Crypto Forum S. Q. Dijkhuis, Ed. Internet-Draft Cleverbase Intended status: Informational 17 October 2024 Expires: 20 April 2025 Hierarchical Deterministic Keys draft-dijkhuis-cfrg-hdkeys-01 Abstract Hierarchical Deterministic Keys enables managing large sets of keys bound to a secure cryptographic device that protects a single key. This enables the development of secure digital identity wallets providing many one-time-use public keys. 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-dijkhuis-cfrg-hdkeys/. Source for this draft and an issue tracker can be found at https://github.com/sander/hierarchical-deterministic-keys. Status of This Memo This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet- Drafts is at https://datatracker.ietf.org/drafts/current/. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress." This Internet-Draft will expire on 20 April 2025. Copyright Notice Copyright (c) 2024 IETF Trust and the persons identified as the document authors. All rights reserved. Dijkhuis Expires 20 April 2025 [Page 1] Internet-Draft HDK October 2024 This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/ license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Table of Contents 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3 1.1. Conventions and definitions . . . . . . . . . . . . . . . 3 2. The Hierarchical Deterministic Keys algorithm . . . . . . . . 4 2.1. Introductory examples . . . . . . . . . . . . . . . . . . 4 2.1.1. Local key derivation example . . . . . . . . . . . . 4 2.1.2. Remote key derivation example . . . . . . . . . . . . 5 2.1.3. Blinding example . . . . . . . . . . . . . . . . . . 6 2.2. Instantiation parameters . . . . . . . . . . . . . . . . 6 2.3. The HDK-Root function . . . . . . . . . . . . . . . . . . 8 2.4. The HDK-Derive-Local function . . . . . . . . . . . . . . 8 2.5. The HDK-Seed-Remote function . . . . . . . . . . . . . . 9 2.6. The HDK-Derive-Remote function . . . . . . . . . . . . . 9 2.7. The HDK-Authenticate function . . . . . . . . . . . . . . 10 2.8. The HDK-Export-Blinding-Factor function . . . . . . . . . 10 3. Generic HDK instantiations . . . . . . . . . . . . . . . . . 11 3.1. Using elliptic curves . . . . . . . . . . . . . . . . . . 11 3.2. Using ECDH message authentication codes for proof of possession . . . . . . . . . . . . . . . . . . . . . . . 12 3.3. Using EC-SDSA signatures for proof of possession . . . . 13 3.4. Using ECDSA signatures for proof of possession . . . . . 14 4. Concrete HDK instantiations . . . . . . . . . . . . . . . . . 14 4.1. HDK-ECDH-P256 . . . . . . . . . . . . . . . . . . . . . . 14 4.2. HDK-ECSDSA-P256 . . . . . . . . . . . . . . . . . . . . . 15 5. Application considerations . . . . . . . . . . . . . . . . . 16 5.1. Secure cryptographic device . . . . . . . . . . . . . . . 16 5.2. Trust evidence . . . . . . . . . . . . . . . . . . . . . 20 5.2.1. Wallet Trust Evidence . . . . . . . . . . . . . . . . 20 5.2.2. Issuer Trust Evidence . . . . . . . . . . . . . . . . 20 5.3. Applying HDK in OpenID for Verifiable Credential Issuance . . . . . . . . . . . . . . . . . . . . . . . . 21 6. Security considerations . . . . . . . . . . . . . . . . . . . 21 6.1. Confidentiality of key handles . . . . . . . . . . . . . 21 7. References . . . . . . . . . . . . . . . . . . . . . . . . . 21 7.1. Normative References . . . . . . . . . . . . . . . . . . 22 7.2. Informative References . . . . . . . . . . . . . . . . . 23 Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . . 24 Contributors . . . . . . . . . . . . . . . . . . . . . . . . . . 24 Author's Address . . . . . . . . . . . . . . . . . . . . . . . . 24 Dijkhuis Expires 20 April 2025 [Page 2] Internet-Draft HDK October 2024 1. Introduction This document specifies the algorithms to apply Hierarchical Deterministic Keys (HDKs). The purpose of an HDK architecture is to manage large sets of keys bound to a secure cryptographic device that protects a single key. This enables the development of secure digital identity wallets providing many one-time-use public keys. The core idea has been introduced in [BIP32] to create multiple cryptocurrency addresses in a manageable way. The present document extends the idea towards devices commonly used for digital wallets, and towards common interaction patterns for document issuance and authentication. To store many HDKs, only a seed string needs to be securely stored, associated with the device private key. Each HDK is then deterministically defined by a path of self-generated indices or provided key handles. Such a path can efficiently be stored and requires less confidentiality than the seed. To prove possession of many HDKs, the secure cryptographic device only needs to perform common cryptographic operations on a single key. The HDK acts as a blinding factor that enables blinding the device public key. This document provides a specification of the generic HDK scheme, generic HDK instantiations, and fully specified concrete HDK instantiations. An HDK instantiation is expected to be applied in a solution deployed as (wallet) solution instances. One solution instance can have multiple HDK instantiations, for example to manage multiple identities or multiple cryptographic algorithms or key protection mechanisms. This document represents the consensus of the authors, based on working group input and feedback. It is not a standard. It does not include security or privacy proofs. 1.1. Conventions and definitions 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. The following notation is used throughout the document. Dijkhuis Expires 20 April 2025 [Page 3] Internet-Draft HDK October 2024 * byte: A sequence of eight bits. * I2OSP(n, w): Convert non-negative integer n to a w-length, big- endian byte string, as described in [RFC8017]. 2. The Hierarchical Deterministic Keys algorithm An HDK instantiation applies local key derivation to create many key pairs from a single seed value. It applies asynchronous remote key generation to enable providers to derive more key pairs. Additionally, an HDK instantiation applies these key pairs to blind a single key pair and proofs of its possession, such as required in [RFC7800]. Solutions MAY omit application of the asynchronous remote key generation functionality. In this case, a solution instance can only derive keys locally. 2.1. Introductory examples 2.1.1. Local key derivation example The following example illustrates the use of key derivation. An HDK tree is defined by an initial public key and a seed value, which is a byte array containing sufficient entropy. Now tree nodes are constructed as follows. Dijkhuis Expires 20 April 2025 [Page 4] Internet-Draft HDK October 2024 +------------------------+ |Confidential static data| |+---------+ +----+ | ||pk_device| |seed| | |+----+----+ +--+-+ | +-----+---------+--------+ +-----------------+---------+---------------------------+ |Level 0 v v | |+-----------------------------------------------------+| ||(pk0, sdk0, salt0) = hdk0 = HDK-Root(pk_device, seed)|| |+----+------------------------------------------------+| +-----+-------------------------------------------------+ Level 1 v +-------------------------++-----------------++-----------------+ |(pk1, sk1, salt1) = ||HDK-Derive-Local(||HDK-Derive-Local(| |HDK-Derive-Local(hdk0, 0)|| hdk0, 1) || hdk0, 2) | +-----------+--------+----++-----------------++-----------------+ | +---------------+ | | +-----------+------------------------+--------------------+ |Level 2 v v | |+-----------------------++-----------------------+ | ||HDK-Derive-Local( ||HDK-Derive-Local( | | || (pk1,sk1,salt1), 0)|| (pk1,sk1,salt1), 1)| | |+-----------------------++-----------------------+ | +---------------------------------------------------------+ The solution instance computes the Level 0 HDK at the root node using a deterministic function called HDK-Root. The HDK consists of a key pair (pk0, sk0), and a byte string salt0 to derive next-level keys. The solution instance computes the Level n > 0 value is using a deterministic function called HDK-Derive-Local. The function takes the previous-level salt as input, and a sequence number i starting at 0. The function returns a new HDK as output. 2.1.2. Remote key derivation example Instead of a locally generated index, an HDK can also be derived using a key handle as per Asynchronous Remote Key Generation (ARKG) [I-D.draft-bradleylundberg-cfrg-arkg-02]. To enable ARKG, the solution instance uses HDK-Seed-Remote and provides the output public key to an issuer. The issuer returns a key handle, using which the solution instance can derive a next-level key pair and seed using HDK-Derive-Remote. Locally derived parents can have remotely derived children. Remotely derived parents can have locally derived children. Dijkhuis Expires 20 April 2025 [Page 5] Internet-Draft HDK October 2024 2.1.3. Blinding example The next concept to illustrate is blinding. Blinding enables a solution instance to prove possession of a private key without disclosing the directly associated public key. This way, solutions can avoid linkability across readers of a document that is released with proof of possession. In this example, a document is issued in such a way that it can be presented with proof of possession using pk as derived using HDK. The solution instance applies the HDK-Authenticate function to the associated sk along with the device private key sk_device and reader- provided reader_data. The output is device_data, which the solution instance can subsequently use to prove possession to the reader. The reader does not need to be aware that HDK was used. In secure cryptographic device +-----------+ |sk_device +-------------+ +-----------+ | ------------- | HDK in | solution | instance v +-----------+ +-----------+ HDK-Authenticate->|device_data| |pk | ^ ^ +-----------+ +-----------+ | | +-----------+ | | |sk +-------+ | +-----------+ | ------------- | +-----------+ | |reader_data+-------------+ +-----------+ Blinding methods can be constructed such that the secure cryptographic device does not need to be designed for it. In such cases, sk_device does not contain the value of the private device key but a reference to it. 2.2. Instantiation parameters The parameters of an HDK instantiation are: * ID: A domain separation tag, represented as a string of ASCII bytes. Dijkhuis Expires 20 April 2025 [Page 6] Internet-Draft HDK October 2024 * Nk: The amount of bytes needed to create a uniformly random key. Note that Nk usually needs to be higher than the size of the key space, for example to maintain uniform distribution when deriving RNG({1,2,...,n-1}) from RNG({0,1,2,...,2^k-1}) for k=8*Nk and 2^k >= n as per [TR03111] Section 4.1.1 Algorithm 2. * Ns: The amount of bytes of a salt value with sufficient entropy. * key(bytes): Deterministically outputs a key pair (pk, sk) from a uniformly random string of Nk bytes. * serialize(pk): Serializes a public key pk to a fixed-size string. * expand(msg, DST, L): Outputs a uniformly random string of L bytes using a cryptographic hash or extendable-output function and input byte strings msg and DST. * BL: An asymmetric key blinding scheme [I-D.draft-bradleylundberg-cfrg-arkg-02], consisting of the functions: - BL-Blind-Public-Key(pk, tau, info): Outputs pk blinded with blinding factor tau and domain separation parameter info, both byte strings. - BL-Blind-Private-Key(sk, tau, info): Outputs sk blinded with blinding factor tau and domain separation parameter info, both byte strings. * ARKG: An asynchronous remote key generation instantiation [I-D.draft-bradleylundberg-cfrg-arkg-02], encapsulating an asymmetric key blinding scheme instantiation BL and a key encapsulation mechanism KEM, and consisting of the functions: - ARKG-Derive-Public-Key(pk, info): Outputs (pk', kh) where pk' is a derived public key and kh is a key handle to derive the associated private key, based on an ARKG public seed pk = (pk_kem, pk_bl) and application-specific information info. - ARKG-Derive-Private-Key(sk, kh, info): Outputs sk', a blinded private key based on ARKG private seed sk = (sk_kem, sk_bl), a key handle kh, and application-specific information info. * HDK-Root(pk_device, seed): See The HDK-Root function (Section 2.3). * HDK-Derive-Remote(pk_device, (pk, sk, salt), kh): See The HDK-Derive-Remote function (Section 2.6). Dijkhuis Expires 20 April 2025 [Page 7] Internet-Draft HDK October 2024 * HDK-Authenticate(sk_device, sk_hdk, reader_data): See The HDK-Authenticate function (Section 2.7). A concrete HDK instantiation MUST specify the instantiation of each of the above functions and values. 2.3. The HDK-Root function A solution instance creates a root HDK using a seed and a device public key. The generation of the seed is out of scope for this specification. Inputs: - pk_device, a device public key. - seed, a string of Ns bytes. Outputs: - pk, the root public key. - sk, the root private key. - salt, the root salt. def HDK-Root(pk_device, seed) 2.4. The HDK-Derive-Local function A solution instance derives a key pair and a salt from an HDK and an index. Inputs: - pk, a public key. - sk, a private key. - salt, a string of Ns bytes. - index, an integer between 0 and 2^32-1 (inclusive). Outputs: - pk', the next-level public key at the provided index. - sk', the next-level private key at the provided index. - salt', the next-level salt at the provided index. def HDK-Derive-Local((pk, sk, salt), index): msg = serialize(pk) || I2OSP(index, 4) okm = expand(msg, ID || salt, Nk + Ns) tau = okm[0:Nk] info = "HDK-Derive-Local" sk' = BL-Blind-Private-Key(sk, tau, info) pk' = BL-Blind-Public-Key(pk, tau, info) salt' = okm[Nk:] return (pk', sk', salt') Dijkhuis Expires 20 April 2025 [Page 8] Internet-Draft HDK October 2024 2.5. The HDK-Seed-Remote function A solution instance derives an ARKG seed from an HDK. Inputs: - pk, a public key. - sk, a private key. - salt, a string of Ns bytes. Outputs: - pk', an ARKG public seed. - sk', an ARKG private seed. def HDK-Seed-Remote((pk, sk, salt)): okm = expand("seed", ID || salt, Nk) (pk_kem, sk_kem) = key(okm) pk_bl = pk sk_bl = sk return ((pk_kem, pk_bl), (sk_kem, sk_bl)) Given an ARKG public seed pk, an issuer can derive an ARKG key handle kh and blinded public key pk' using: (pk', kh) = ARKG-Derive-Public-Key(pk, "") 2.6. The HDK-Derive-Remote function A solution instance derives a key pair and a salt from an HDK and an ARKG key handle. Inputs: - pk_device, the device public key. - pk, a public key. - sk, a private key. - salt, a string of Ns bytes. - kh, an ARKG key handle. Outputs: - pk', the next-level public key for the provided key handle. - sk', the next-level private key for the provided key handle. - salt', the next-level salt for the provided key handle. def HDK-Derive-Remote(pk_device, (pk, sk, salt), kh) Dijkhuis Expires 20 April 2025 [Page 9] Internet-Draft HDK October 2024 2.7. The HDK-Authenticate function A solution instance authenticates the device by creating a blinded proof applying the device private key and an HDK private key. This yields device data which it can use to prove possession of the device-bound document. The application-specific data for proof of possession is out of scope for HDK. Inputs: - sk_device, a (reference to a) device private key. - sk_hdk, an HDK private key. - reader_data, a byte string of solution instance-specific data. Outputs: - device_data, a byte string of device data for proving possession. def HDK-Authenticate(sk_device, sk_hdk, reader_data) Implementations of this function typically perform pre-processing on the reader_data, invoke the device key operation on the result, and perform post-processing on the output. A HDK instantiation MUST define HDK-Authenticate such that the device_data can be verified using the public key in the same HDK as sk_hdk. The reader does not need to know that HDK was applied: the public key will look like any other public key used for proofs of possession. 2.8. The HDK-Export-Blinding-Factor function When presenting multiple documents, a reader could require a proof that multiple keys are associated to a single device. Several protocols for a cryptographic proof of association are possible, such as [Verheul2024]. For example, a solution instance could prove that two elliptic curve keys B1 = [bf1]D and B2 = [bf2]D, where bf1 and bf2 are multiplicative blinding factors for a common device public key D, are associated using a zero-knowledge protocol. In this protocol, the solution instance proves that they know the discrete logarithm of B2 = [bf2/bf1]B1 with respect to generator B1. The construction of proof of association protocols requires availability to the prover of the blinding factors. The following function enables exporting these blinding factors. Dijkhuis Expires 20 April 2025 [Page 10] Internet-Draft HDK October 2024 Inputs: - pk, an HDK public key. - sk, an HDK private key. - salt, an HDK salt which is a string of Ns bytes. Outputs: - bf, an HDK private key which is used as a blinding factor. def HDK-Export-Blinding-Factor((pk, sk, salt)): bf = sk return bf Implementations SHOULD use a plausibly deniable proof of association protocol to ensure that the interactive presentation does not accidentally generate evidence that is potentially non-repudiable. 3. Generic HDK instantiations 3.1. Using elliptic curves Instantiations of HDK using elliptic curves requires the following cryptographic construct: * EC: An elliptic curve with elements of type Element and scalars of type Scalar, consisting of the functions: - EC-Add(A, B): Outputs the sum between Elements A and B. - EC-Scalar-Mult(A, k): Outputs the scalar multiplication between Element A and Scalar k. - EC-Scalar-Base-Mult(k): Outputs the scalar multiplication between the base Element and Scalar k. - EC-Order(): Outputs the order of the base Element. - EC-Serialize-Element(A): Outputs a byte string representing Element A. These instantiations instantiate the following: Dijkhuis Expires 20 April 2025 [Page 11] Internet-Draft HDK October 2024 def serialize(pk): return EC-Serialize-Element(pk) def key(bytes): sk' = OS2IP(bytes) mod (EC-Order() - 1) sk = sk' + 1 pk = EC-Scalar-Base-Mult(sk) return (pk, sk) 3.2. Using ECDH message authentication codes for proof of possession Such instantiations of HDK use elliptic curves (see Using elliptic curves (Section 3.1)) and require the following cryptographic construct: * ECDH: An Elliptic Curve Key Agreement Algorithm - Diffie-Hellman (ECKA-DH) [TR03111] with elliptic curve EC, consisting of the functions: - ECDH-Create-Shared-Secret(sk_self, pk_other): Outputs a shared secret byte string representing an Element. In such instantiations, the reader provides an ephemeral public key reader_data. The HDK-Authenticate function returns device_data consisting of a binary encoded x-coordinate Z_AB of an ECDH operation with sk_device and sk_hdk. Subsequently, the solution instance creates a message authentication code (MAC), such as in ECDH-MAC authentication defined in [ISO18013-5]. The reader verifies this MAC by performing an ECDH operation with its ephemeral private key and the HDK public key. These instantiations instantiate the following: Dijkhuis Expires 20 April 2025 [Page 12] Internet-Draft HDK October 2024 def HDK-Root(pk_device, seed): msg = serialize(pk_device) okm = expand(msg, ID || seed, Nk + Ns) (_, sk') = key(okm[0:Nk]) pk' = EC-Scalar-Mult(pk_device, sk') salt' = okm[Nk:] return (pk', sk', salt') def HDK-Derive-Remote(pk_device, (pk, sk, salt), kh): (pk_arkg, sk_arkg) = HDK-Seed-Remote((pk, sk, salt)) sk' = ARKG-Derive-Private-Key(sk_arkg, kh, "") pk' = EC-Scalar-Mult(pk_device, sk') msg = serialize(pk') salt' = expand(msg, ID || salt, Ns) return (pk', sk', salt') def HDK-Authenticate(sk_device, sk_hdk, reader_data): P' = EC-Scalar-Mult(reader_data, sk_hdk) # Compute Z_AB within the secure cryptographic device. Z_AB = ECDH-Create-Shared-Secret(sk_device, P') return Z_AB 3.3. Using EC-SDSA signatures for proof of possession Such instantiations of HDK use elliptic curves (see Using elliptic curves (Section 3.1)) require the following cryptographic construct: * DSA: an EC-SDSA (Schnorr) digital signature algorithm [TR03111], consisting of the functions: - DSA-Sign(sk, message): Outputs the signature (c, r) created using private signing key sk over byte string message. - DSA-Verify(signature, pk, message): Outputs whether signature is a signature over message using public verification key pk. - DSA-Serialize(c, r): Outputs the byte array serialization of the signature (c, r). - DSA-Deserialize(bytes): Outputs the signature (c, r) represented by byte string bytes. The reader MUST create an input byte string reader_data with sufficient entropy for each challenge. Dijkhuis Expires 20 April 2025 [Page 13] Internet-Draft HDK October 2024 The reader MUST verify the proof device_data using DSA-Verify with the HDK public key. def HDK-Root(pk_device, seed): msg = serialize(pk_device) okm = expand(msg, ID || seed, Nk + Ns) (pk_blind, sk') = key(okm[0:Nk]) pk' = EC-Add(pk_device, pk_blind) salt' = okm[Nk:] return (pk', sk', salt') def HDK-Derive-Remote(pk_device, (pk, sk, salt), kh): (pk_arkg, sk_arkg) = HDK-Seed-Remote((pk, sk, salt)) sk' = ARKG-Derive-Private-Key(sk_arkg, kh, "") pk' = EC-Add(pk_device, EC-Scalar-Base-Mult(sk')) msg = serialize(pk') salt' = expand(msg, ID || salt, Ns) return (pk', sk', salt') def HDK-Authenticate(sk_device, sk_hdk, reader_data): # Compute signature within the secure cryptographic device. signature = DSA-Sign(sk_device, reader_data) (c, s) = DSA-Deserialize(proof) s' = s + c * sk_hdk mod EC-Order() proof = DSA-Serialize(c, s') return proof 3.4. Using ECDSA signatures for proof of possession Due to potential patent claims, this document does not specify an implementation for threshold ECDSA. 4. Concrete HDK instantiations The RECOMMENDED instantiation is the HDK-ECDH-P256. This avoids the risk of having the holder unknowingly producing a potentially non- repudiable signature over reader-provided data. Secure cryptographic devices that enable a high level of assurance typically support managing ECDH keys with the P-256 elliptic curve. 4.1. HDK-ECDH-P256 This instantiation uses ECDH (see Using ECDH message authentication codes for proof of possession (Section 3.2)). * ID: "HDK-ECDH-P256-v1" Dijkhuis Expires 20 April 2025 [Page 14] Internet-Draft HDK October 2024 * Nr: 48 * Ns: 32 * expand: expand_message_xmd from [RFC9380] with: - H: SHA-256 [FIPS180-4] - b_in_bytes: 32 - s_in_bytes: 64 * ARKG: ARKG instantiation as described in [I-D.draft-bradleylundberg-cfrg-arkg-02] with the identifier ARKG- P256MUL-ECDH, KEM as defined above, and BL with elliptic curve arithmetic as described in [I-D.draft-bradleylundberg-cfrg-arkg-02] Section 3.1, but with multiplicative instead of additive blinding. * EC: The NIST curve secp256r1 (P-256) [SEC2]. * ECDH: ECKA-DH with curve EC The holder MUST generate sk_device as an ECDH private key in the secure cryptographic device. 4.2. HDK-ECSDSA-P256 This instantiation uses EC-SDSA (see Using EC-SDSA signatures for proof of possession (Section 3.3)). * ID: "HDK-ECSDSA-P256-v1" * Nr: 48 * Ns: 32 * expand: expand_message_xmd from [RFC9380] with: - H: SHA-256 [FIPS180-4] - b_in_bytes: 32 - s_in_bytes: 64 Dijkhuis Expires 20 April 2025 [Page 15] Internet-Draft HDK October 2024 * ARKG: ARKG instantiation as described in [I-D.draft-bradleylundberg-cfrg-arkg-02] with the identifier ARKG- P256ADD-ECDH, KEM as defined above, and BL with elliptic curve arithmetic as described in [I-D.draft-bradleylundberg-cfrg-arkg-02] Section 3.1. * EC: The NIST curve secp256r1 (P-256) [SEC2]. * DSA: EC-SDSA-opt (the optimised EC-SDSA) with curve EC. The holder MUST generate sk_device as a DSA private key in the secure cryptographic device. 5. Application considerations 5.1. Secure cryptographic device The HDK algorithm assumes that the holder controls a secure cryptographic device that protects the device key pair (pk_device, sk_device). The device key is under sole control of the holder. In the context of [EU2024-1183], this device is typically called a Wallet Secure Cryptographic Device (WSCD), running a personalised Wallet Secure Cryptographic Application (WSCA) that exposes a Secure Cryptographic Interface (SCI) to a Wallet Instance (WI) running on a User Device (UD). The WSCD is certified to protect access to the device private key with high attack potential resistance to achieve high level of assurance authentication as per [EU2015-1502]. This typically means that the key is associated with a strong possession factor and with a rate-limited Personal Identification Number (PIN) check as a knowledge factor, and the verification of both factors actively involve the WSCD. An example deployment of HDK in this context is illustrated below. Dijkhuis Expires 20 April 2025 [Page 16] Internet-Draft HDK October 2024 +---------------------+ +----------------------+ |Issuer infrastructure| |User Device (UD) | | | | | |+-------------------+|OpenID4VCI|+--------------------+| ||Issuer service |<----------++Wallet Instance (WI)|| || || |++-------------------+| ||Optionally an || +-+--------------------+ ||ARKG subordinate || |Secure ||party || |Cryptographic |+-------------------+| |Interface (SCI) +---------------------+ +v-------------------+ |Wallet Secure | |Cryptographic | Internal Manages |Application (WSCA) | registry <-----------+ | |Optionally an | |ARKG delegating | |party | ++-------------------+ |Uses +v-------------------+ Protects |Wallet secure | Device keys <-----------+cryptographic | |device (WSCD) | +--------------------+ The WSCA could be a single program or could be deployed in a distributed architecture, as illustrated below. +--------------+ |User device | |+------------+| ||WI || |++-----------+| | |SCI | |+v-----------+| ||WSCA agent || |++-----------+| +-+------------+ |WSCA protocol +v-----------+ |WSCA service| +------------+ In the case of a distributed WSCA, the UD contains a local component, here called WSCA agent, accessing an external and possibly remote WSCA service from one or more components over a WSCA protocol. For example, the WSCA agent may be a local web API client and the WSCA Dijkhuis Expires 20 April 2025 [Page 17] Internet-Draft HDK October 2024 service may be provided at a remote web API server. In such cases, typically the WSCA service receives a high-assurance security evaluation, while the WSCA agent is assessed to not be able to compromise the system's security guarantees. The internal registry can be managed by the WSCA agent, by the WSCA service, or by the combination. When the user device is a natural person’s mobile phone, WSCA agent management could provide better confidentiality protection against compromised WSCA service providers. When the user device is a cloud server used by a legal person, and the legal person deploys its own WSCD, WSCA service management could provide better confidentiality protection against compromised Wallet Instance cloud providers. In a distributed WSCA architecture, the WSCA could internally apply distributed key generation. A description of this is out of scope for the current document. The HDK algorithm can support any of the following WSCD architectures: 1. Local external standalone device, for example: * GlobalPlatform secure element, running for example a Java Card applet as WSCA for: - Personal Identity Verification (PIV) - Fast IDentity Online 2 (FIDO2) 2. Local internal standalone programmable cryptographic chip, for example: * Smartphone embedded universal integrated circuit card (eUICC), running for example a Subscriber Identity Module (SIM) as WSCA; also called eSIM * Smartphone embedded secure element (eSE), running for example a Java Card applet as WSCA 3. Local internal preprogammed security platform, for example: * Android trusted execution environment acting as WSCA * Android StrongBox secure element acting as WSCA * iOS Secure Enclave system-on-chip acting as WSCA Dijkhuis Expires 20 April 2025 [Page 18] Internet-Draft HDK October 2024 * Trusted Platform Module (TPM) acting as WSCA 4. Remote HSM, for example: * Cryptographic module certified against EN 419221-5:2018 with a local client application providing a WSCA service, remotely controlled for example using: - PIV card as possession factor and PIN verification using a HSM-backed Device-Enhanced Augmented PAKE (an approach proposed by Sweden) - Android/iOS security platform or standalone device, applying asymmetric cryptography to enable detection of remote HSM corruption as described in [SCAL3] In all cases, the WSCD may implement a Cryptographic Service Provider [TR03181] to reduce the scope for Common Criteria certification of the WSCA. The solution proposal discussed herein works in all four WSCD architectures that support the required cryptographic primitives within the WSCD: * In the case of HDK-ECDH-P256: - P-256 ECDH key pair generation - P-256 ECDH key agreement * In the case of HDK-ECSDSA-P256: - P-256 EC-SDSA key pair generation - P-256 EC-SDSA signature creation The other HDK operations can be performed in a WSCA or WSCA agent running on any UD, including hostile ones with limited sandboxing capabilities, such as in a smartphone's rich execution environment or in a personal computer web browser. If the user enters the PIN in the WI instead of on the WSCD directly, the WI MUST process it directly after entering, the WI MUST keep the plaintext PIN confidential, and the WI MUST delete the PIN from memory as soon as the encrypted PIN or data derived from the PIN is passed over the SCI. Dijkhuis Expires 20 April 2025 [Page 19] Internet-Draft HDK October 2024 The rate-limiting of the PIN check MUST be managed within the WSCD or on securely managed SCI infrastructure. In particular, the rate- limiting MUST NOT be managed solely in local WI or WSCA agent software since it is assumed that attackers could modify this without detection. 5.2. Trust evidence Some issuers could require evidence from a solution provider of the security of the holder's cryptographic device. This evidence is in the context of [EU2024-1183] divided into initial "Wallet Trust Evidence" and related "Issuer Trust Evidence". Each is a protected document that contains a trust evidence public key associated with a private key that is protected in the secure cryptographic device. In HDK, these public keys are specified as follows. 5.2.1. Wallet Trust Evidence The Wallet Trust Evidence public key is the root HDK public key. To achieve reader unlinkability, the wallet SHOULD limit access to a trusted person identification document provider only. To prevent association across identities, the solution provider MUST before issuing Wallet Trust Evidence ensure that (a) a newly generated device key pair is used and (b) the wallet follows the protocol so that the HDK-Root output is bound to exactly this key. For (a), the solution provider could rely on freshness of a key attestation and ensure that each device public key is attested only once. For (b), the wallet could proof knowledge of sk' with a Schnorr non-interactive zero-knowledge proof [RFC8235] with base point pk_device. This would ensure,that the root blinding key sk' is not shared with the solution provider to reduce the risk of the solution provider unblinding future derived keys. 5.2.2. Issuer Trust Evidence The Issuer Trust Evidence public key can be any non-root HDK public key. The solution provider MUST verify that the wallet knows the associated private key before issuing Issuer Trust Evidence. The solution provider MUST ensure that sk_device is under sole control of the solution instance holder. To achieve reader unlinkability, the solution instance MUST limit access of Issuer Trust Evidence to a single issuer. Subsequent issuers within the same HDK tree do not need to receive any Issuer Trust Evidence, since they can derive equally secure keys by applying ARKG to presented keys attested by trusted (other) issuers. Dijkhuis Expires 20 April 2025 [Page 20] Internet-Draft HDK October 2024 5.3. Applying HDK in OpenID for Verifiable Credential Issuance In [draft-OpenID4VCI], the following terminology applies: +===================+===================+ | OpenID4VCI | HDK | +===================+===================+ | Credential | attestation | +-------------------+-------------------+ | Credential Issuer | issuer | +-------------------+-------------------+ | Verifier | reader | +-------------------+-------------------+ | Wallet | solution instance | +-------------------+-------------------+ Table 1 HDK enables solution instances and issuers cooperatively to establish the cryptographic key material that issued attestations will be bound to. For asynchronous batch issuance, HDK proposes an update to the OpenID4VCI endpoints. This proposal is under discussion in openid/ OpenID4VCI#359 (https://github.com/openid/OpenID4VCI/issues/359). In the update, the solution instance shares an ARKG public seed with the issuer, and the issuer shares a key handle for each attestation, generated using: ARKG-Derive-Public-Key(key_generation_public_key, "") 6. Security considerations 6.1. Confidentiality of key handles The key handles MUST be considered confidential, since they provide knowledge about the blinding factors. Compromise of this knowledge could introduce undesired linkability. In HDK, both the holder and the issuer know the key handle during issuance. In an alternative to HDK, the holder independently generates blinded key pairs and proofs of association, providing the issuer with zero knowledge about the blinding factors. However, this moves the problem: the proofs of association would now need to be considered confidential. 7. References Dijkhuis Expires 20 April 2025 [Page 21] Internet-Draft HDK October 2024 7.1. Normative References [FIPS180-4] National Institute of Standards and Technology (NIST), "Secure Hash Standard (SHS)", FIPS 180-4, DOI 10.6028/NIST.FIPS.180-4, June 2012, . [I-D.draft-bradleylundberg-cfrg-arkg-02] Lundberg, E. and J. Bradley, "The Asynchronous Remote Key Generation (ARKG) algorithm", Work in Progress, Internet- Draft, draft-bradleylundberg-cfrg-arkg-02, 27 May 2024, . [ISO18013-5] ISO/IEC, "Personal identification - ISO-compliant driving licence - Part 5: Mobile driving licence (mDL) application", ISO/IEC 18013-5:2021, September 2019, . [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, March 1997, . [RFC7800] Jones, M., Bradley, J., and H. Tschofenig, "Proof-of- Possession Key Semantics for JSON Web Tokens (JWTs)", RFC 7800, DOI 10.17487/RFC7800, April 2016, . [RFC8017] Moriarty, K., Ed., Kaliski, B., Jonsson, J., and A. Rusch, "PKCS #1: RSA Cryptography Specifications Version 2.2", RFC 8017, DOI 10.17487/RFC8017, November 2016, . [RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, May 2017, . [RFC8235] Hao, F., Ed., "Schnorr Non-interactive Zero-Knowledge Proof", RFC 8235, DOI 10.17487/RFC8235, September 2017, . [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, . Dijkhuis Expires 20 April 2025 [Page 22] Internet-Draft HDK October 2024 [SEC2] Certicom Research, "SEC 2: Recommended Elliptic Curve Domain Parameters, Version 2.0", SEC 2 Version 2.0, January 2010, . [TR03111] Federal Office for Information Security (BSI), "Elliptic Curve Cryptography", BSI TR-03111 Version 2.10, June 2018, . 7.2. Informative References [BIP32] Wuille, P., "Hierarchical Deterministic Wallets", BIP 32, February 2021, . [draft-OpenID4VCI] Lodderstedt, T., Yasuda, K., and T. Looker, "OpenID for Verifiable Credential Issuance, draft 13", 8 February 2024, . [EU2015-1502] European Commission, "Commission Implementing Regulation (EU) 2015/1502 of 8 September 2015 on setting out minimum technical specifications and procedures for assurance levels for electronic identification means", (EU) 2015/1502, September 2025, . [EU2024-1183] The European Parliament and the Council of the European Union, "Amending Regulation (EU) No 910/2014 as regards establishing the European Digital Identity Framework", (EU) 2024/1183, April 2024, . [SCAL3] Cleverbase ID B.V., "SCAL3: Verify that systems operate under your sole control, version de8c5ae", March 2024, . Dijkhuis Expires 20 April 2025 [Page 23] Internet-Draft HDK October 2024 [TR03181] Federal Office for Information Security (BSI), "Cryptographic Service Provider 2 (CSP2)", BSI TR-03181 Version 0.94, April 2023, . [Verheul2024] Verheul, E., "Attestation Proof of Association – provability that attestation keys are bound to the same hardware and person", 18 September 2024, . Acknowledgements This design is based on ideas introduced to the EU Digital Identity domain by Peter Lee Altmann. Helpful feedback came from Emil Lundberg, John Bradley and Remco Schaar. Contributors Micha Kraus Author's Address Sander Dijkhuis (editor) Cleverbase Email: mail@sanderdijkhuis.nl Dijkhuis Expires 20 April 2025 [Page 24]