier needs to know the address itself, the public key, and the
values of the auxiliary parameters. The verifier can then go on to
verify messages signed by the owner of the public key (i.e., the
address owner). No additional security infrastructure, such as a
public key infrastructure (PKI), certification authorities, or other
trusted servers, is needed.
Note that because CGAs themselves are not certified, an attacker can
create a new CGA from any subnet prefix and its own (or anyone
else's) public key. However, the attacker cannot take a CGA created
by someone else and send signed messages that appear to come from the
owner of that address.
The address format and the CGA parameter format are defined in
Sections 2 and 3. Detailed algorithms for generating addresses and
for verifying them are given in Sections 4 and 5, respectively.
Section 6 defines the procedures for generating and verifying CGA
signatures. The security considerations in Section 7 include
limitations of CGA-based security, the reasoning behind the hash
extension technique that enables effective hash lengths above the
64-bit limit of the interface identifier, the implications of CGAs on
privacy, and protection against related-protocol attacks.
In this document, the key words MUST, MUST NOT, REQUIRED, SHALL,
SHALL NOT, SHOULD, SHOULD NOT, RECOMMENDED, MAY, and OPTIONAL are to
be interpreted as described in [RFC 2119].
2. CGA Format
When talking about addresses, this document refers to IPv6 addresses
in which the leftmost 64 bits of a 128-bit address form the subnet
prefix and the rightmost 64 bits of the address form the interface
identifier [RFC 3513]. We number the bits of the interface identifier
starting from bit zero on the left.
A cryptographically generated address (CGA) has a security parameter
(Sec) that determines its strength against brute-force attacks. The
security parameter is a three-bit unsigned integer, and it is encoded
in the three leftmost bits (i.e., bits 0 - 2) of the interface
identifier. This can be written as follows:
Sec = (interface identifier & 0xe000000000000000) >> 61
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RFC 3972 Cryptographically Generated Addresses March 2005
The CGA is associated with a set of parameters that consist of a
public key and auxiliary parameters. Two hash values Hash1 (64 bits)
and Hash2 (112 bits) are computed from the parameters. The formats
of the public key and auxiliary parameters, and the way to compute
the hash values, are defined in Section 3.
A cryptographically generated address is defined as an IPv6 address
that satisfies the following two conditions:
o The first hash value, Hash1, equals the interface identifier of
the address. Bits 0, 1, 2, 6, and 7 (i.e., the bits that encode
the security parameter Sec and the "u" and "g" bits from the
standard IPv6 address architecture format of interface identifiers
[RFC 3513]) are ignored in the comparison.
o The 16*Sec leftmost bits of the second hash value, Hash2, are
zero.
The above definition can be stated in terms of the following two bit
masks:
Mask1 (64 bits) = 0x1cffffffffffffff
Mask2 (112 bits) = 0x0000000000000000000000000000 if Sec=0,
0xffff000000000000000000000000 if Sec=1,
0xffffffff00000000000000000000 if Sec=2,
0xffffffffffff0000000000000000 if Sec=3,
0xffffffffffffffff000000000000 if Sec=4,
0xffffffffffffffffffff00000000 if Sec=5,
0xffffffffffffffffffffffff0000 if Sec=6, and
0xffffffffffffffffffffffffffff if Sec=7
A cryptographically generated address is an IPv6 address for which
the following two equations hold:
Hash1 & Mask1 == interface identifier & Mask1
Hash2 & Mask2 == 0x0000000000000000000000000000
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3. CGA Parameters and Hash Values
Each CGA is associated with a CGA Parameters data structure, which
has the following format:
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
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ +
| |
+ Modifier (16 octets) +
| |
+ +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
+ Subnet Prefix (8 octets) +
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
|Collision Count| |
+-+-+-+-+-+-+-+-+ |
| |
~ Public Key (variable length) ~
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| |
~ Extension Fields (optional, variable length) ~
| |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Modifier
This field contains a 128-bit unsigned integer, which can be any
value. The modifier is used during CGA generation to implement
the hash extension and to enhance privacy by adding randomness to
the address.
Subnet Prefix
This field contains the 64-bit subnet prefix of the CGA.
Collision Count
This is an eight-bit unsigned integer that MUST be 0, 1, or 2.
The collision count is incremented during CGA generation to
recover from an address collision detected by duplicate address
detection.
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Public Key
This is a variable-length field containing the public key of the
address owner. The public key MUST be formatted as a DER-encoded
[ITU.X690.2002] ASN.1 structure of the type SubjectPublicKeyInfo,
defined in the Internet X.509 certificate profile [RFC 3280]. SEND
SHOULD use an RSA public/private key pair. When RSA is used, the
algorithm identifier MUST be rsaEncryption, which is
1.2.840.113549.1.1.1, and the RSA public key MUST be formatted by
using the RSAPublicKey type as specified in Section 2.3.1 of RFC
3279 [RFC 3279]. The RSA key length SHOULD be at least 384 bits.
Other public key types are undesirable in SEND, as they may result
in incompatibilities between implementations. The length of this
field is determined by the ASN.1 encoding.
Extension Fields
This is an optional variable-length field that is not used in the
current specification. Future versions of this specification may
use this field for additional data items that need to be included
in the CGA Parameters data structure. IETF standards action is
required to specify the use of the extension fields.
Implementations MUST ignore the value of any unrecognized
extension fields.
The two hash values MUST be computed as follows. The SHA-1 hash
algorithm [FIPS.180-1.1995] is applied to the CGA Parameters. When
Hash1 is computed, the input to the SHA-1 algorithm is the CGA
Parameters data structure. The 64-bit Hash1 is obtained by taking
the leftmost 64 bits of the 160-bit SHA-1 hash value. When Hash2 is
computed, the input is the same CGA Parameters data structure except
that the subnet prefix and collision count are set to zero. The
112-bit Hash2 is obtained by taking the leftmost 112 bits of the
160-bit SHA-1 hash value. Note that the hash values are computed
over the entire CGA Parameters data structure, including any
unrecognized extension fields.
4. CGA Generation
The process of generating a new CGA takes three input values: a
64-bit subnet prefix, the public key of the address owner as a
DER-encoded ASN.1 structure of the type SubjectPublicKeyInfo, and the
security parameter Sec, which is an unsigned three-bit integer. The
cost of generating a new CGA depends exponentially on the security
parameter Sec, which can have values from 0 to 7.
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A CGA and associated parameters SHOULD be generated as follows:
1. Set the modifier to a random or pseudo-random 128-bit value.
2. Concatenate from left to right the modifier, 9 zero octets, the
encoded public key, and any optional extension fields. Execute
the SHA-1 algorithm on the concatenation. Take the 112 leftmost
bits of the SHA-1 hash value. The result is Hash2.
3. Compare the 16*Sec leftmost bits of Hash2 with zero. If they are
all zero (or if Sec=0), continue with step 4. Otherwise,
increment the modifier by one and go back to step 2.
4. Set the 8-bit collision count to zero.
5. Concatenate from left to right the final modifier value, the
subnet prefix, the collision count, the encoded public key, and
any optional extension fields. Execute the SHA-1 algorithm on the
concatenation. Take the 64 leftmost bits of the SHA-1 hash value.
The result is Hash1.
6. Form an interface identifier from Hash1 by writing the value of
Sec into the three leftmost bits and by setting bits 6 and 7
(i.e., the "u" and "g" bits) to zero.
7. Concatenate the 64-bit subnet prefix and the 64-bit interface
identifier to form a 128-bit IPv6 address with the subnet prefix
to the left and interface identifier to the right, as in a
standard IPv6 address [RFC 3513].
8. Perform duplicate address detection if required, as per [RFC 3971].
If an address collision is detected, increment the collision count
by one and go back to step 5. However, after three collisions,
stop and report the error.
9. Form the CGA Parameters data structure by concatenating from left
to right the final modifier value, the subnet prefix, the final
collision count value, the encoded public key, and any optional
extension fields.
The output of the address generation algorithm is a new CGA and a CGA
Parameters data structure.
The initial value of the modifier in step 1 SHOULD be chosen randomly
to make addresses generated from the same public key unlinkable,
which enhances privacy (see Section 7.3). The quality of the random
number generator does not affect the strength of the binding between
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the address and the public key. Implementations that have no strong
random numbers available MAY use a non-cryptographic pseudo-random
number generator initialized with the current time of day.
For Sec=0, the above algorithm is deterministic and relatively fast.
Nodes that implement CGA generation MAY always use the security
parameter value Sec=0. If Sec=0, steps 2 - 3 of the generation
algorithm can be skipped.
For Sec values greater than zero, the above algorithm is not
guaranteed to terminate after a certain number of iterations. The
brute-force search in steps 2 - 3 takes O(2^(16*Sec)) iterations to
complete. The algorithm has been intentionally designed so that the
generation of CGAs with high Sec values is infeasible with current
technology.
Implementations MAY use optimized or otherwise modified versions of
the above algorithm for CGA generation. However, the output of any
modified versions MUST fulfill the following two requirements.
First, the resulting CGA and CGA Parameters data structure MUST be
formatted as specified in Sections 2 - 3. Second, the CGA
verification procedure defined in Section 5 MUST succeed when invoked
on the output of the CGA generation algorithm. Note that some
optimizations involve trade-offs between privacy and the cost of
address generation.
One optimization is particularly important. If the subnet prefix of
the address changes but the address owner's public key does not, the
old modifier value MAY be reused. If it is reused, the algorithm
SHOULD be started from step 4. This optimization avoids repeating
the expensive search for an acceptable modifier value but may, in
some situations, make it easier for an observer to link two addresses
to each other.
Note that this document does not specify whether duplicate address
detection should be performed and how the detection is done. Step 8
only defines what to do if some form of duplicate address detection
is performed and an address collision is detected.
Future versions of this specification may specify additional inputs
to the CGA generation algorithm that are concatenated as extension
fields to the end of the CGA Parameters data structure. No such
extension fields are defined in this document.
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5. CGA Verification
CGA verification takes an IPv6 address and a CGA Parameters data
structure as input. The CGA Parameters consist of the concatenated
modifier, subnet prefix, collision count, public key, and optional
extension fields. The verification either succeeds or fails.
The CGA MUST be verified with the following steps:
1. Check that the collision count in the CGA Parameters data
structure is 0, 1, or 2. The CGA verification fails if the
collision count is out of the valid range.
2. Check that the subnet prefix in the CGA Parameters data structure
is equal to the subnet prefix (i.e., the leftmost 64 bits) of the
address. The CGA verification fails if the prefix values differ.
3. Execute the SHA-1 algorithm on the CGA Parameters data structure.
Take the 64 leftmost bits of the SHA-1 hash value. The result is
Hash1.
4. Compare Hash1 with the interface identifier (i.e., the rightmost
64 bits) of the address. Differences in the three leftmost bits
and in bits 6 and 7 (i.e., the "u" and "g" bits) are ignored. If
the 64-bit values differ (other than in the five ignored bits),
the CGA verification fails.
5. Read the security parameter Sec from the three leftmost bits of
the 64-bit interface identifier of the address. (Sec is an
unsigned 3-bit integer.)
6. Concatenate from left to right the modifier, 9 zero octets, the
public key, and any extension fields that follow the public key in
the CGA Parameters data structure. Execute the SHA-1 algorithm on
the concatenation. Take the 112 leftmost bits of the SHA-1 hash
value. The result is Hash2.
7. Compare the 16*Sec leftmost bits of Hash2 with zero. If any one
of them is not zero, the CGA verification fails. Otherwise, the
verification succeeds. (If Sec=0, the CGA verification never
fails at this step.)
If the verification fails at any step, the execution of the algorithm
MUST be stopped immediately. On the other hand, if the verification
succeeds, the verifier knows that the public key in the CGA
Parameters is the authentic public key of the address owner. The
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verifier can extract the public key by removing 25 octets from the
beginning of the CGA Parameters and by decoding the following
SubjectPublicKeyInfo data structure.
Note that the values of bits 6 and 7 (the "u" and "g" bits) of the
interface identifier are ignored during CGA verification. In the
SEND protocol, after the verification succeeds, the verifier SHOULD
process all CGAs in the same way regardless of the Sec, modifier, and
collision count values. In particular, the verifier in the SEND
protocol SHOULD NOT have any security policy that differentiates
between addresses based on the value of Sec. That way, the address
generator is free to choose any value of Sec.
All nodes that implement CGA verification MUST be able to process all
security parameter values Sec = 0, 1, 2, 3, 4, 5, 6, 7. The
verification procedure is relatively fast and always requires at most
two computations of the SHA-1 hash function. If Sec=0, the
verification never fails in steps 6 - 7 and these steps can be
skipped.
Nodes that implement CGA verification for SEND SHOULD be able to
process RSA public keys that have the algorithm identifier
rsaEncryption and, key length between 384 and 2,048 bits.
Implementations MAY support longer keys. Future versions of this
specification may recommend support for longer keys.
Implementations of CGA verification MUST ignore the value of any
unrecognized extension fields that follow the public key in the CGA
Parameters data structure. However, implementations MUST include any
such unrecognized data in the hash input when computing Hash1 in step
3 and Hash2 in step 6 of the CGA verification algorithm. This is
important to ensure upward compatibility with future extensions.
6. CGA Signatures
This section defines the procedures for generating and verifying CGA
signatures. To sign a message, a node needs the CGA, the associated
CGA Parameters data structure, the message, and the private
cryptographic key that corresponds to the public key in the CGA
Parameters. The node also must have a 128-bit type tag for the
message from the CGA Message Type name space.
To sign a message, a node SHOULD do the following:
o Concatenate the 128-bit type tag (in network byte order) and the
message with the type tag to the left and the message to the
right. The concatenation is the message to be signed in the next
step.
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RFC 3972 Cryptographically Generated Addresses March 2005
o Generate the RSA signature by using the RSASSA-PKCS1-v1_5
[RFC 3447] signature algorithm with the SHA-1 hash algorithm. The
private key and the concatenation created above are the inputs to
the generation operation.
The SEND protocol specification [RFC 3971] defines several messages
that contain a signature in the Signature Option. The SEND protocol
specification also defines a type tag from the CGA Message Type name
space. The same type tag is used for all the SEND messages that have
the Signature Option. This type tag is an IANA-allocated 128 bit
integer that has been chosen at random to prevent an accidental type
collision with messages of other protocols that use the same public
key but that may or may not use IANA-allocated type tags.
The CGA, the CGA Parameters data structure, the message, and the
signature are sent to the verifier. The SEND protocol specification
defines how these data items are sent in SEND protocol messages.
Note that the 128-bit type tag is not included in the SEND protocol
messages because the verifier knows its value implicitly from the
ICMP message type field in the SEND message. See the SEND
specification [RFC 3971] for precise information about how SEND
handles the type tag.
To verify a signature, the verifier needs the CGA, the associated CGA
Parameters data structure, the message, and the signature. The
verifier also needs to have the 128-bit type tag for the message.
To verify the signature, a node SHOULD do the following:
o Verify the CGA as defined in Section 5. The inputs to the CGA
verification are the CGA and the CGA Parameters data structure.
o Concatenate the 128-bit type tag and the message with the type tag
to the left and the message to the right. The concatenation is
the message whose signature is to be verified in the next step.
o Verify the RSA signature by using the RSASSA-PKCS1-v1_5 [RFC 3447]
algorithm with the SHA-1 hash algorithm. The inputs to the
verification operation are the public key (i.e., the RSAPublicKey
structure from the SubjectPublicKeyInfo structure that is a part
of the CGA Parameters data structure), the concatenation created
above, and the signature.
The verifier MUST accept the signature as authentic only if both the
CGA verification and the signature verification succeed.
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7. Security Considerations
7.1. Security Goals and Limitations
The purpose of CGAs is to prevent stealing and spoofing of existing
IPv6 addresses. The public key of the address owner is bound
cryptographically to the address. The address owner can use the
corresponding private key to assert its ownership and to sign SEND
messages sent from the address.
It is important to understand that an attacker can create a new
address from an arbitrary subnet prefix and its own (or someone
else's) public key because CGAs are not certified. However, the
attacker cannot impersonate somebody else's address. This is because
the attacker would have to find a collision of the cryptographic hash
value Hash1. (The property of the hash function needed here is
called second pre-image resistance [MOV97].)
For each valid CGA Parameters data structure, there are 4*(Sec+1)
different CGAs that match the value. This is because decrementing
the Sec value in the three leftmost bits of the interface identifier
does not invalidate the address, and the verifier ignores the values
of the "u" and "g" bits. In SEND, this does not have any security or
implementation implications.
Another limitation of CGAs is that there is no mechanism for proving
that an address is not a CGA. Thus, an attacker could take someone
else's CGA and present it as a non-cryptographically generated
address (e.g., as an RFC 3041 address [RFC 3041]). An attacker does
not benefit from this because although SEND nodes accept both signed
and unsigned messages from every address, they give priority to the
information in the signed messages.
The minimum RSA key length required for SEND is only 384 bits. So
short keys are vulnerable to integer-factoring attacks and cannot be
used for strong authentication or secrecy. On the other hand, the
cost of factoring 384-bit keys is currently high enough to prevent
most denial-of-service attacks. Implementations that initially use
short RSA keys SHOULD be prepared to switch to longer keys when
denial-of-service attacks arising from integer factoring become a
problem.
The impact of a key compromise on CGAs depends on the application for
which they are used. In SEND, it is not a major concern. If the
private signature key is compromised because the SEND node has itself
been compromised, the attacker does not need to spoof SEND messages
from the node. When it is discovered that a node has been
compromised, a new signature key and a new CGA SHOULD be generated.
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On the other hand, if the RSA key is compromised because integer-
factoring attacks for the chosen key length have become practical,
the key has to be replaced with a longer one, as explained above. In
either case, the address change effectively revokes the old public
key. It is not necessary to have any additional key revocation
mechanism or to limit the lifetimes of the signature keys.
7.2. Hash Extension
As computers become faster, the 64 bits of the interface identifier
will not be sufficient to prevent attackers from searching for hash
collisions. It helps somewhat that we include the subnet prefix of
the address in the hash input. This prevents the attacker from using
a single pre-computed database to attack addresses with different
subnet prefixes. The attacker needs to create a separate database
for each subnet prefix. Link-local addresses are, however, left
vulnerable because the same prefix is used by all IPv6 nodes.
To prevent the CGA technology from becoming outdated as computers
become faster, the hash technique used to generate CGAs must be
extended somehow. The chosen extension technique is to increase the
cost of both address generation and brute-force attacks by the same
parameterized factor while keeping the cost of address use and
verification constant. This also provides protection for link-local
addresses. Introduction of the hash extension is the main difference
between this document and earlier CGA proposals [OR01][Nik01][MC02].
To achieve the effective extension of the hash length, the input to
the second hash function, Hash2, is modified (by changing the
modifier value) until the leftmost 16*Sec bits of the hash value are
zero. This increases the cost of address generation approximately by
a factor of 2^(16*Sec). It also increases the cost of brute-force
attacks by the same factor. That is, the cost of creating a CGA
Parameters data structure that binds the attacker's public key with
somebody else's address is increased from O(2^59) to
O(2^(59+16*Sec)). The address generator may choose the security
parameter Sec depending on its own computational capacity, the
perceived risk of attacks, and the expected lifetime of the address.
Currently, Sec values between 0 and 2 are sufficient for most IPv6
nodes. As computers become faster, higher Sec values will slowly
become useful.
Theoretically, if no hash extension is used (i.e., Sec=0) and a
typical attacker is able to tap into N local networks at the same
time, an attack against link-local addresses is N times as efficient
as an attack against addresses of a specific network. The effect
could be countered by using a slightly higher Sec value for link-
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local addresses. When higher Sec values (such that 2^(16*Sec) > N)
are used for all addresses, the relative advantage of attacking
link-local addresses becomes insignificant.
The effectiveness of the hash extension depends on the assumption
that the computational capacities of the attacker and the address
generator will grow at the same (potentially exponential) rate. This
is not necessarily true if the addresses are generated on low-end
mobile devices, for which the main design goals are to lower cost and
decrease size, rather than increase computing power. But there is no
reason for doing so. The expensive part of the address generation
(steps 1 - 3 of the generation algorithm) may be delegated to a more
powerful computer. Moreover, this work can be done in advance or
offline, rather than in real time, when a new address is needed.
To make it possible for mobile nodes whose subnet prefixes change
frequently to use Sec values greater than zero, we have decided not
to include the subnet prefix in the input of Hash2. The result is
weaker than it would be if the subnet prefix were included in the
input of both hashes. On the other hand, our scheme is at least as
strong as using the hash extension technique without including the
subnet prefix in either hash. It is also at least as strong as not
using the hash extension but including the subnet prefix. This
trade-off was made because mobile nodes frequently move to insecure
networks, where they are at the risk of denial-of-service (DoS)
attacks (for example, during the duplicate address detection
procedure).
In most networks, the goal of Secure Neighbor Discovery and CGA
signatures is to prevent denial-of-service attacks. Therefore, it is
usually sensible to start by using a low Sec value and to replace
addresses with stronger ones only when denial-of-service attacks
based on brute-force search become a significant problem. If CGAs
were used as a part of a strong authentication or secrecy mechanism,
it might be necessary to start with higher Sec values.
The collision count value is used to modify the input to Hash1 if
there is an address collision. It is important not to allow
collision count values higher than 2. First, it is extremely
unlikely that three collisions would occur and the reason is certain
to be either a configuration or implementation error or a denial-of-
service attack. (When the SEND protocol is used, deliberate
collisions caused by a DoS attacker are detected and ignored.)
Second, an attacker doing a brute-force search to match a given CGA
can try all different values of a collision count without repeating
the brute-force search for the modifier value. Thus, if higher
values are allowed for the collision count, the hash extension
technique becomes less effective in preventing brute force attacks.
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7.3. Privacy Considerations
CGAs can give the same level of pseudonymity as the IPv6 address
privacy extensions defined in RFC 3041 [RFC 3041]. An IP host can
generate multiple pseudo-random CGAs by executing the CGA generation
algorithm of Section 4 multiple times and by using a different random
or pseudo-random initial value for the modifier every time. The host
should change its address periodically as in [RFC 3041]. When privacy
protection is needed, the (pseudo)random number generator used in
address generation SHOULD be strong enough to produce unpredictable
and unlinkable values. Advice on random number generation can be
found in [RFC 1750].
There are two apparent limitations to this privacy protection.
However, as will be explained below, neither is very serious.
First, the high cost of address generation may prevent hosts that use
a high Sec value from changing their address frequently. This
problem is mitigated because the expensive part of the address
generation may be done in advance or offline, as explained in the
previous section. It should also be noted that the nodes that
benefit most from high Sec values (e.g., DNS servers, routers, and
data servers) usually do not require pseudonymity, and the nodes that
have high privacy requirements (e.g., client PCs and mobile hosts)
are unlikely targets for expensive brute-force DoS attacks and can
make do with lower Sec values.
Second, the public key of the address owner is revealed in the signed
SEND messages. This means that if the address owner wants to be
pseudonymous toward the nodes in the local links that it accesses, it
should generate not only a new address but also a new public key.
With typical local-link technologies, however, a node's link-layer
address is a unique identifier for the node. As long as the node
keeps using the same link-layer address, it makes little sense to
change the public key for privacy reasons.
7.4. Related Protocols
Although this document defines CGAs only for the purposes of Secure
Neighbor Discovery, other protocols could be defined elsewhere that
use the same addresses and public keys. This raises the possibility
of related-protocol attacks in which a signed message from one
protocol is replayed in another protocol. This means that other
protocols (perhaps even those designed without an intimate knowledge
of SEND) could endanger the security of SEND. What makes this threat
even more significant is that the attacker could create a CGA from
someone else's public key and then replay signed messages from a
protocol that has nothing to do with CGAs or IP addresses.
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RFC 3972 Cryptographically Generated Addresses March 2005
To prevent the related-protocol attacks, a type tag is prepended to
every message before it is signed. The type tags are 128-bit
randomly chosen values, which prevents accidental type collisions
with even poorly designed protocols that do not use any type tags.
Moreover, the SEND protocol includes the sender's CGA address in all
signed messages. This makes it even more difficult for an attacker
to take signed messages from some other context and to replay them as
SEND messages.
Finally, a strong cautionary note has to be made about using CGA
signatures for purposes other than SEND. First, the other protocols
MUST include a type tag and the sender address in all signed messages
in the same way that SEND does. Each protocol MUST define its own
type tag values as explained in Section 8. Moreover, because of the
possibility of related-protocol attacks, the public key MUST be used
only for signing, and it MUST NOT be used for encryption. Second,
the minimum RSA key length of 384 bits may be too short for many
applications and the impact of key compromise on the particular
protocol must be evaluated. Third, CGA-based authorization is
particularly suitable for securing neighbor discovery [RFC 2461] and
duplicate address detection [RFC 2462] because these are network-layer
signaling protocols for which IPv6 addresses are natural endpoint
identifiers. In any protocol that uses other identifiers, such as
DNS names, CGA signatures alone are not a sufficient security
mechanism. There must also be a secure way of mapping the other
identifiers to IPv6 addresses. If the goal is not to verify claims
about IPv6 addresses, CGA signatures are probably not the right
solution.
8. IANA Considerations
This document defines a new CGA Message Type name space for use as
type tags in messages that may be signed by using CGA signatures.
The values in this name space are 128-bit unsigned integers. Values
in this name space are allocated on a First Come First Served basis
[RFC 2434]. IANA assigns new 128-bit values directly without a
review.
The requester SHOULD generate the new values with a strong random-
number generator. Continuous ranges of at most 256 values can be
requested provided that the 120 most significant bits of the values
have been generated with a strong random-number generator.
IANA does not generate random values for the requester. IANA
allocates requested values without verifying the way in which they
have been generated. The name space is essentially unlimited, and
any number of individual values and ranges of at most 256 values can
be allocated.
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RFC 3972 Cryptographically Generated Addresses March 2005
CGA Message Type values for private use MAY be generated with a
strong random-number generator without IANA allocation.
This document does not define any new values in any name space.
9. References
9.1. Normative References
[RFC 3971] Arkko, J., Ed., Kempf, J., Sommerfeld, B., Zill,
B., and P. Nikander, "SEcure Neighbor Discovery
(SEND)", RFC 3971, March 2005.
[RFC 3279] Bassham, L., Polk, W., and R. Housley, "Algorithms
and Identifiers for the Internet X.509 Public Key
Infrastructure Certificate and Certificate
Revocation List (CRL) Profile", RFC 3279, April
2002.
[RFC 2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC 3513] Hinden, R. and S. Deering, "Internet Protocol
Version 6 (IPv6) Addressing Architecture", RFC
3513, April 2003.
[RFC 3280] Housley, R., Polk, W., Ford, W., and D. Solo,
"Internet X.509 Public Key Infrastructure
Certificate and Certificate Revocation List (CRL)
Profile", RFC 3280, April 2002.
[ITU.X690.2002] International Telecommunications Union,
"Information Technology - ASN.1 encoding rules:
Specification of Basic Encoding Rules (BER),
Canonical Encoding Rules (CER) and Distinguished
Encoding Rules (DER)", ITU-T Recommendation X.690,
July 2002.
[RFC 3447] Jonsson, J. and B. Kaliski, "Public-Key
Cryptography Standards (PKCS) #1: RSA Cryptography
Specifications Version 2.1", RFC 3447, February
2003.
[RFC 2434] Narten, T. and H. Alvestrand, "Guidelines for
Writing an IANA Considerations Section in RFCs",
BCP 26, RFC 2434, October 1998.
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RFC 3972 Cryptographically Generated Addresses March 2005
[FIPS.180-1.1995] National Institute of Standards and Technology,
"Secure Hash Standard", Federal Information
Processing Standards Publication FIPS PUB 180-1,
April 1995,
<http://www.itl.nist.gov/fipspubs/fip180-1.htm>.
9.2. Informative References
[AAKMNR02] Arkko, J., Aura, T., Kempf, J., Mantyla, V.,
Nikander, P., and M. Roe, "Securing IPv6 neighbor
discovery and router discovery", ACM Workshop on
Wireless Security (WiSe 2002), Atlanta, GA USA ,
September 2002.
[Aura03] Aura, T., "Cryptographically Generated Addresses
(CGA)", 6th Information Security Conference
(ISC'03), Bristol, UK, October 2003.
[RFC 1750] Eastlake, D., Crocker, S., and J. Schiller,
"Randomness Recommendations for Security", RFC
1750, December 1994.
[MOV97] Menezes, A., van Oorschot, P., and S. Vanstone,
"Handbook of Applied Cryptography", CRC Press ,
1997.
[MC02] Montenegro, G. and C. Castelluccia, "Statistically
unique and cryptographically verifiable identifiers
and addresses", ISOC Symposium on Network and
Distributed System Security (NDSS 2002), San Diego,
CA USA , February 2002.
[RFC 3041] Narten, T. and R. Draves, "Privacy Extensions for
Stateless Address Autoconfiguration in IPv6", RFC
3041, January 2001.
[RFC 2461] Narten, T., Nordmark, E., and W. Simpson, "Neighbor
Discovery for IP Version 6 (IPv6)", RFC 2461,
December 1998.
[Nik01] Nikander, P., "A scaleable architecture for IPv6
address ownership", draft-nikander-addr-ownership-
00 (work in progress), March 2001.
[OR01] O'Shea, G. and M. Roe, "Child-proof authentication
for MIPv6 (CAM)", ACM Computer Communications
Review 31(2), April 2001.
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RFC 3972 Cryptographically Generated Addresses March 2005
[RFC 2462] Thomson, S. and T. Narten, "IPv6 Stateless Address
Autoconfiguration", RFC 2462, December 1998.
Aura Standards Track PAGE 19
RFC 3972 Cryptographically Generated Addresses March 2005
Appendix A. Example of CGA Generation
We generate a CGA with Sec=1 from the subnet prefix fe80:: and the
following public key:
305c 300d 0609 2a86 4886 f70d 0101 0105 0003 4b00 3048 0241
00c2 c2f1 3730 5454 f10b d9ce a368 44b5 30e9 211a 4b26 2b16
467c b7df ba1f 595c 0194 f275 be5a 4d38 6f2c 3c23 8250 8773
c786 7f9b 3b9e 63a0 9c7b c48f 7a54 ebef af02 0301 0001
The modifier is initialized to a random value 89a8 a8b2 e858 d8b8
f263 3f44 d2d4 ce9a. The input to Hash2 is:
89a8 a8b2 e858 d8b8 f263 3f44 d2d4 ce9a 0000 0000 0000 0000 00
305c 300d 0609 2a86 4886 f70d 0101 0105 0003 4b00 3048 0241
00c2 c2f1 3730 5454 f10b d9ce a368 44b5 30e9 211a 4b26 2b16
467c b7df ba1f 595c 0194 f275 be5a 4d38 6f2c 3c23 8250 8773
c786 7f9b 3b9e 63a0 9c7b c48f 7a54 ebef af02 0301 0001
The 112 first bits of the SHA-1 hash value computed from the above
input are Hash2=436b 9a70 dbfd dbf1 926e 6e66 29c0. This does not
begin with 16*Sec=16 zero bits. Thus, we must increment the modifier
by one and recompute the hash. The new input to Hash2 is:
89a8 a8b2 e858 d8b8 f263 3f44 d2d4 ce9b 0000 0000 0000 0000 00
305c 300d 0609 2a86 4886 f70d 0101 0105 0003 4b00 3048 0241
00c2 c2f1 3730 5454 f10b d9ce a368 44b5 30e9 211a 4b26 2b16
467c b7df ba1f 595c 0194 f275 be5a 4d38 6f2c 3c23 8250 8773
c786 7f9b 3b9e 63a0 9c7b c48f 7a54 ebef af02 0301 0001
The new hash value is Hash2=0000 01ca 680b 8388 8d09 12df fcce. The
16 leftmost bits of Hash2 are all zero. Thus, we found a suitable
modifier. (We were very lucky to find it so soon.)
The input to Hash1 is:
89a8 a8b2 e858 d8b8 f263 3f44 d2d4 ce9b fe80 0000 0000 0000 00
305c 300d 0609 2a86 4886 f70d 0101 0105 0003 4b00 3048 0241
00c2 c2f1 3730 5454 f10b d9ce a368 44b5 30e9 211a 4b26 2b16
467c b7df ba1f 595c 0194 f275 be5a 4d38 6f2c 3c23 8250 8773
c786 7f9b 3b9e 63a0 9c7b c48f 7a54 ebef af02 0301 0001
The 64 first bits of the SHA-1 hash value of the above input are
Hash1=fd4a 5bf6 ffb4 ca6c. We form an interface identifier from this
by writing Sec=1 into the three leftmost bits and by setting bits 6
and 7 (the "u" and "g" bits) to zero. The new interface identifier
is 3c4a:5bf6:ffb4:ca6c.
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RFC 3972 Cryptographically Generated Addresses March 2005
Finally, we form the IPv6 address fe80::3c4a:5bf6:ffb4:ca6c. This is
the new CGA. No address collisions were detected this time.
(Collisions are very rare.) The CGA Parameters data structure
associated with the address is the same as the input to Hash1 above.
Appendix B. Acknowledgements
The author gratefully acknowledges the contributions of Jari Arkko,
Francis Dupont, Pasi Eronen, Christian Huitema, James Kempf, Pekka
Nikander, Michael Roe, Dave Thaler, and other participants of the
SEND working group.
Author's Address
Tuomas Aura
Microsoft Research
Roger Needham Building
7 JJ Thomson Avenue
Cambridge CB3 0FB
United Kingdom
Phone: +44 1223 479708
EMail: tuomaura@microsoft.com
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RFC 3972 Cryptographically Generated Addresses March 2005
Full Copyright Statement
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Cryptographically Generated Addresses (CGA)
RFC TOTAL SIZE: 51473 bytes
PUBLICATION DATE: Friday, March 11th, 2005
LEGAL RIGHTS: The IETF Trust (see BCP 78)
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