Crypto Forum E. Lundberg, Ed.
Internet-Draft J. Bradley
Intended status: Informational Yubico
Expires: 29 November 2024 28 May 2024
The Asynchronous Remote Key Generation (ARKG) algorithm
draft-bradleylundberg-cfrg-arkg-02
Abstract
Asynchronous Remote Key Generation (ARKG) is an abstract algorithm
that enables delegation of asymmetric public key generation without
giving access to the corresponding private keys. This capability
enables a variety of applications: a user agent can generate
pseudonymous public keys to prevent tracking; a message sender can
generate ephemeral recipient public keys to enhance forward secrecy;
two paired authentication devices can each have their own private
keys while each can register public keys on behalf of the other.
This document provides three main contributions: a specification of
the generic ARKG algorithm using abstract primitives; a set of
formulae for instantiating the abstract primitives using concrete
primitives; and an initial set of fully specified concrete ARKG
instances. We expect that additional instances will be defined in
the future.
About This Document
This note is to be removed before publishing as an RFC.
Status information for this document may be found at
https://datatracker.ietf.org/doc/draft-bradleylundberg-cfrg-arkg/.
Source for this draft and an issue tracker can be found at
https://github.com/Yubico/arkg-rfc.
Status of This Memo
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provisions of BCP 78 and BCP 79.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Requirements Language . . . . . . . . . . . . . . . . . . 5
1.2. Notation . . . . . . . . . . . . . . . . . . . . . . . . 5
2. The Asynchronous Remote Key Generation (ARKG) algorithm . . . 5
2.1. Instance parameters . . . . . . . . . . . . . . . . . . . 5
2.2. The function ARKG-Generate-Seed . . . . . . . . . . . . . 7
2.2.1. Deterministic key generation . . . . . . . . . . . . 8
2.3. The function ARKG-Derive-Public-Key . . . . . . . . . . . 8
2.4. The function ARKG-Derive-Private-Key . . . . . . . . . . 9
3. Generic ARKG instantiations . . . . . . . . . . . . . . . . . 10
3.1. Using elliptic curve addition for key blinding . . . . . 10
3.2. Using HMAC to adapt a KEM without integrity protection . 12
3.3. Using ECDH as the KEM . . . . . . . . . . . . . . . . . . 14
3.4. Using X25519 or X448 as the KEM . . . . . . . . . . . . . 16
3.5. Using the same key for both key blinding and KEM . . . . 17
4. Concrete ARKG instantiations . . . . . . . . . . . . . . . . 17
4.1. ARKG-P256ADD-ECDH . . . . . . . . . . . . . . . . . . . . 17
4.2. ARKG-P384ADD-ECDH . . . . . . . . . . . . . . . . . . . . 18
4.3. ARKG-P521ADD-ECDH . . . . . . . . . . . . . . . . . . . . 18
4.4. ARKG-P256kADD-ECDH . . . . . . . . . . . . . . . . . . . 19
4.5. ARKG-curve25519ADD-X25519 . . . . . . . . . . . . . . . . 19
4.6. ARKG-curve448ADD-X448 . . . . . . . . . . . . . . . . . . 20
4.7. ARKG-edwards25519ADD-X25519 . . . . . . . . . . . . . . . 21
4.8. ARKG-edwards448ADD-X448 . . . . . . . . . . . . . . . . . 22
5. COSE bindings . . . . . . . . . . . . . . . . . . . . . . . . 23
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5.1. COSE key type: ARKG public seed . . . . . . . . . . . . . 23
5.2. COSE key reference types . . . . . . . . . . . . . . . . 24
6. Security Considerations . . . . . . . . . . . . . . . . . . . 25
7. Privacy Considerations . . . . . . . . . . . . . . . . . . . 25
8. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 25
8.1. COSE Key Types Registrations . . . . . . . . . . . . . . 25
8.2. COSE Key Type Parameters Registrations . . . . . . . . . 26
8.3. COSE Algorithms Registrations . . . . . . . . . . . . . . 27
9. Design rationale . . . . . . . . . . . . . . . . . . . . . . 29
9.1. Using a MAC . . . . . . . . . . . . . . . . . . . . . . . 29
9.2. Implementation Status . . . . . . . . . . . . . . . . . . 30
10. References . . . . . . . . . . . . . . . . . . . . . . . . . 30
10.1. Normative References . . . . . . . . . . . . . . . . . . 30
10.2. Informative References . . . . . . . . . . . . . . . . . 31
Appendix A. Acknowledgements . . . . . . . . . . . . . . . . . . 32
Appendix B. Test Vectors . . . . . . . . . . . . . . . . . . . . 33
Appendix C. Document History . . . . . . . . . . . . . . . . . . 33
Contributors . . . . . . . . . . . . . . . . . . . . . . . . . . 33
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 33
1. Introduction
Asynchronous Remote Key Generation (ARKG) introduces a mechanism to
generate public keys without access to the corresponding private
keys. Such a mechanism is useful for many scenarios when a new
public key is needed but the private key holder is not available to
perform the key generation. This may occur when private keys are
stored in a hardware security device, which may be unavailable or
locked at the time a new public key is needed.
Some motivating use cases of ARKG include:
* *Single-use asymmetric keys*: Envisioned for the European Union's
digital identity framework, which is set to use single-use
asymmetric keys to prevent colluding verifiers from using public
keys as correlation handles. Each digital identity credential
would thus be issued with a single-use proof-of-possession key,
used only once to present the credential to a verifier. ARKG
empowers both online and offline usage scenarios: for offline
scenarios, ARKG enables pre-generation of public keys for single-
use credentials without needing to access the hardware security
device that holds the private keys. For online scenarios, ARKG
gives the credential issuer assurance that all derived private
keys are bound to the same secure hardware element. In both
cases, application performance may be improved since public keys
can be generated in a general-purpose execution environment
instead of a secure enclave.
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* *Enhanced forward secrecy*: The use of ARKG can facilitate forward
secrecy in certain contexts. For instance, section 8.5.4 of RFC
9052 (https://www.rfc-editor.org/rfc/rfc9052.html#name-direct-key-
agreement) notes that "Since COSE is designed for a store-and-
forward environment rather than an online environment, [...]
forward secrecy (see [RFC4949]) is not achievable. A static key
will always be used for the receiver of the COSE object." As
opposed to workarounds like exchanging a large number of keys in
advance, ARKG enables the the sender to generate ephemeral
recipient public keys on demand.
* *Backup key generation*: For example, the W3C Web Authentication
API [WebAuthn] (WebAuthn) generates a new key pair for each
account on each web site. ARKG could allow for simultaneously
generating a backup public key when registering a new public key.
A primary authenticator could generate both a key pair for itself
and a public key for a paired backup authenticator. The backup
authenticator only needs to be paired with the primary
authenticator once, and can then be safely stored until it is
needed.
ARKG consists of three procedures:
* *Initialization*: The _delegating party_ generates a _seed pair_
and discloses the _public seed_ to a _subordinate party_, while
securely retaining the _private seed_.
* *Public key generation*: The subordinate party uses the public
seed to autonomously generate a new public key along with a unique
_key handle_ for the public key. This can be repeated any number
of times.
* *Private key derivation*: The delegating party uses a key handle
and the private seed to derive the private key corresponding to
the public key generated along with the key handle. This can be
repeated with any number of key handles.
Notably, ARKG can be built entirely using established cryptographic
primitives. The required primitives are a public key blinding scheme
and a key encapsulation mechanism (KEM), which may in turn use a key
derivation function (KDF) and a message authentication code (MAC)
scheme. Both conventional primitives and quantum-resistant
alternatives exist that meet these requirements. [Wilson]
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1.1. Requirements Language
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in
BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all
capitals, as shown here.
1.2. Notation
The following notation is used throughout this document:
* The symbol || represents octet string concatenation.
* Literal text strings and octet strings are denoted using the CDDL
syntax defined in Section 3.1 of [RFC8610].
* Elliptic curve operations are written in additive notation: +
denotes point addition, i.e., the curve group operation; * denotes
point multiplication, i.e., repeated point addition; and + also
denotes scalar addition modulo the curve order. * has higher
precedence than +, i.e., a + b * C is equivalent to a + (b * C).
2. The Asynchronous Remote Key Generation (ARKG) algorithm
The ARKG algorithm consists of three functions, each performed by one
of two participants: the _delegating party_ or the _subordinate
party_. The delegating party generates an ARKG _seed pair_ and emits
the _public seed_ to the subordinate party while keeping the _private
seed_ secret. The subordinate party can then use the public seed to
generate derived public keys and _key handles_, and the delegating
party can use the private seed and a key handle to derive the
corresponding private key.
The following subsections define the abstract instance parameters
used to construct the three ARKG functions, followed by the
definitions of the three ARKG functions.
2.1. Instance parameters
ARKG is composed of a suite of other algorithms. The parameters of
an ARKG instance are:
* BL: An asymmetric key blinding scheme [Wilson], consisting of:
- Function BL-Generate-Keypair() -> (pk, sk): Generate a blinding
key pair.
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No input.
Output consists of a blinding public key pk and a blinding
private key sk.
- Function BL-Blind-Public-Key(pk, tau, info) -> pk_tau:
Deterministically compute a blinded public key.
Input consists of a blinding public key pk, a blinding factor
tau and a domain separation parameter info.
Output consists of the blinded public key pk_tau.
- Function BL-Blind-Private-Key(sk, tau, info) -> sk_tau:
Deterministically compute a blinded private key.
Input consists of a blinding private key sk, a blinding factor
tau and a domain separation parameter info.
Output consists of the blinded private key sk_tau.
tau and info are an opaque octet strings of arbitrary length. The
representations of pk and pk_tau are defined by the protocol that
invokes ARKG. The representations of sk and sk_tau are an
undefined implementation detail.
See [Wilson] for definitions of security properties required of
the key blinding scheme BL.
* KEM: A key encapsulation mechanism, consisting of the functions:
- KEM-Generate-Keypair() -> (pk, sk): Generate a key
encapsulation key pair.
No input.
Output consists of public key pk and private key sk.
- KEM-Encaps(pk, info) -> (k, c): Generate a key encapsulation.
Input consists of an encapsulation public key pk and a domain
separation parameter info.
Output consists of a shared secret k and an encapsulation
ciphertext c.
- KEM-Decaps(sk, c, info) -> k: Decapsulate a shared secret.
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Input consists of encapsulation private key sk, encapsulation
ciphertext c and a domain separation parameter info.
Output consists of the shared secret k on success, or an error
otherwise.
k, c and info are opaque octet strings of arbitrary length. The
representation of pk is defined by the protocol that invokes ARKG.
The representation of sk is an undefined implementation detail.
The KEM MUST guarantee integrity of the ciphertext, meaning that
knowledge of the public key pk and the domain separation parameter
info is required in order to create any ciphertext c that can be
successfully decapsulated by the corresponding private key sk.
Section 3.2 describes a general formula for how any KEM can be
adapted to include this guarantee. Section 9.1 discusses the
reasons for this requirement.
See [Wilson] for definitions of additional security properties
required of the key encapsulation mechanism KEM.
A concrete ARKG instantiation MUST specify the instantiation of each
of the above functions and values.
The output keys of the BL scheme are also the output keys of the ARKG
instance as a whole. For example, if BL-Blind-Public-Key and BL-
Blind-Private-Key output ECDSA keys, then the ARKG instance will also
output ECDSA keys.
We denote a concrete ARKG instance by the pattern ARKG-BL-KEM,
substituting the chosen instantiation for the BL and KEM. Note that
this pattern cannot in general be unambiguously parsed;
implementations MUST NOT attempt to construct an ARKG instance by
parsing such a pattern string. Concrete ARKG instances MUST always
be identified by lookup in a registry of fully specified ARKG
instances. This is to prevent usage of algorithm combinations that
may be incompatible or insecure.
2.2. The function ARKG-Generate-Seed
This function is performed by the delegating party. The delegating
party generates the ARKG seed pair (pk, sk) and keeps the private
seed sk secret, while the public seed pk is provided to the
subordinate party. The subordinate party will then be able to
generate public keys on behalf of the delegating party.
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ARKG-Generate-Seed() -> (pk, sk)
ARKG instance parameters:
BL A key blinding scheme.
KEM A key encapsulation mechanism.
Inputs: None
Output:
(pk, sk) An ARKG seed pair with public seed pk
and private seed sk.
The output (pk, sk) is calculated as follows:
(pk_kem, sk_kem) = KEM-Generate-Keypair()
(pk_bl, sk_bl) = BL-Generate-Keypair()
pk = (pk_kem, pk_bl)
sk = (sk_kem, sk_bl)
2.2.1. Deterministic key generation
Although the above definition expresses the key generation as opaque,
likely sampling uniformly random key distributions, implementations
MAY choose to implement the functions BL-Generate-Keypair(), KEM-
Generate-Keypair() and ARKG-Generate-Seed() as deterministic
functions of some out-of-band input. This can be thought of as
defining a single-use ARKG instance where these function outputs are
static. This use case is beyond the scope of this document since the
implementation of ARKG-Generate-Seed is internal to the delegating
party, even if applications choose to distribute the delegating party
across multiple processing entities.
For example, one entity may randomly sample pk_bl, derive pk_kem
deterministically from pk_bl and submit only pk_bl to a separate
service that uses the same procedure to also derive the same pk_kem.
This document considers both of these entities as parts of the same
logical delegating party.
2.3. The function ARKG-Derive-Public-Key
This function is performed by the subordinate party, which holds the
ARKG public seed pk = (pk_kem, pk_bl). The resulting public key pk'
can be provided to external parties to use in asymmetric cryptography
protocols, and the resulting key handle kh can be used by the
delegating party to derive the private key corresponding to pk'.
This function may be invoked any number of times with the same public
seed, in order to generate any number of public keys.
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ARKG-Derive-Public-Key((pk_kem, pk_bl), info) -> (pk', kh)
ARKG instance parameters:
BL A key blinding scheme.
KEM A key encapsulation mechanism.
Inputs:
pk_kem A key encapsulation public key.
pk_bl A key blinding public key.
info An octet string containing optional context
and application specific information
(can be a zero-length string).
Output:
pk' A blinded public key.
kh A key handle for deriving the blinded
private key sk' corresponding to pk'.
The output (pk', kh) is calculated as follows:
info_kem = 'ARKG-Derive-Key-KEM.' || info
info_bl = 'ARKG-Derive-Key-BL.' || info
(tau, c) = KEM-Encaps(pk_kem, info_kem)
pk' = BL-Blind-Public-Key(pk_bl, tau, info_bl)
kh = c
If this procedure aborts due to an error, the procedure can safely be
retried with the same arguments.
2.4. The function ARKG-Derive-Private-Key
This function is performed by the delegating party, which holds the
ARKG private seed (sk_kem, sk_bl). The resulting private key sk' can
be used in asymmetric cryptography protocols to prove possession of
sk' to an external party that has the corresponding public key.
This function may be invoked any number of times with the same
private seed, in order to derive the same or different private keys
any number of times.
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ARKG-Derive-Private-Key((sk_kem, sk_bl), kh, info) -> sk'
ARKG instance parameters:
BL A key blinding scheme.
KEM A key encapsulation mechanism.
Inputs:
sk_kem A key encapsulation private key.
sk_bl A key blinding private key.
kh A key handle output from ARKG-Derive-Public-Key.
info An octet string containing optional context
and application specific information
(can be a zero-length string).
Output:
sk' A blinded private key.
The output sk' is calculated as follows:
info_kem = 'ARKG-Derive-Key-KEM.' || info
info_bl = 'ARKG-Derive-Key-BL.' || info
tau = KEM-Decaps(sk_kem, kh, info_kem)
If decapsulation failed:
Abort with an error.
sk' = BL-Blind-Private-Key(sk_bl, tau, info_bl)
Errors in this procedure are typically unrecoverable. For example,
KEM-Decaps may fail to decapsulate the KEM ciphertext kh if it fails
an integrity check. ARKG instantiations SHOULD be chosen in a way
that such errors are impossible if kh was generated by an honest and
correct implementation of ARKG-Derive-Public-Key. Incorrect or
malicious implementations of ARKG-Derive-Public-Key do not degrade
the security of a correct and honest implementation of ARKG-Derive-
Private-Key. See also Section 9.1.
3. Generic ARKG instantiations
This section defines generic formulae for instantiating the
individual ARKG parameters, which can be used to define concrete ARKG
instantiations.
3.1. Using elliptic curve addition for key blinding
Instantiations of ARKG whose output keys are elliptic curve keys can
use elliptic curve addition as the key blinding scheme BL
[Frymann2020] [Wilson]. This section defines a general formula for
such instantiations of BL.
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This formula has the following parameters:
* crv: An elliptic curve.
* hash-to-crv-suite: A hash-to-curve suite [RFC9380] suitable for
hashing to the scalar field of crv.
* DST_ext: A domain separation tag.
Then the BL parameter of ARKG may be instantiated as follows:
* G is the generator of the prime order subgroup of crv.
* N is the order of G.
* The function hash_to_field is defined in Section 5 of [RFC9380].
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BL-Generate-Keypair() -> (pk, sk)
Generate (pk, sk) using some procedure defined for the curve crv.
BL-Blind-Public-Key(pk, tau, info) -> pk_tau
tau' = hash_to_field(tau, 1) with the parameters:
DST: 'ARKG-BL-EC.' || DST_ext || info
F: GF(N), the scalar field
of the prime order subgroup of crv
p: N
m: 1
L: The L defined in hash-to-crv-suite
expand_message: The expand_message function
defined in hash-to-crv-suite
pk_tau = pk + tau' * G
BL-Blind-Private-Key(sk, tau, info) -> sk_tau
tau' = hash_to_field(tau, 1) with the parameters:
DST: 'ARKG-BL-EC.' || DST_ext || info
F: GF(N), the scalar field
of the prime order subgroup of crv.
p: N
m: 1
L: The L defined in hash-to-crv-suite
expand_message: The expand_message function
defined in hash-to-crv-suite
sk_tau_tmp = sk + tau'
If sk_tau_tmp = 0, abort with an error.
sk_tau = sk_tau_tmp
3.2. Using HMAC to adapt a KEM without integrity protection
Not all key encapsulation mechanisms guarantee ciphertext integrity,
meaning that a valid KEM ciphertext can be created only with
knowledge of the KEM public key. This section defines a general
formula for adapting any KEM to include integrity protection by
prepending a MAC to the KEM ciphertext.
For example, ECDH does not guarantee ciphertext integrity - any
elliptic curve point is a valid ECDH ciphertext and can be
successfully decapsulated using any elliptic curve private scalar.
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This formula has the following parameters:
* Hash: A cryptographic hash function.
* DST_ext: A domain separation parameter.
* Sub-Kem: A key encapsulation mechanism as described for the KEM
parameter in Section 2.1, except Sub-Kem MAY ignore the info
parameter and MAY not guarantee ciphertext integrity. Sub-Kem
defines the functions Sub-Kem-Generate-Keypair, Sub-Kem-Encaps and
Sub-Kem-Decaps.
The KEM parameter of ARKG may be instantiated using Sub-Kem, HMAC
[RFC2104] and HKDF [RFC5869] as follows:
* L is the output length of Hash in octets.
* LEFT(X, n) is the first n bytes of the byte array X.
* DROP_LEFT(X, n) is the byte array X without the first n bytes.
We truncate the HMAC output to 128 bits (16 octets) because as
described in Section 9.1, ARKG needs ciphertext integrity only to
ensure correctness, not for security. Extendable-output functions
used as the Hash parameter SHOULD still be instantiated with an
output length appropriate for the desired security level, in order to
not leak information about the Sub-KEM shared secret key.
KEM-Generate-Keypair() -> (pk, sk)
(pk, sk) = Sub-Kem-Generate-Keypair()
KEM-Encaps(pk, info) -> (k, c)
info_sub = 'ARKG-KEM-HMAC.' || DST_ext || info
(k', c') = Sub-Kem-Encaps(pk, info_sub)
prk = HKDF-Extract with the arguments:
Hash: Hash
salt: not set
IKM: k'
mk = HKDF-Expand with the arguments:
Hash: Hash
PRK: prk
info: 'ARKG-KEM-HMAC-mac.' || DST_ext || info
L: L
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t = HMAC-Hash-128(K=mk, text=info)
k = HKDF-Expand with the arguments:
Hash: Hash
PRK: prk
info: 'ARKG-KEM-HMAC-shared.' || DST_ext || info
L: The length of k' in octets.
c = t || c'
KEM-Decaps(sk, c, info) -> k
t = LEFT(c, 16)
c' = DROP_LEFT(c, 16)
info_sub = 'ARKG-KEM-HMAC.' || DST_ext || info
k' = Sub-Kem-Decaps(sk, c', info_sub)
prk = HKDF-Extract with the arguments:
Hash: Hash
salt: not set
IKM: k'
mk = HKDF-Expand with the arguments:
Hash: Hash
PRK: prk
info: 'ARKG-KEM-HMAC-mac.' || DST_ext || info
L: L
t' = HMAC-Hash-128(K=mk, text=info)
If t = t':
k = HKDF-Expand with the arguments:
Hash: Hash
PRK: prk
info: 'ARKG-KEM-HMAC-shared.' || DST_ext || info
L: The length of k' in octets.
Else:
Abort with an error.
3.3. Using ECDH as the KEM
Instantiations of ARKG can use ECDH [RFC6090] as the key
encapsulation mechanism KEM [Frymann2020] [Wilson]. This section
defines a general formula for such instantiations of KEM.
This formula has the following parameters:
* crv: an elliptic curve valid for use with ECDH [RFC6090].
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* Hash: A cryptographic hash function.
* DST_ext: A domain separation parameter.
The KEM parameter of ARKG may be instantiated as described in section
Section 3.2 with the parameters:
* Hash: Hash.
* DST_ext: 'ARKG-ECDH.' || DST_ext.
* Sub-Kem: The functions Sub-Kem-Generate-Keypair, Sub-Kem-Encaps
and Sub-Kem-Decaps defined as follows:
- Elliptic-Curve-Point-to-Octet-String and Octet-String-to-
Elliptic-Curve-Point are the conversion routines defined in
sections 2.3.3 and 2.3.4 of [SEC1], without point compression.
- ECDH(pk, sk) represents the compact output of ECDH [RFC6090]
using public key (curve point) pk and private key (exponent)
sk.
- G is the generator of the prime order subgroup of crv.
- N is the order of G.
Sub-Kem-Generate-Keypair() -> (pk, sk)
Generate (pk, sk) using some procedure defined for crv.
Sub-Kem-Encaps(pk, info) -> (k, c)
(pk', sk') = Sub-Kem-Generate-Keypair()
k = ECDH(pk, sk')
c = Elliptic-Curve-Point-to-Octet-String(pk')
Sub-Kem-Decaps(sk, c, info) -> k
pk' = Octet-String-to-Elliptic-Curve-Point(c)
k = ECDH(pk', sk)
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3.4. Using X25519 or X448 as the KEM
Instantiations of ARKG can use X25519 or X448 [RFC7748] as the key
encapsulation mechanism KEM. This section defines a general formula
for such instantiations of KEM.
This formula has the following parameters:
* DH-Function: the function X25519 or the function X448 [RFC7748].
* DST_ext: A domain separation parameter.
The KEM parameter of ARKG may be instantiated as described in section
Section 3.2 with the parameters:
* Hash: SHA-512 [FIPS 180-4] if DH-Function is X25519, or SHAKE256
[FIPS 202] with output length 64 octets if DH-Function is X448.
* DST_ext: 'ARKG-ECDHX.' || DST_ext.
* Sub-Kem: The functions Sub-Kem-Generate-Keypair, Sub-Kem-Encaps
and Sub-Kem-Decaps defined as follows:
- Random-Bytes(N) represents a cryptographically secure,
uniformly distributed random octet string of length N.
- L is 32 if DH-Function is X25519, or 56 if DH-Function is X448.
- G is the octet string h'0900000000000000 0000000000000000
0000000000000000 0000000000000000' if DH-Function is X25519, or
the octet string h'0500000000000000 0000000000000000
0000000000000000 0000000000000000 0000000000000000
0000000000000000 0000000000000000' if DH-Function is X448.
These are the little-endian encodings of the integers 9 and 5,
which is the u-coordinate of the generator point of the
respective curve group.
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Sub-Kem-Generate-Keypair() -> (pk, sk)
sk = Random-Bytes(L)
pk = DH-Function(sk, G)
Sub-Kem-Encaps(pk, info) -> (k, c)
(pk', sk') = Sub-Kem-Generate-Keypair()
k = DH-Function(sk', pk)
c = pk'
Sub-Kem-Decaps(sk, c, info) -> k
k = DH-Function(sk, c)
3.5. Using the same key for both key blinding and KEM
When an ARKG instance uses the same type of key for both the key
blinding and the KEM - for example, if elliptic curve arithmetic is
used for key blinding as described in Section 3.1 and ECDH is used as
the KEM as described in Section 3.3 [Frymann2020] - then the two keys
MAY be the same key. Representations of such an ARKG seed MAY allow
for omitting the second copy of the constituent key, but such
representations MUST clearly identify that the single constituent key
is to be used both as the key blinding key and the KEM key.
4. Concrete ARKG instantiations
This section defines an initial set of concrete ARKG instantiations.
TODO: IANA registry? COSE/JOSE?
4.1. ARKG-P256ADD-ECDH
The identifier ARKG-P256ADD-ECDH represents the following ARKG
instance:
* BL: Elliptic curve addition as described in Section 3.1 with the
parameters:
- crv: The NIST curve secp256r1 [SEC2].
- hash-to-crv-suite: P256_XMD:SHA-256_SSWU_RO_ [RFC9380].
- DST_ext: 'ARKG-P256ADD-ECDH'.
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* KEM: ECDH as described in Section 3.3 with the parameters:
- crv: The NIST curve secp256r1 [SEC2].
- Hash: SHA-256 [FIPS 180-4].
- DST_ext: 'ARKG-P256ADD-ECDH'.
4.2. ARKG-P384ADD-ECDH
The identifier ARKG-P384ADD-ECDH represents the following ARKG
instance:
* BL: Elliptic curve addition as described in Section 3.1 with the
parameters:
- crv: The NIST curve secp384r1 [SEC2].
- hash-to-crv-suite: P384_XMD:SHA-384_SSWU_RO_ [RFC9380].
- DST_ext: 'ARKG-P384ADD-ECDH'.
* KEM: ECDH as described in Section 3.3 with the parameters:
- crv: The NIST curve secp384r1 [SEC2].
- Hash: SHA-384 [FIPS 180-4].
- DST_ext: 'ARKG-P384ADD-ECDH'.
4.3. ARKG-P521ADD-ECDH
The identifier ARKG-P521ADD-ECDH represents the following ARKG
instance:
* BL: Elliptic curve addition as described in Section 3.1 with the
parameters:
- crv: The NIST curve secp521r1 [SEC2].
- hash-to-crv-suite: P521_XMD:SHA-512_SSWU_RO_ [RFC9380].
- DST_ext: 'ARKG-P521ADD-ECDH'.
* KEM: ECDH as described in Section 3.3 with the parameters:
- crv: The NIST curve secp521r1 [SEC2].
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- Hash: SHA-512 [FIPS 180-4].
- DST_ext: 'ARKG-P521ADD-ECDH'.
4.4. ARKG-P256kADD-ECDH
The identifier ARKG-P256kADD-ECDH represents the following ARKG
instance:
* BL: Elliptic curve addition as described in Section 3.1 with the
parameters:
- crv: The SECG curve secp256k1 [SEC2].
- hash-to-crv-suite: secp256k1_XMD:SHA-256_SSWU_RO_ [RFC9380].
- DST_ext: 'ARKG-P256kADD-ECDH'.
* KEM: ECDH as described in Section 3.3 with the parameters:
- crv: The SECG curve secp256k1 [SEC2].
- Hash: SHA-256 [FIPS 180-4].
- DST_ext: 'ARKG-P256kADD-ECDH'.
4.5. ARKG-curve25519ADD-X25519
The identifier ARKG-curve25519ADD-X25519 represents the following
ARKG instance:
* BL: Elliptic curve addition as described in Section 3.1 with the
parameters:
- crv: The curve curve25519 [RFC7748].
- hash-to-crv-suite: curve25519_XMD:SHA-512_ELL2_RO_ [RFC9380].
- DST_ext: 'ARKG-curve25519ADD-X25519'.
WARNING: Some algorithms on curve25519, including X25519
[RFC7748], construct private key scalars within a particular range
to enable optimizations and constant-time guarantees. This BL
scheme does not guarantee that blinded private scalars remain in
that range, so implementations using this ARKG instance MUST NOT
rely on such a guarantee.
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Note: Input and output keys of this BL scheme are curve scalars
and curve points. Some algorithms on curve25519, including X25519
[RFC7748], define the private key input as a random octet string
and applies some preprocessing to it before interpreting the
result as a private key scalar, and define public keys as a
particular octet string encoding of a curve point. This BL scheme
is not compatible with such preprocessing since it breaks the
relationship between the blinded private key and the blinded
public key. Implementations using this ARKG instance MUST apply
BL-Blind-Private-Key to the interpreted private key scalar, not
the random private key octet string, and implementations of BL-
Blind-Public-Key MUST interpret the public key input as a curve
point, not an opaque octet string.
* KEM: X25519 as described in Section 3.4 with the parameters:
- DH-Function: X25519 [RFC7748].
- DST_ext: 'ARKG-curve25519ADD-X25519'.
4.6. ARKG-curve448ADD-X448
The identifier ARKG-curve448ADD-X448 represents the following ARKG
instance:
* BL: Elliptic curve addition as described in Section 3.1 with the
parameters:
- crv: The curve curve448 [RFC7748].
- hash-to-crv-suite: curve448_XOF:SHAKE256_ELL2_RO_ [RFC9380].
- DST_ext: 'ARKG-curve448ADD-X448'.
WARNING: Some algorithms on curve25519, including X448 [RFC7748],
construct private key scalars within a particular range to enable
optimizations and constant-time guarantees. This BL scheme does
not guarantee that blinded private scalars remain in that range,
so implementations using this ARKG instance MUST NOT rely on such
a guarantee.
Note: Input and output keys of this BL scheme are curve scalars
and curve points. Some algorithms on curve25519, including X448
[RFC7748], define the private key input as a random octet string
and applies some preprocessing to it before interpreting the
result as a private key scalar, and define public keys as a
particular octet string encoding of a curve point. This BL scheme
is not compatible with such preprocessing since it breaks the
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relationship between the blinded private key and the blinded
public key. Implementations using this ARKG instance MUST apply
BL-Blind-Private-Key to the interpreted private key scalar, not
the random private key octet string, and implementations of BL-
Blind-Public-Key MUST interpret the public key input as a curve
point, not an opaque octet string.
* KEM: X448 as described in Section 3.4 with the parameters:
- DH-Function: X448 [RFC7748].
- DST_ext: 'ARKG-curve448ADD-X448'.
4.7. ARKG-edwards25519ADD-X25519
The identifier ARKG-edwards25519ADD-X25519 represents the following
ARKG instance:
* BL: Elliptic curve addition as described in Section 3.1 with the
parameters:
- crv: The curve edwards25519 [RFC7748].
- hash-to-crv-suite: edwards25519_XMD:SHA-512_ELL2_RO_ [RFC9380].
- DST_ext: 'ARKG-edwards25519ADD-X25519'.
WARNING: Some algorithms on edwards25519, including EdDSA
[RFC8032], construct private key scalars within a particular range
to enable optimizations and constant-time guarantees. This BL
scheme does not guarantee that blinded private scalars remain in
that range, so implementations using this ARKG instance MUST NOT
rely on such a guarantee.
Note: Input and output keys of this BL scheme are curve scalars
and curve points. Some algorithms on edwards25519, including
EdDSA [RFC8032], define the private key input as a random octet
string and applies some preprocessing to it before interpreting
the result as a private key scalar, and define public keys as a
particular octet string encoding of a curve point. This BL scheme
is not compatible with such preprocessing since it breaks the
relationship between the blinded private key and the blinded
public key. Implementations using this ARKG instance MUST apply
BL-Blind-Private-Key to the interpreted private key scalar, not
the random private key octet string, and implementations of BL-
Blind-Public-Key MUST interpret the public key input as a curve
point, not an opaque octet string.
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* KEM: X25519 as described in Section 3.4 with the parameters:
- DH-Function: X25519 [RFC7748].
- DST_ext: 'ARKG-edwards25519ADD-X25519'.
4.8. ARKG-edwards448ADD-X448
The identifier ARKG-edwards448ADD-X448 represents the following ARKG
instance:
* BL: Elliptic curve addition as described in Section 3.1 with the
parameters:
- crv: The curve edwards448 [RFC7748].
- hash-to-crv-suite: edwards448_XOF:SHAKE256_ELL2_RO_ [RFC9380].
- DST_ext: 'ARKG-edwards448ADD-X448'.
WARNING: Some algorithms on edwards25519, including EdDSA
[RFC8032], construct private key scalars within a particular range
to enable optimizations and constant-time guarantees. This BL
scheme does not guarantee that blinded private scalars remain in
that range, so implementations using this ARKG instance MUST NOT
rely on such a guarantee.
Note: Input and output keys of this BL scheme are curve scalars
and curve points. Some algorithms on edwards25519, including
EdDSA [RFC8032], define the private key input as a random octet
string and applies some preprocessing to it before interpreting
the result as a private key scalar, and define public keys as a
particular octet string encoding of a curve point. This BL scheme
is not compatible with such preprocessing since it breaks the
relationship between the blinded private key and the blinded
public key. Implementations using this ARKG instance MUST apply
BL-Blind-Private-Key to the interpreted private key scalar, not
the random private key octet string, and implementations of BL-
Blind-Public-Key MUST interpret the public key input as a curve
point, not an opaque octet string.
* KEM: X448 as described in Section 3.4 with the parameters:
- DH-Function: X448 [RFC7748].
- DST_ext: 'ARKG-edwards448ADD-X448'.
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5. COSE bindings
This section proposes additions to COSE [RFC9052] to support ARKG use
cases. The novelty lies primarily in a new key type definition to
represent ARKG public seeds and new key type definitions to represent
references to private keys rather than the keys themselves.
5.1. COSE key type: ARKG public seed
An ARKG public seed is represented as a COSE_Key structure [RFC9052]
with kty value TBD (placeholder value -65537). This key type defines
key type parameters -1 and -2 for the BL and KEM public key,
respectively.
The following CDDL example represents an ARKG-P256ADD-ECDH public
seed restricted to generating derived public keys for use with the
ESP256 [fully-spec-algs] signature algorithm:
{
1: -65537, ; kty: ARKG-pub-seed
; kid: Opaque identifier
2: h'60b6dfddd31659598ae5de49acb220d8
704949e84d484b68344340e2565337d2',
3: -65539, ; alg: ESP256-ARKG
-1: { ; BL public key
1: 2, ; kty: EC2
-1: 1, ; crv: P256
-2: h'69380FC1C3B09652134FEEFBA61776F9
7AF875CE46CA20252C4165102966EBC5',
-3: h'8B515831462CCB0BD55CBA04BFD50DA6
3FAF18BD845433622DAF97C06A10D0F1',
},
-2: { ; KEM public key
1: 2, ; kty: EC2
-1: 1, ; crv: P256
-2: h'5C099BEC31FAA581D14E208250D3FFDA
9EC7F543043008BC84967A8D875B5D78',
-3: h'539D57429FCB1C138DA29010A155DCA1
4566A8F55AC2F1780810C49D4ED72D58',
}
}
The following is the same example encoded as CBOR:
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h'a50139fbb402582060b6dfddd31659598ae5de49acb220d8704949e84d484b68
344340e2565337d2033a0001000220a40102200121582069380fc1c3b0965213
4feefba61776f97af875ce46ca20252c4165102966ebc52258208b515831462c
cb0bd55cba04bfd50da63faf18bd845433622daf97c06a10d0f121a401022001
2158205c099bec31faa581d14e208250d3ffda9ec7f543043008bc84967a8d87
5b5d78225820539d57429fcb1c138da29010a155dca14566a8f55ac2f1780810
c49d4ed72d58'
5.2. COSE key reference types
While keys used by many other algorithms can usually be referenced by
a single atomic identifier, such as that used in the kid parameter in
a COSE_Key object or in the unprotected header of a COSE_Recipient,
users of the function ARKG-Derive-Secret-Key need to represent a
reference to an ARKG private seed along with a key handle for a
derived private key.
A COSE key reference is a COSE_Key object whose kty value is defined
to represent a reference to a key. The kid parameter MUST be present
when kty is a key reference type.
The following CDDL example represents a reference to a key derived by
ARKG-P256ADD-ECDH and restricted for use with the ESP256
[fully-spec-algs] signature algorithm:
{
1: -65538, ; kty: ARKG-derived
; kid: Opaque identifier of ARKG-pub-seed
2: h'60b6dfddd31659598ae5de49acb220d8
704949e84d484b68344340e2565337d2',
3: -65539, ; alg: ESP256-ARKG
; ARKG-P256ADD-ECDH key handle
; (truncated HMAC-SHA-256 followed by
SEC1 uncompressed ECDH public key)
-1: h'ae079e9c52212860678a7cee25b6a6d4
048219d973768f8e1adb8eb84b220b0ee3
a2532828b9aa65254fe3717a29499e9b
aee70cea75b5c8a2ec2eb737834f7467
e37b3254776f65f4cfc81e2bc4747a84',
; info argument to ARKG-Derive-Private-Key
-2: 'Example application info',
}
The following is the same example encoded as CBOR:
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h'a40139fbb502582060b6dfddd31659598ae5de49acb220d8704949e84d484b68
344340e2565337d2033a00010002205851ae079e9c52212860678a7cee25b6a6
d4048219d973768f8e1adb8eb84b220b0ee3a2532828b9aa65254fe3717a2949
9e9baee70cea75b5c8a2ec2eb737834f7467e37b3254776f65f4cfc81e2bc474
7a84'
6. Security Considerations
TODO
7. Privacy Considerations
TODO
8. IANA Considerations
8.1. COSE Key Types Registrations
This section registers the following values in the IANA "COSE Key
Types" registry [IANA.cose].
* Name: ARKG-pub-seed
- Value: TBD (Placeholder -65537)
- Description: ARKG public seed
- Capabilities: [kty(-65537), pk_bl, pk_kem]
- Reference: Section 5.1 of this document
* Name: ARKG-derived
- Value: TBD (Placeholder -65538)
- Description: Reference to private key derived by ARKG
- Capabilities: [kty(-65538), kh]
- Reference: Section 5.2 of this document
* Name: Ref-OKP
- Value: TBD (Requested assignment -1)
- Description: Reference to a key pair of key type "OKP"
- Capabilities: [kty(-1), crv]
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- Reference: Section 5.2 of this document
* Name: Ref-EC2
- Value: TBD (Requested assignment -2)
- Description: Reference to a key pair of key type "EC2"
- Capabilities: [kty(-1), crv]
- Reference: Section 5.2 of this document
8.2. COSE Key Type Parameters Registrations
This section registers the following values in the IANA "COSE Key
Type Parameters" registry [IANA.cose].
* Key Type: TBD (ARKG-pub-seed, placeholder -65537)
- Name: pk_bl
- Label: -1
- CBOR Type: COSE_Key
- Description: ARKG key blinding public key
- Reference: Section 5.1 of this document
* Key Type: TBD (ARKG-pub-seed, placeholder -65537)
- Name: pk_kem
- Label: -2
- CBOR Type: COSE_Key
- Description: ARKG key encapsulation public key
- Reference: Section 5.1 of this document
* Key Type: TBD (ARKG-derived, placeholder -65538)
- Name: kh
- Label: -1
- CBOR Type: bstr
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- Description: kh argument to ARKG-Derive-Private-Key
- Reference: Section 5.2 of this document
* Key Type: TBD (ARKG-derived, placeholder -65538)
- Name: info
- Label: -2
- CBOR Type: bstr
- Description: info argument to ARKG-Derive-Private-Key
- Reference: Section 5.2 of this document
8.3. COSE Algorithms Registrations
This section registers the following values in the IANA "COSE
Algorithms" registry [IANA.cose].
* Name: ESP256-ARKG
- Value: TBD (Placeholder -65539)
- Description: ESP256 with key derived by ARKG-P256ADD-ECDH
- Capabilities: [kty]
- Change Controller: TBD
- Reference: [fully-spec-algs], Section 4.1 of this document
- Recommended: Yes
* Name: ESP384-ARKG
- Value: TBD (Placeholder -65540)
- Description: ESP384 with key derived by ARKG-P384ADD-ECDH
- Capabilities: [kty]
- Change Controller: TBD
- Reference: [fully-spec-algs], Section 4.2 of this document
- Recommended: Yes
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* Name: ESP512-ARKG
- Value: TBD (Placeholder -65541)
- Description: ESP512 with key derived by ARKG-P521ADD-ECDH
- Capabilities: [kty]
- Change Controller: TBD
- Reference: [fully-spec-algs], Section 4.3 of this document
- Recommended: Yes
* Name: ES256K-ARKG
- Value: TBD (Placeholder -65542)
- Description: ES256K with key derived by ARKG-P256kADD-ECDH
- Capabilities: [kty]
- Change Controller: TBD
- Reference: [RFC8812], Section 4.4 of this document
- Recommended: Yes
* Name: Ed25519-ARKG
- Value: TBD (Placeholder -65543)
- Description: Ed25519 with key derived by ARKG-
edwards25519ADD-X25519
- Capabilities: [kty]
- Change Controller: TBD
- Reference: [fully-spec-algs], Section 4.7 of this document
- Recommended: Yes
* Name: Ed448-ARKG
- Value: TBD (Placeholder -65544)
- Description: Ed448 with key derived by ARKG-edwards448ADD-X448
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- Capabilities: [kty]
- Change Controller: TBD
- Reference: [fully-spec-algs], Section 4.8 of this document
- Recommended: Yes
TODO: Add the rest
9. Design rationale
9.1. Using a MAC
The ARKG construction by Wilson [Wilson] omits the MAC and instead
encodes application context in the PRF labels, arguing that this
leads to invalid keys/signatures in cases that would have a bad MAC.
We choose to keep the MAC from the construction by Frymann et al.
[Frymann2020], but allow it to be omitted in case the chosen KEM
already guarantees ciphertext integrity.
The reason for this is to ensure that the delegating party can
distinguish key handles that belong to its ARKG seed. For example,
this is important for applications using the W3C Web Authentication
API [WebAuthn], which do not know beforehand which authenticators are
connected and available. Instead, authentication requests may
include references to several eligible authenticators, and the one to
use is chosen opportunistically by the WebAuthn client depending on
which are available at the time. Consider using ARKG in such a
scenario to sign some data with a derived private key: a user may
have several authenticators and thus several ARKG seeds, so the
signing request might include several well-formed ARKG key handles,
but only one of them belongs to the ARKG seed of the authenticator
that is currently connected. Without an integrity check, choosing
the wrong key handle might cause the ARKG-Derive-Private-Key
procedure to silently derive the wrong key instead of returning an
explicit error, which would in turn lead to an invalid signature or
similar final output. This would make it difficult or impossible to
diagnose the root cause of the issue and present actionable user
feedback. For this reason, we require the KEM to guarantee
ciphertext integrity so that ARKG-Derive-Private-Key can fail early
if the key handle belongs to a different ARKG seed.
It is straightforward to see that adding the MAC to the construction
by Wilson does not weaken the security properties defined by Frymann
et al. [Frymann2020]: the construction by Frymann et al. can be
reduced to the ARKG construction in this document by instantiating BL
as described in Section 3.1 and KEM as described in Section 3.3. The
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use of hash_to_field in Section 3.1 corresponds to the KDF_1
parameter in [Frymann2020], and the use of HMAC and HKDF in
Section 3.2 corresponds to the MAC and KDF_2 parameters in
[Frymann2020]. Hence if one can break PK-unlinkability or SK-
security of the ARKG construction in this document, one can also
break the same property of the construction by Frymann et al.
9.2. Implementation Status
TODO
10. References
10.1. Normative References
[fully-spec-algs]
Jones, M. B., "Fully-Specified Algorithms for JOSE and
COSE", 2024, .
[IANA.cose]
IANA, "CBOR Object Signing and Encryption (COSE)",
.
[RFC2104] Krawczyk, H., Bellare, M., and R. Canetti, "HMAC: Keyed-
Hashing for Message Authentication", RFC 2104,
DOI 10.17487/RFC2104, February 1997,
.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
.
[RFC4949] Shirey, R., "Internet Security Glossary, Version 2",
FYI 36, RFC 4949, DOI 10.17487/RFC4949, August 2007,
.
[RFC5869] Krawczyk, H. and P. Eronen, "HMAC-based Extract-and-Expand
Key Derivation Function (HKDF)", RFC 5869,
DOI 10.17487/RFC5869, May 2010,
.
[RFC6090] McGrew, D., Igoe, K., and M. Salter, "Fundamental Elliptic
Curve Cryptography Algorithms", RFC 6090,
DOI 10.17487/RFC6090, February 2011,
.
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[RFC7748] Langley, A., Hamburg, M., and S. Turner, "Elliptic Curves
for Security", RFC 7748, DOI 10.17487/RFC7748, January
2016, .
[RFC8032] Josefsson, S. and I. Liusvaara, "Edwards-Curve Digital
Signature Algorithm (EdDSA)", RFC 8032,
DOI 10.17487/RFC8032, January 2017,
.
[RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
May 2017, .
[RFC8610] Birkholz, H., Vigano, C., and C. Bormann, "Concise Data
Definition Language (CDDL): A Notational Convention to
Express Concise Binary Object Representation (CBOR) and
JSON Data Structures", RFC 8610, DOI 10.17487/RFC8610,
June 2019, .
[RFC8812] Jones, M., "CBOR Object Signing and Encryption (COSE) and
JSON Object Signing and Encryption (JOSE) Registrations
for Web Authentication (WebAuthn) Algorithms", RFC 8812,
DOI 10.17487/RFC8812, August 2020,
.
[RFC9052] Schaad, J., "CBOR Object Signing and Encryption (COSE):
Structures and Process", STD 96, RFC 9052,
DOI 10.17487/RFC9052, August 2022,
.
[RFC9380] Faz-Hernandez, A., Scott, S., Sullivan, N., Wahby, R. S.,
and C. A. Wood, "Hashing to Elliptic Curves", RFC 9380,
DOI 10.17487/RFC9380, August 2023,
.
[SEC1] Certicom Research, "SEC 1: Elliptic Curve Cryptography",
2009, .
[SEC2] Certicom Research, "SEC 2: Recommended Elliptic Curve
Domain Parameters", 2010,
.
10.2. Informative References
[BIP32] Wuille, P., "BIP 32 Hierarchical Deterministic Wallets",
2012, .
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[Clermont] Clermont, S. A. and Technische Universität Darmstadt,
"Post Quantum Asynchronous Remote Key Generation. Master's
thesis", 2022, .
[Frymann2020]
Frymann, N., Gardham, D., Kiefer, F., Lundberg, E.,
Manulis, M., and D. Nilsson, "Asynchronous Remote Key
Generation: An Analysis of Yubico's Proposal for W3C
WebAuthn. CCS '20: Proceedings of the 2020 ACM SIGSAC
Conference on Computer and Communications Security", 2020,
.
[Frymann2023]
Frymann, N., Gardham, D., and M. Manulis, "Asynchronous
Remote Key Generation for Post-Quantum Cryptosystems from
Lattices. 2023 IEEE 8th European Symposium on Security and
Privacy", 2023, .
[WebAuthn-Recovery]
Lundberg, E. and D. Nilsson, "WebAuthn recovery extension:
Asynchronous delegated key generation without shared
secrets. GitHub", 2019,
.
[Wilson] Wilson, S. M. and University of Waterloo,, "Post-Quantum
Account Recovery for Passwordless Authentication. Master's
thesis", 2023, .
Appendix A. Acknowledgements
ARKG was first proposed under this name by Frymann et al.
[Frymann2020], who analyzed a proposed extension to W3C Web
Authentication by Lundberg and Nilsson [WebAuthn-Recovery], which was
in turn inspired by a similar construction by Wuille [BIP32] used to
create privacy-preserving Bitcoin addresses. Frymann et al.
[Frymann2020] generalized the constructions by Lundberg, Nilsson and
Wuille from elliptic curves to any discrete logarithm (DL) problem,
and also proved the security of arbitrary asymmetric protocols
composed with ARKG. Further generalizations to include quantum-
resistant instantiations were developed independently by Clermont
[Clermont], Frymann et al. [Frymann2023] and Wilson [Wilson].
This document adopts the construction proposed by Wilson [Wilson],
modified by the inclusion of a MAC in the key handles as done in the
original construction by Frymann et al. [Frymann2020].
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The authors would like to thank all of these authors for their
research and development work that led to the creation of this
document.
Appendix B. Test Vectors
TODO
Appendix C. Document History
* 00 Initial Version
* 01 Editorial Fixes to formatting and references.
* 02
- Rewritten introduction.
- Renamed ARKG-Derive-Secret-Key to ARKG-Derive-Private-Key.
- Overhauled EC instantiations to use hash_to_field and account
for non-prime order curve key generation.
- Eliminated top-level MAC and KDF instance parameters.
- Added info parameter to instance parameter functions.
- Added requirement of KEM ciphertext integrity and generic
formula for augmenting any KEM using HMAC.
- Added curve/edwards25519/448 instances.
- Added proposal for COSE bindings and key reference types.
Contributors
Dain Nilsson
Yubico
Peter Altmann
Agency for Digital Government
Sweden
Authors' Addresses
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Emil Lundberg (editor)
Yubico
Kungsgatan 44
Stockholm
Sweden
Email: emil@emlun.se
John Bradley
Yubico
Email: ve7jtb@ve7jtb.com
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