Proof-of-Possession Key Semantics for CBOR Web Tokens (CWTs)Microsoftmbj@microsoft.comhttp://self-issued.info/RISE SICSScheelevaegen 17Lund223 70Swedenludwig@ri.seEricsson ABFärögatan 6Kista164 80Swedengoran.selander@ericsson.comSpotifyerdtman@spotify.comArm Ltd.6060Hall in TirolAustriaHannes.Tschofenig@arm.com
Security
ACECBOR Web TokenCWTProof-of-PossessionHolder-of-Key
This specification describes how to declare in a CBOR Web Token (CWT)
that the presenter of the CWT possesses a particular proof-of-possession key.
Being able to prove possession of a key is also sometimes described as
being the holder-of-key.
This specification provides equivalent functionality to
"Proof-of-Possession Key Semantics for JSON Web Tokens (JWTs)" (RFC 7800)
but using CBOR and CWTs rather than JSON and JWTs.
This specification describes how a CBOR Web Token (CWT) can declare
that the presenter of the CWT possesses a particular proof-of-possession (PoP) key.
Proof of possession of a key is also sometimes described as
being the holder-of-key.
This specification provides equivalent functionality to
"Proof-of-Possession Key Semantics for JSON Web Tokens (JWTs)"
but using CBOR and CWTs
rather than JSON and JWTs .
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
when, and only when, they appear in all capitals, as shown here.
This specification uses terms defined in
the CBOR Web Token (CWT) ,
CBOR Object Signing and Encryption (COSE) , and
Concise Binary Object Representation (CBOR)
specifications.
These terms are defined by this specification:
Party that creates the CWT and binds the claims about the subject to the
proof-of-possession key.
Party that proves possession of a private key (for asymmetric key cryptography)
or secret key (for symmetric key cryptography) to a recipient of a CWT.
In the context of OAuth, this party is also called the OAuth Client.
Party that receives the CWT containing the proof-of-possession key information from the presenter.
In the context of OAuth, this party is also called the OAuth Resource Server.
This specification provides examples in CBOR extended diagnostic
notation, as defined in Appendix G of .
The examples include line breaks for readability.
By including a cnf (confirmation) claim in a CWT,
the issuer of the CWT declares that the presenter possesses a particular key
and that the recipient can cryptographically confirm that
the presenter has possession of that key.
The value of the cnf claim is a CBOR map
and the members of that map identify the proof-of-possession key.
The presenter can be identified in one of several ways by the CWT,
depending upon the application requirements.
For instance, some applications may use
the CWT sub (subject) claim ,
to identify the presenter.
Other applications may use
the iss claim
to identify the presenter.
In some applications, the subject identifier might be relative to
the issuer identified by the iss (issuer) claim .
The actual mechanism used is dependent upon the application.
The case in which the presenter is the subject of the CWT is analogous to
Security Assertion Markup Language (SAML) 2.0 SubjectConfirmation usage.
The cnf claim in the CWT is used to carry confirmation methods. Some of
them use proof-of-possession keys while others do not. This design is
analogous to the SAML 2.0 SubjectConfirmation
element in which a number of different subject confirmation methods can
be included (including proof-of-possession key information).
The set of confirmation members that a
CWT must contain to be considered valid is context dependent
and is outside the scope of this specification.
Specific applications of CWTs will require implementations
to understand and process some confirmation members in particular ways.
However, in the absence of such requirements, all confirmation members
that are not understood by implementations MUST be ignored.
This specification establishes the
IANA "CWT Confirmation Methods" registry for these members
in and registers the members defined by this specification.
Other specifications can register
other members used for confirmation, including other members for
conveying proof-of-possession keys using different key
representations.
The cnf claim value MUST represent only a single
proof-of-possession key. At most one of the COSE_Key
and Encrypted_COSE_Key confirmation values defined
in may be present. Note that if an application
needs to represent multiple proof-of-possession keys in the same CWT, one way
for it to achieve this is to use other claim names, in addition to
cnf, to hold the additional proof-of-possession
key information. These claims could use the same syntax and semantics as the
cnf claim. Those claims would be defined by
applications or other specifications and could be registered in the
IANA "CBOR Web Token Claims" registry .
When the key held by the presenter is an asymmetric private key,
the COSE_Key member
is a COSE_Key
representing the corresponding asymmetric public key.
The following example demonstrates such a declaration
in the CWT Claims Set of a CWT:
The COSE_Key MUST contain the required key members for a COSE_Key of that key type
and MAY contain other COSE_Key members,
including the kid (Key ID) member.
The COSE_Key member MAY also be used for a COSE_Key
representing a symmetric key, provided that the CWT is encrypted
so that the key is not revealed to unintended parties.
The means of encrypting a CWT is explained in .
If the CWT is not encrypted, the symmetric key MUST be encrypted as described in . This procedure is equivalent to
the one defined in section 3.3 of .
When the key held by the presenter is a symmetric key,
the Encrypted_COSE_Key member
is an encrypted COSE_Key
representing the symmetric key
encrypted to a key known to the recipient
using COSE_Encrypt or COSE_Encrypt0.
The following example
illustrates a symmetric key that could subsequently be encrypted for use in the
Encrypted_COSE_Key member:
The COSE_Key representation
is used as the plaintext when encrypting the key.
The following example CWT Claims Set of a CWT
illustrates the use of an encrypted symmetric key as the
Encrypted_COSE_Key member value:
The example above was generated with the key:
The proof-of-possession key can also be identified using
a Key ID instead of communicating the actual key,
provided the recipient is able to obtain the identified key
using the Key ID.
In this case,
the issuer of a CWT declares that the presenter possesses a particular key
and that the recipient can cryptographically confirm
proof of possession of the key by the presenter by including a
cnf claim in the CWT
whose value is a CBOR map with the CBOR map containing a
kid member
identifying the key.
The following example demonstrates such a declaration
in the CWT Claims Set of a CWT:
The content of the kid value is application specific.
For instance, some applications may choose to use a cryptographic hash of the public key
value as the kid value.
Note that the use of a Key ID to identify a proof-of-possession key needs to be carefully circumscribed,
as described below and in .
In cases where the Key ID is not a cryptographic value derived from the key
or where not all of the parties involved are validating the cryptographic derivation,
implementers should expect collisions, where different keys are assigned the same Key ID.
Recipients of a CWT with a PoP key linked through only a Key ID should be prepared to handle
such situations.
In the world of constrained Internet of Things (IoT) devices,
there is frequently a restriction on the size of Key IDs,
either because of table constraints or a desire to keep message sizes small.
Note that the value of a Key ID for a specific key is not
necessarily the same for different parties. When sending a COSE
encrypted message with a shared key, the Key ID may be different on
both sides of the conversation, with the appropriate one being included
in the message based on the recipient of the message.
Proof of possession is often demonstrated by having the presenter sign
a value determined by the recipient using the key possessed by the presenter.
This value is sometimes called a "nonce" or a "challenge".
There are, however, also other means to demonstrate freshness of the exchange
and to link the proof-of-possession key to the participating parties,
as demonstrated by various authentication and key exchange protocols.
The means of communicating the nonce and the nature of its contents
are intentionally not described in this specification,
as different protocols will communicate this information in different ways.
Likewise, the means of communicating the signed nonce is also not specified,
as this is also protocol specific.
Note that other means of proving possession of the key
exist, which could be used in conjunction with a CWT's confirmation key.
Applications making use of such alternate means are encouraged
to register them in the IANA "CWT Confirmation Methods" registry
established in .
All the security considerations that
are discussed in also apply here.
In addition, proof of possession introduces its own unique security issues.
Possessing a key is only valuable if it is kept secret.
Appropriate means must be used to ensure that unintended parties
do not learn private key or symmetric key values.
Applications utilizing proof of possession SHOULD also utilize audience restriction,
as described in Section 3.1.3 of ,
as it provides additional protections.
Audience restriction can be used by recipients to reject messages intended for different recipients.
A recipient might not understand the cnf claim.
Applications that use proof-of-possession keys in CWTs with the cnf claim
MUST ensure that the parts of this specification
that they use are implemented by the intended recipient.
CBOR Web Tokens with proof-of-possession keys are used in context of an architecture,
such as the ACE OAuth Framework ,
in which protocols are used by a presenter to request these tokens
and to subsequently use them with recipients.
Proof of possession only provides the intended security gains when the
proof is known to be current and not subject to replay attacks;
security protocols using mechanisms such as nonces and timestamps can be used to
avoid the risk of replay when performing proof of possession for a token.
Note that a discussion of the architecture or specific protocols that
CWT proof-of-possession tokens are used with is beyond the scope of this specification.
As is the case with other information included in a CWT,
it is necessary to apply data origin authentication and integrity protection
(via a keyed message digest or a digital signature).
Data origin authentication ensures that the recipient of the CWT
learns about the entity that created the CWT
since this will be important for any policy decisions.
Integrity protection prevents an adversary from changing
any elements conveyed within the CWT payload.
Special care has to be applied when carrying symmetric keys inside the CWT
since those not only require integrity protection
but also confidentiality protection
(e.g., either by encrypting the cnf element,
as specified in ,
or by encrypting the whole CWT, as specified in ).
As described in Section 6 (Key Identification) and Appendix D (Notes on Key Selection)
of , it is important to make explicit trust decisions about the keys.
Proof-of-possession signatures made with keys
not meeting the application's trust criteria MUST NOT be relied upon.
A proof-of-possession key can be used as a correlation handle if the same key
is used on multiple occasions.
Thus, for privacy reasons, it is recommended that different proof-of-possession keys
be used when interacting with different parties.
The use of CWTs with proof-of-possession keys requires additional information
to be shared between the involved parties in order to ensure correct processing.
The recipient needs to be able to use credentials to verify the authenticity and
integrity of the CWT. Furthermore, the recipient may need to be able to decrypt
either the whole CWT or the encrypted parts thereof (see ).
This requires the recipient to know information about the issuer.
Likewise, there needs to be agreement between the issuer and the recipient
about the claims being used (which is also true of CWTs in general).
When an issuer creates a CWT containing a Key ID claim, it needs to make sure that
it does not issue another CWT with different claims containing the same Key ID
within the lifetime of the CWTs, unless intentionally desired.
Failure to do so may allow one party to impersonate another party,
with the potential to gain additional privileges.
A case where such reuse of a Key ID would be intentional is when a presenter obtains
a CWT with different claims (e.g., extended scope) for the same recipient, but wants to
continue using an existing security association (e.g., a DTLS session) bound to the key
identified by the Key ID.
Likewise, if PoP keys are used for multiple different kinds of CWTs in an application
and the PoP keys are identified by Key IDs, care must be taken to keep the keys
for the different kinds of CWTs segregated so that an attacker cannot
cause the wrong PoP key to be used by using a valid Key ID
for the wrong kind of CWT.
Using an audience restriction for the CWT would be one strategy to mitigate this risk.
The following registration procedure is used for all the
registries established by this specification.
Values are registered on a Specification Required
basis after a three-week review period on the cwt-reg-review@ietf.org mailing
list, on the advice of one or more Designated Experts. However, to allow for the
allocation of values prior to publication, the Designated Experts may approve
registration once they are satisfied that such a specification will be published.
[[ Note to the RFC Editor:
The name of the mailing list should be determined in consultation
with the IESG and IANA. Suggested name: cwt-reg-review@ietf.org. ]]
Registration requests sent to the mailing list for review should use
an appropriate subject
(e.g., "Request to Register CWT Confirmation Method: example").
Registration requests that are undetermined for
a period longer than 21 days can be brought to the IESG's attention
(using the iesg@ietf.org mailing list) for resolution.
Designated Experts should determine whether a registration request contains
enough information for the registry to be populated with the new values and
whether the proposed new functionality already exists.
In the case of an incomplete registration
or an attempt to register already existing functionality,
the Designated Experts should ask for corrections or reject the registration.
It is suggested that multiple Designated Experts be appointed who are able to
represent the perspectives of different applications using this specification
in order to enable broadly informed review of registration decisions.
In cases where a registration decision could be perceived as
creating a conflict of interest for a particular Expert,
that Expert should defer to the judgment of the other Experts.
This specification registers the cnf claim in the IANA
"CBOR Web Token Claims" registry
established by .
Claim Name: cnf
Claim Description: Confirmation
JWT Claim Name: cnf
Claim Key: TBD (maybe 8)
Claim Value Type(s): map
Change Controller: IESG
Specification Document(s): of [[ this document ]]
This specification establishes the
IANA "CWT Confirmation Methods" registry
for CWT cnf member values.
The registry records the confirmation method member
and a reference to the specification that defines it.
The human-readable name requested (e.g., "kid").
Brief description of the confirmation method (e.g., "Key Identifier").
Claim Name of the equivalent JWT confirmation method value,
as registered in .
CWT claims should normally have a corresponding JWT claim.
If a corresponding JWT claim would not make sense,
the Designated Experts can choose to accept registrations
for which the JWT Claim Name is listed as "N/A".
CBOR map key value for the confirmation method.
CBOR types that can be used for the confirmation method value.
For Standards Track RFCs, list the "IESG". For others, give the name of the
responsible party.
Reference to the document or documents that specify the parameter,
preferably including URIs that
can be used to retrieve copies of the documents.
An indication of the relevant
sections may also be included but is not required.
Note that the Designated Experts and IANA must be able to obtain
copies of the specification document(s) to perform their work.
Confirmation Method Name: COSE_Key
Confirmation Method Description: COSE_Key Representing Public Key
JWT Confirmation Method Name: jwk
Confirmation Key: 1
Confirmation Value Type(s): COSE_Key structure
Change Controller: IESG
Specification Document(s): of [[ this document ]]
Confirmation Method Name: Encrypted_COSE_Key
Confirmation Method Description: Encrypted COSE_Key
JWT Confirmation Method Name: jwe
Confirmation Key: 2
Confirmation Value Type(s): COSE_Encrypt or COSE_Encrypt0 structure (with an optional corresponding COSE_Encrypt or COSE_Encrypt0 tag)
Change Controller: IESG
Specification Document(s): of [[ this document ]]
Confirmation Method Name: kid
Confirmation Method Description: Key Identifier
JWT Confirmation Method Name: kid
Confirmation Key: 3
Confirmation Value Type(s): binary string
Change Controller: IESG
Specification Document(s): of [[ this document ]]
CBOR Web Token ClaimsIANACBOR Web Token (CWT)Microsoftmbj@microsoft.comhttp://self-issued.info/erik@wahlstromstekniska.seSpotify ABerdtman@spotify.comARM Ltd.Hannes.Tschofenig@arm.comJSON Web Signature (JWS)Microsoftmbj@microsoft.comhttp://self-issued.info/Ping Identityve7jtb@ve7jtb.comNomura Research Instituten-sakimura@nri.co.jpJSON Web Token (JWT)Microsoftmbj@microsoft.comhttp://self-issued.info/Ping Identityve7jtb@ve7jtb.comNomura Research Instituten-sakimura@nri.co.jpAssertions and Protocol for the OASIS Security Assertion Markup Language
(SAML) V2.0Internet2cantor.2@osu.eduNokiaJohn.Kemp@nokia.comRSA Securityrphilpott@rsasecurity.comSun Microsystemseve.maler@sun.comJSON Web Token ClaimsIANA
Thanks to the following people for their reviews of the specification:
Roman Danyliw,
Benjamin Kaduk,
Michael Richardson,
and
Jim Schaad.
Ludwig Seitz and Göran Selander worked on this document as part of
the CelticPlus projects CyberWI and CRITISEC, with funding from Vinnova.
[[ to be removed by the RFC Editor before publication as an RFC ]]
-08
Addressed remaining Area Director review comments by Benjamin Kaduk.
-07
Addressed Area Director review by Benjamin Kaduk.
-06
Corrected nits identified by Roman Danyliw.
-05
Added text suggested by Jim Schaad describing considerations when using the Key ID confirmation method.
-04
Addressed additional WGLC comments by Jim Schaad and Roman Danyliw.
-03
Addressed review comments by Jim Schaad, see https://www.ietf.org/mail-archive/web/ace/current/msg02798.html
Removed unnecessary sentence in the introduction regarding the use any strings that could be case-sensitive.
Clarified the terms Presenter and Recipient.
Clarified text about the confirmation claim.
-02
Changed "typically" to "often" when describing ways of performing proof of possession.
Changed b64 to hex encoding in an example.
Changed to using the RFC 8174 boilerplate instead of the RFC 2119 boilerplate.
-01
Now uses CBOR diagnostic notation for the examples.
Added a table summarizing the "cnf" names, keys, and value types.
Addressed some of Jim Schaad's feedback on -00.
-00
Created the initial working group draft from draft-jones-ace-cwt-proof-of-possession-01.