Internet-Draft | Authentication Credentials DTLS profile | July 2023 |
Tiloca & Mattsson | Expires 11 January 2024 | [Page] |
This document updates the Datagram Transport Layer Security (DTLS) Profile for Authentication and Authorization for Constrained Environments (ACE). In particular, it specifies the use of additional formats of authentication credentials for establishing a DTLS session, when peer authentication is based on asymmetric cryptography. Therefore, this document updates RFC 9202. What is defined in this document is seamlessly applicable also if the profile uses Transport Layer Security (TLS) instead.¶
This note is to be removed before publishing as an RFC.¶
Discussion of this document takes place on the Authentication and Authorization for Constrained Environments Working Group mailing list (ace@ietf.org), which is archived at https://mailarchive.ietf.org/arch/browse/ace/.¶
Source for this draft and an issue tracker can be found at https://gitlab.com/crimson84/draft-tiloca-ace-authcred-dtls-profile.¶
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The Authentication and Authorization for Constrained Environments (ACE) framework [RFC9200] defines an architecture to enforce access control for constrained devices. A Client (C) requests an evidence of granted permissions from an Authorization Server (AS) in the form of an access token, then uploads the access token to the target Resource Server (RS), and finally accesses protected resources at the RS according to what is specified in the access token.¶
The framework has as main building blocks the OAuth 2.0 framework [RFC6749], the Constrained Application Protocol (CoAP) [RFC7252] for message transfer, CBOR [RFC8949] for compact encoding, and COSE [RFC9052][RFC9053] for self-contained protection of access tokens.¶
Separate profile documents define in detail how the participants in the ACE architecture communicate, especially as to the security protocols that they use. In particular, the ACE profile defined in [RFC9202] specifies how Datagram Transport Layer Security (DTLS) [RFC6347][RFC9147] is used to protect communications with transport-layer security in the ACE architecture. The profile has also been extended in [I-D.ietf-ace-extend-dtls-authorize], in order to allow the alternative use of Transport Layer Security (TLS) [RFC8446] when CoAP is transported over TCP or WebSockets [RFC8323].¶
The DTLS profile [RFC9202] allows C and RS to establish a DTLS session with peer authentication based on symmetric or asymmetric cryptography. For the latter case, the profile defines an RPK mode (see Section 3.2 of [RFC9202]), where authentication relies on the public keys of the two peers as raw public keys [RFC7250].¶
That is, C specifies its public key to the AS when requesting an access token, and the AS provides such public key to the target RS as included in the issued access token. Upon issuing the access token, the AS also provides C with the public key of the RS. Then, C and RS use their asymmetric keys when performing the DTLS handshake, as defined in [RFC7250].¶
Per [RFC9202], the DTLS profile admits only a COSE Key object [RFC9052] as the format of authentication credentials to use for transporting the public keys of C and RS, as raw public keys. However, it is desirable to enable additional types of authentication credentials, as enhanced raw public keys or as public certificates.¶
This document enables such additional formats, by defining how the public keys of C and RS can be specified as CBOR Web Token (CWT) Claims Sets (CCSs) [RFC8392], or X.509 certificates [RFC5280], or C509 certificates [I-D.ietf-cose-cbor-encoded-cert]. In particular, this document updates [RFC9202] as follows.¶
When using the updated RPK mode, both public keys can be transported as a CCS, or instead only one can be transported as a CCS while the other one as a COSE Key object.¶
Also, the RPK mode and the certificate mode can be combined. That is, it is possible that one of the two authentication credentials is a public certificate, while the other one is a raw public key.¶
These updates to the DTLS profile rely on the CWT Confirmation Methods "kccs", "x5bag", "x5chain", "c5b", and "c5c", which are defined in [I-D.ietf-ace-edhoc-oscore-profile].¶
What is defined in this document is seamlessly applicable if TLS is used instead, as defined in [I-D.ietf-ace-extend-dtls-authorize].¶
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.¶
Readers are expected to be familiar with the terms and concepts described in the ACE framework for Authentication and Authorization [RFC9200][RFC9201] and its DTLS profile [RFC9202], as well as with terms and concepts related to CBOR Web Tokens (CWTs) [RFC8392] and CWT Confirmation Methods [RFC8747].¶
The terminology for entities in the considered architecture is defined in OAuth 2.0 [RFC6749]. In particular, this includes Client (C), Resource Server (RS), and Authorization Server (AS).¶
Readers are also expected to be familiar with the terms and concepts related to the CoAP protocol [RFC7252], CBOR [RFC8949], COSE [RFC9052][RFC9053], the DTLS protocol suite [RFC6347][RFC9147], and the use of raw public keys in DTLS [RFC7250].¶
Note that, unless otherwise indicated, the term "endpoint" is used here following its OAuth definition, aimed at denoting resources such as /token and /introspect at the AS, and /authz-info at the RS. This document does not use the CoAP definition of "endpoint", which is "An entity participating in the CoAP protocol."¶
This document also refers to the term "authentication credential", which denotes the information associated with an entity, including that entity's public key and parameters associated with the public key. Examples of authentication credentials are CWT Claims Sets (CCSs) [RFC8392], X.509 certificates [RFC5280], and C509 certificates [I-D.ietf-cose-cbor-encoded-cert].¶
Examples throughout this document are expressed in CBOR diagnostic notation without the tag and value abbreviations.¶
The rest of this section updates Section 3.2 of [RFC9202], by defining how the raw public key of C and RS can be transported as a CCS [RFC8392], as an alternative to a COSE Key object [RFC9052]. Note that only the differences from [RFC9202] are compiled below.¶
If the raw public key of C is transported as a CCS, the following applies.¶
If the raw public key of RS is transported as a CCS, the following applies.¶
For the "req_cnf" parameter of the Access Token Request, the "rs_cnf" parameter of the Access Token Response, and the "cnf" claim of the access token, the Confirmation Method "kccs" structure and its identifier are defined in [I-D.ietf-ace-edhoc-oscore-profile].¶
It is not required that both public keys are transported as a CCS. That is, one of the two authentication credentials can be a CCS, while the other one can be a COSE Key object as per Section 3.2 of [RFC9202].¶
Figure 1 shows an example of Access Token Request from C to the AS.¶
Figure 2 shows an example of Access Token Response from the AS to C.¶
This section defines a new certificate mode of the DTLS profile, which enables the transport of public keys of C and RS as public certificates.¶
Compared to the RPK mode defined in Section 3.2 of [RFC9202] and extended in Section 2 of this document, the certificate mode displays the following differences.¶
If the authentication credential AUTH_CRED_C of C is a public certificate, the following applies.¶
The "req_cnf" parameter [RFC9201] of the Access Token Request (see Section 5.8.1 of [RFC9200] specifies AUTH_CRED_C as follows.¶
The "cnf" claim of the access token that the AS provides to C in the Access Token Response (see Section 5.8.2 of [RFC9200]) specifies AUTH_CRED_C as follows.¶
If the authentication credential AUTH_CRED_RS of RS is a public certificate, the following applies.¶
The "rs_cnf" parameter [RFC9201] of the Access Token Response specifies AUTH_CRED_RS as follows.¶
For the "req_cnf" parameter of the Access Token Request, the "rs_cnf" parameter of the Access Token Response, and the "cnf" claim of the access token, the Confirmation Method "c5c" and "c5b" structures and their identifiers are defined in [I-D.ietf-ace-edhoc-oscore-profile].¶
When using either of the structures "x5chain", "x5bag", "c5c" and "c5b", i.e., either a chain or a bag of certificates, the specified authentication credential is just the end entity X.509 or C509 certificate.¶
As per [RFC6347][RFC9147], a public certificate is specified in the Certificate message of the DTLS handshake. For X.509 certificates, the TLS Certificate Type is "X509", as defined in [RFC6091]. For C509 certificates, the TLS certificate type is "C509 Certificate", as defined in [I-D.ietf-cose-cbor-encoded-cert].¶
It is not required that AUTH_CRED_C and AUTH_CRED_RS are both X.509 certificates or both C509 certificates.¶
Also, one of the two authentication credentials can be a public certificate, while the other one can be a raw public key. This is consistent with the admitted, combined use of raw public keys and certificates, as discussed in Section 5.3 of [RFC7250].¶
Figure 3 shows an example of Access Token Request from C to the AS. In the example, C specifies its authentication credential by means of an "x5chain" structure, including only its own X.509 certificate.¶
Figure 4 shows an example of Access Token Response from the AS to C. In the example, the AS specifies the authentication credential of RS by means of an "x5chain" structure, including only the X.509 certificate of the RS.¶
The security considerations from [RFC9200] and [RFC9202] apply to this document as well.¶
When using public certificates as authentication credentials, the security considerations from Appendix C.2 of [RFC8446] apply.¶
When using X.509 certificates as authentication credentials, the security considerations from [RFC5280], [RFC6818], [RFC8398], and [RFC8399] apply.¶
When using C509 certificates as authentication credentials, the security considerations from [I-D.ietf-cose-cbor-encoded-cert] apply.¶
This document has no actions for IANA.¶
The authors sincerely thank Rikard Höglund and Göran Selander for their comments and feedback. The work on this document has been partly supported by the H2020 project SIFIS-Home (Grant agreement 952652).¶