Network Working Group | I. Liusvaara |
Internet-Draft | Independent |
Intended status: Standards Track | July 8, 2016 |
Expires: January 9, 2017 |
CFRG ECDH and signatures in JOSE
draft-ietf-jose-cfrg-curves-05
This document defines how to use the Diffie-Hellman algorithms "X25519" and "X448" as well as the signature algorithms "Ed25519" and "Ed448" from the IRTF CFRG elliptic curves work in JOSE.
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 http://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 January 9, 2017.
Copyright (c) 2016 IETF Trust and the persons identified as the document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://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. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License.
Internet Research Task Force (IRTF) Crypto Forum Research Group (CFRG) selected new Diffie-Hellman algorithms ("X25519" and "X448"; [RFC7748]) and signature algorithms ("Ed25519" and "Ed448"; [I-D.irtf-cfrg-eddsa]) for asymmetric key cryptography. This document defines how those algorithms are to be used in JOSE in interoperable manner.
This document defines the conventions to be used in the context of [RFC7515], [RFC7516], and [RFC7517].
While the CFRG also defined two pairs of isogenous elliptic curves that underlie these algorithms, these curves are not directly exposed, as the algorithms laid on top are sufficient for the purposes of JOSE and are much easier to use. (Trying to apply ECDSA to those curves leads to nasty corner-cases and produces odd results.)
All inputs to and outputs from the the ECDH and signature functions are defined to be octet strings, with the exception of outputs of verification functions, which are booleans.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in [RFC2119].
"JWS Signing Input" and "JWS Signature" are defined by [RFC7515].
"Key Agreement with Elliptic Curve Diffie-Hellman Ephemeral Static" is defined by [RFC7518], section 4.6.
The JOSE key format ("JSON Web Key (JWK)") is defined by [RFC7517] and thumbprints for it ("JSON Web Key (JWK) Thumbprint") in [RFC7638].
A new key type (kty) value "OKP" (Octet Key Pair) is defined for public key algorithms that use octet strings as private and public keys. It has the following parameters:
Note: Do not assume that there is an underlying elliptic curve, despite the existence of the "crv" and "x" parameters. (For instance, this key type could be extended to represent DH algorithms based on hyperelliptic surfaces.)
When calculating JWK Thumbprints [RFC7638], the three public key fields are included in the hash input in lexicographic order: "crv", "kty", and "x".
For purpose of using EdDSA for signing data using "JSON Web Signature (JWS)" ([RFC7515]), algorithm "EdDSA" is defined here, to be applied as the value of the "alg" parameter.
The following key subtypes are defined here for use with EdDSA:
"crv" EdDSA Variant Ed25519 Ed25519 Ed448 Ed448
The key type used with these keys is "OKP" and the algorithm used for signing is "EdDSA". These subtypes MUST NOT be used for ECDH-ES.
The EdDSA variant used is determined by the subtype of the key (Ed25519 for "Ed25519" and Ed448 for "Ed448").
Signing for these is preformed by applying the signing algorithm defined in [I-D.irtf-cfrg-eddsa] to the private key (as private key), public key (as public key) and the JWS Signing Input (as message). The resulting signature is the JWS Signature. All inputs and outputs are octet strings.
Verification is performed by applying the verification algorithm defined in [I-D.irtf-cfrg-eddsa] to the public key (as public key), the JWS Signing Input (as message) and the JWS Signature (as signature). All inputs are octet strings. If the algorithm accepts, the signature is valid; otherwise, the signature is invalid.
The following key subtypes are defined here for purpose of "Key Agreement with Elliptic Curve Diffie-Hellman Ephemeral Static" (ECDH-ES):
"crv" ECDH Function Applied X25519 X25519 X448 X448
The key type used with these keys is "OKP". These subtypes MUST NOT be used for signing.
[RFC7518] Section 4.6 defines the ECDH-ES algorithms "ECDH-ES+A128KW", "ECDH-ES+A192KW", "ECDH-ES+A256KW" and "ECDH-ES".
The "x" parameter of the "epk" field is set as follows:
Apply the appropriate ECDH function to the ephemeral private key (as scalar input) and the standard basepoint (as u-coordinate input). The base64url encoding of the output is the value for the "x" parameter of the "epk" field. All inputs and outputs are octet strings.
The Z value (raw key agreement output) for key agreement (to be used in subsequent KDF as per [RFC7518] section 4.6.2) is determined as follows:
Apply the appropriate ECDH function to the ephemeral private key (as scalar input) and receiver public key (as u-coordinate input). The output is the Z value. All inputs and outputs are octet strings.
Security considerations from [RFC7748] and [I-D.irtf-cfrg-eddsa] apply here.
Do not separate key material from information about what key subtype it is for. When using keys, check that the algorithm is compatible with the key subtype for the key. To do otherwise opens the system up to attacks via mixing up algorithms. It is particularly dangerous to mix up signature and MAC algorithms.
Although for Ed25519 and Ed448, the signature binds the key used for signing, do not assume this, as there are many signature algorithms that fail to make such a binding. If key-binding is desired, include the key used for signing either inside the JWS protected header or the data to sign.
If key generation or batch signature verification is performed, a well-seeded cryptographic random number generator is REQUIRED. Signing and non-batch signature verification are deterministic operations and do not need random numbers of any kind.
The JWA ECDH-ES KDF construction does not mix keys into the final shared secret. While in key exchange such could be a bad mistake, here either the receiver public key has to be chosen maliciously or the sender has to be malicious in order to cause problems. In either case, all security evaporates.
The nominal security strengths of X25519 and X448 are ~126 and ~223 bits. Therefore, using 256-bit symmetric encryption (especially key wrapping and encryption) with X448 is RECOMMENDED.
Thanks to Michael B. Jones for his comments on an initial pre-draft and editorial help.
Thanks to Matt Miller for some editorial help.
The following is added to the "JSON Web Key Types" registry:
The following is added to the "JSON Web Key Parameters" registry:
The following is added to the "JSON Web Signature and Encryption Algorithms" registry:
The following is added to the "JSON Web Key Elliptic Curve" registry:
[RFC2119] | Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, March 1997. |
[RFC4648] | Josefsson, S., "The Base16, Base32, and Base64 Data Encodings", RFC 4648, DOI 10.17487/RFC4648, October 2006. |
[RFC7515] | Jones, M., Bradley, J. and N. Sakimura, "JSON Web Signature (JWS)", RFC 7515, DOI 10.17487/RFC7515, May 2015. |
[RFC7517] | Jones, M., "JSON Web Key (JWK)", RFC 7517, DOI 10.17487/RFC7517, May 2015. |
[RFC7518] | Jones, M., "JSON Web Algorithms (JWA)", RFC 7518, DOI 10.17487/RFC7518, May 2015. |
[RFC7638] | Jones, M. and N. Sakimura, "JSON Web Key (JWK) Thumbprint", RFC 7638, DOI 10.17487/RFC7638, September 2015. |
[RFC7748] | Langley, A., Hamburg, M. and S. Turner, "Elliptic Curves for Security", RFC 7748, DOI 10.17487/RFC7748, January 2016. |
[I-D.irtf-cfrg-eddsa] | Josefsson, S. and I. Liusvaara, "Edwards-curve Digital Signature Algorithm (EdDSA)", Internet-Draft draft-irtf-cfrg-eddsa-05, March 2016. |
[RFC7516] | Jones, M. and J. Hildebrand, "JSON Web Encryption (JWE)", RFC 7516, DOI 10.17487/RFC7516, May 2015. |
To the extent possible, the examples use material taken from test vectors of [RFC7748] and [I-D.irtf-cfrg-eddsa].
{"kty":"OKP","crv":"Ed25519", "d":"nWGxne_9WmC6hEr0kuwsxERJxWl7MmkZcDusAxyuf2A" "x":"11qYAYKxCrfVS_7TyWQHOg7hcvPapiMlrwIaaPcHURo"}
The hexadecimal dump of private key is:
9d 61 b1 9d ef fd 5a 60 ba 84 4a f4 92 ec 2c c4 44 49 c5 69 7b 32 69 19 70 3b ac 03 1c ae 7f 60
And of the public key is:
d7 5a 98 01 82 b1 0a b7 d5 4b fe d3 c9 64 07 3a 0e e1 72 f3 da a6 23 25 af 02 1a 68 f7 07 51 1a
This is the public parts of the previous private key (which just omits "d"):
{"kty":"OKP","crv":"Ed25519", "x":"11qYAYKxCrfVS_7TyWQHOg7hcvPapiMlrwIaaPcHURo"}
The JWK Thumbprint canonicalization of the two above examples (with linebreak inserted for formatting reasons) is:
{"crv":"Ed25519","kty":"OKP","x":"11qYAYKxCrfVS_7TyWQHOg7hcvPapiMlrwI aaPcHURo"}
Which has the SHA-256 hash (in hexadecimal) of 90facafea9b1556698540f70c0117a22ea37bd5cf3ed3c47093c1707282b4b89, which results in the base64url encoded JWK Thumbprint representation of "kPrK_qmxVWaYVA9wwBF6Iuo3vVzz7TxHCTwXBygrS4k".
The JWS protected header is:
{"alg":"EdDSA"}
This has the base64url encoding of:
eyJhbGciOiJFZERTQSJ9
The payload is (text):
Example of Ed25519 signing
This has the base64url encoding of:
RXhhbXBsZSBvZiBFZDI1NTE5IHNpZ25pbmc
The JWS signing input is (concatenation of base64url encoding of the (protected) header, a dot and base64url encoding of the payload) is:
eyJhbGciOiJFZERTQSJ9.RXhhbXBsZSBvZiBFZDI1NTE5IHNpZ25pbmc
Applying the Ed25519 signing algorithm using the private key, public key, and the JWS signing input yields the signature (hex):
86 0c 98 d2 29 7f 30 60 a3 3f 42 73 96 72 d6 1b 53 cf 3a de fe d3 d3 c6 72 f3 20 dc 02 1b 41 1e 9d 59 b8 62 8d c3 51 e2 48 b8 8b 29 46 8e 0e 41 85 5b 0f b7 d8 3b b1 5b e9 02 bf cc b8 cd 0a 02
Converting this to base64url yields:
hgyY0il_MGCjP0JzlnLWG1PPOt7-09PGcvMg3AIbQR6dWbhijcNR4ki4iylGjg5BhVsPt 9g7sVvpAr_MuM0KAg
So the compact serialization of the JWS is (concatenation of signing input, a dot, and base64url encoding of the signature):
eyJhbGciOiJFZERTQSJ9.RXhhbXBsZSBvZiBFZDI1NTE5IHNpZ25pbmc.hgyY0il_MGCj P0JzlnLWG1PPOt7-09PGcvMg3AIbQR6dWbhijcNR4ki4iylGjg5BhVsPt9g7sVvpAr_Mu M0KAg
The JWS from above example is:
eyJhbGciOiJFZERTQSJ9.RXhhbXBsZSBvZiBFZDI1NTE5IHNpZ25pbmc.hgyY0il_MGCj P0JzlnLWG1PPOt7-09PGcvMg3AIbQR6dWbhijcNR4ki4iylGjg5BhVsPt9g7sVvpAr_Mu M0KAg
This has 2 dots in it, so it might be valid a JWS. Base64url decoding the protected header yields:
{"alg":"EdDSA"}
So this is an EdDSA signature. Now the key has: "kty":"OKP" and "crv":"Ed25519", so the signature is Ed25519 signature.
The signing input is the part before second dot:
eyJhbGciOiJFZERTQSJ9.RXhhbXBsZSBvZiBFZDI1NTE5IHNpZ25pbmc
Applying Ed25519 verification algorithm to the public key, JWS signing input and the signature yields true. So the signature is valid. The message is the base64url decoding of the part between the dots:
Example of Ed25519 Signing
The public key to encrypt to is:
{"kty":"OKP","crv":"X25519","kid":"Bob" "x":"3p7bfXt9wbTTW2HC7OQ1Nz-DQ8hbeGdNrfx-FG-IK08"}
The public key from the target key is (hex):
de 9e db 7d 7b 7d c1 b4 d3 5b 61 c2 ec e4 35 37 3f 83 43 c8 5b 78 67 4d ad fc 7e 14 6f 88 2b 4f
The ephemeral secret happens to be (hex):
77 07 6d 0a 73 18 a5 7d 3c 16 c1 72 51 b2 66 45 df 4c 2f 87 eb c0 99 2a b1 77 fb a5 1d b9 2c 2a
So the ephemeral public key is X25519(ephkey,G) (hex):
85 20 f0 09 89 30 a7 54 74 8b 7d dc b4 3e f7 5a 0d bf 3a 0d 26 38 1a f4 eb a4 a9 8e aa 9b 4e 6a
This is represented as the ephemeral public key value:
{"kty":"OKP","crv":"X25519", "x":"hSDwCYkwp1R0i33ctD73Wg2_Og0mOBr066SpjqqbTmo"}
So the protected header could, for example, be:
{"alg":"ECDH-ES+A128KW","epk":{"kty":"OKP","crv":"X25519", "x":"hSDwCYkwp1R0i33ctD73Wg2_Og0mOBr066SpjqqbTmo"}, "enc":"A128GCM","kid":"Bob"}
And the sender computes as the DH Z value as X25519(ephkey,recv_pub) (hex):
4a 5d 9d 5b a4 ce 2d e1 72 8e 3b f4 80 35 0f 25 e0 7e 21 c9 47 d1 9e 33 76 f0 9b 3c 1e 16 17 42
The receiver computes as the DH Z value as X25519(seckey,ephkey_pub) (hex):
4a 5d 9d 5b a4 ce 2d e1 72 8e 3b f4 80 35 0f 25 e0 7e 21 c9 47 d1 9e 33 76 f0 9b 3c 1e 16 17 42
Which is the same as the sender's value (the both sides run this through the KDF before using it as a direct encryption key or AES128-KW key).
The public key to encrypt to (with linebreak inserted for formatting reasons) is:
{"kty":"OKP","crv":"X448","kid":"Dave", "x":"PreoKbDNIPW8_AtZm2_sz22kYnEHvbDU80W0MCfYuXL8PjT7QjKhPKcG3LV67D2 uB73BxnvzNgk"}
The public key from target key is (hex):
3e b7 a8 29 b0 cd 20 f5 bc fc 0b 59 9b 6f ec cf 6d a4 62 71 07 bd b0 d4 f3 45 b4 30 27 d8 b9 72 fc 3e 34 fb 42 32 a1 3c a7 06 dc b5 7a ec 3d ae 07 bd c1 c6 7b f3 36 09
The ephemeral secret happens to be (hex):
9a 8f 49 25 d1 51 9f 57 75 cf 46 b0 4b 58 00 d4 ee 9e e8 ba e8 bc 55 65 d4 98 c2 8d d9 c9 ba f5 74 a9 41 97 44 89 73 91 00 63 82 a6 f1 27 ab 1d 9a c2 d8 c0 a5 98 72 6b
So the ephemeral public key is X448(ephkey,G) (hex):
9b 08 f7 cc 31 b7 e3 e6 7d 22 d5 ae a1 21 07 4a 27 3b d2 b8 3d e0 9c 63 fa a7 3d 2c 22 c5 d9 bb c8 36 64 72 41 d9 53 d4 0c 5b 12 da 88 12 0d 53 17 7f 80 e5 32 c4 1f a0
This is packed into ephemeral public key value (linebreak inserted for formatting purposes):
{"kty":"OKP","crv":"X448", "x":"mwj3zDG34-Z9ItWuoSEHSic70rg94Jxj-qc9LCLF2bvINmRyQdlT1AxbEtqIEg1 TF3-A5TLEH6A"}
So the protected header could for example be (linebreak inserted for formatting purposes):
{"alg":"ECDH-ES+A256KW","epk":{"kty":"OKP","crv":"X448", "x":"mwj3zDG34-Z9ItWuoSEHSic70rg94Jxj-qc9LCLF2bvINmRyQdlT1AxbEtqIEg1 TF3-A5TLEH6A"},"enc":"A256GCM","kid":"Dave"}
And the sender computes as the DH Z value as X448(ephkey,recv_pub) (hex):
07 ff f4 18 1a c6 cc 95 ec 1c 16 a9 4a 0f 74 d1 2d a2 32 ce 40 a7 75 52 28 1d 28 2b b6 0c 0b 56 fd 24 64 c3 35 54 39 36 52 1c 24 40 30 85 d5 9a 44 9a 50 37 51 4a 87 9d
The receiver computes as the DH Z value as X448(seckey,ephkey_pub) (hex):
07 ff f4 18 1a c6 cc 95 ec 1c 16 a9 4a 0f 74 d1 2d a2 32 ce 40 a7 75 52 28 1d 28 2b b6 0c 0b 56 fd 24 64 c3 35 54 39 36 52 1c 24 40 30 85 d5 9a 44 9a 50 37 51 4a 87 9d
Which is the same as the sender's value (the both sides run this through KDF before using as direct encryption key or AES256-KW key).