From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc9101.txt | 1297 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1297 insertions(+) create mode 100644 doc/rfc/rfc9101.txt (limited to 'doc/rfc/rfc9101.txt') diff --git a/doc/rfc/rfc9101.txt b/doc/rfc/rfc9101.txt new file mode 100644 index 0000000..115b07f --- /dev/null +++ b/doc/rfc/rfc9101.txt @@ -0,0 +1,1297 @@ + + + + +Internet Engineering Task Force (IETF) N. Sakimura +Request for Comments: 9101 NAT.Consulting +Category: Standards Track J. Bradley +ISSN: 2070-1721 Yubico + M. Jones + Microsoft + August 2021 + + +The OAuth 2.0 Authorization Framework: JWT-Secured Authorization Request + (JAR) + +Abstract + + The authorization request in OAuth 2.0 described in RFC 6749 utilizes + query parameter serialization, which means that authorization request + parameters are encoded in the URI of the request and sent through + user agents such as web browsers. While it is easy to implement, it + means that a) the communication through the user agents is not + integrity protected and thus, the parameters can be tainted, b) the + source of the communication is not authenticated, and c) the + communication through the user agents can be monitored. Because of + these weaknesses, several attacks to the protocol have now been put + forward. + + This document introduces the ability to send request parameters in a + JSON Web Token (JWT) instead, which allows the request to be signed + with JSON Web Signature (JWS) and encrypted with JSON Web Encryption + (JWE) so that the integrity, source authentication, and + confidentiality properties of the authorization request are attained. + The request can be sent by value or by reference. + +Status of This Memo + + This is an Internet Standards Track document. + + This document is a product of the Internet Engineering Task Force + (IETF). It represents the consensus of the IETF community. It has + received public review and has been approved for publication by the + Internet Engineering Steering Group (IESG). Further information on + Internet Standards is available in Section 2 of RFC 7841. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + https://www.rfc-editor.org/info/rfc9101. + +Copyright Notice + + Copyright (c) 2021 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 + (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. 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. + +Table of Contents + + 1. Introduction + 1.1. Requirements Language + 2. Terminology + 2.1. Request Object + 2.2. Request Object URI + 3. Symbols and Abbreviated Terms + 4. Request Object + 5. Authorization Request + 5.1. Passing a Request Object by Value + 5.2. Passing a Request Object by Reference + 5.2.1. URI Referencing the Request Object + 5.2.2. Request Using the "request_uri" Request Parameter + 5.2.3. Authorization Server Fetches Request Object + 6. Validating JWT-Based Requests + 6.1. JWE Encrypted Request Object + 6.2. JWS-Signed Request Object + 6.3. Request Parameter Assembly and Validation + 7. Authorization Server Response + 8. TLS Requirements + 9. IANA Considerations + 9.1. OAuth Parameters Registration + 9.2. OAuth Authorization Server Metadata Registry + 9.3. OAuth Dynamic Client Registration Metadata Registry + 9.4. Media Type Registration + 9.4.1. Registry Contents + 10. Security Considerations + 10.1. Choice of Algorithms + 10.2. Request Source Authentication + 10.3. Explicit Endpoints + 10.4. Risks Associated with request_uri + 10.4.1. DDoS Attack on the Authorization Server + 10.4.2. Request URI Rewrite + 10.5. Downgrade Attack + 10.6. TLS Security Considerations + 10.7. Parameter Mismatches + 10.8. Cross-JWT Confusion + 11. Privacy Considerations + 11.1. Collection Limitation + 11.2. Disclosure Limitation + 11.2.1. Request Disclosure + 11.2.2. Tracking Using Request Object URI + 12. References + 12.1. Normative References + 12.2. Informative References + Acknowledgements + Authors' Addresses + +1. Introduction + + The authorization request in OAuth 2.0 [RFC6749] utilizes query + parameter serialization and is typically sent through user agents + such as web browsers. + + For example, the parameters "response_type", "client_id", "state", + and "redirect_uri" are encoded in the URI of the request: + + GET /authorize?response_type=code&client_id=s6BhdRkqt3&state=xyz + &redirect_uri=https%3A%2F%2Fclient%2Eexample%2Ecom%2Fcb HTTP/1.1 + Host: server.example.com + + While it is easy to implement, the encoding in the URI does not allow + application-layer security to be used to provide confidentiality and + integrity protection. While TLS is used to offer communication + security between the client and the user agent as well as the user + agent and the authorization server, TLS sessions are terminated in + the user agent. In addition, TLS sessions may be terminated + prematurely at some middlebox (such as a load balancer). + + As a result, the authorization request of [RFC6749] has shortcomings + in that: + + (a) the communication through the user agents is not integrity + protected, and thus, the parameters can be tainted (integrity + protection failure); + + (b) the source of the communication is not authenticated (source + authentication failure); + + (c) the communication through the user agents can be monitored + (containment/confidentiality failure). + + Due to these inherent weaknesses, several attacks against the + protocol, such as redirection URI rewriting, have been identified. + + The use of application-layer security mitigates these issues. + + The use of application-layer security allows requests to be prepared + by a trusted third party so that a client application cannot request + more permissions than previously agreed upon. + + Furthermore, passing the request by reference allows the reduction of + over-the-wire overhead. + + The JWT [RFC7519] encoding has been chosen because of: + + (1) its close relationship with JSON, which is used as OAuth's + response format + + (2) its developer friendliness due to its textual nature + + (3) its relative compactness compared to XML + + (4) its development status as a Proposed Standard, along with the + associated signing and encryption methods [RFC7515] [RFC7516] + + (5) the relative ease of JWS and JWE compared to XML Signature and + Encryption. + + The parameters "request" and "request_uri" are introduced as + additional authorization request parameters for the OAuth 2.0 + [RFC6749] flows. The "request" parameter is a JSON Web Token (JWT) + [RFC7519] whose JWT Claims Set holds the JSON-encoded OAuth 2.0 + authorization request parameters. Note that, in contrast to RFC + 7519, the elements of the Claims Set are encoded OAuth request + parameters [IANA.OAuth.Parameters], supplemented with only a few of + the IANA-managed JSON Web Token Claims [IANA.JWT.Claims], in + particular, "iss" and "aud". The JWT in the "request" parameter is + integrity protected and source authenticated using JWS. + + The JWT [RFC7519] can be passed to the authorization endpoint by + reference, in which case the parameter "request_uri" is used instead + of "request". + + Using JWT [RFC7519] as the request encoding instead of query + parameters has several advantages: + + (a) Integrity protection. The request can be signed so that the + integrity of the request can be checked. + + (b) Source authentication. The request can be signed so that the + signer can be authenticated. + + (c) Confidentiality protection. The request can be encrypted so + that end-to-end confidentiality can be provided even if the TLS + connection is terminated at one point or another (including at + and before user agents). + + (d) Collection minimization. The request can be signed by a trusted + third party attesting that the authorization request is + compliant with a certain policy. For example, a request can be + pre-examined by a trusted third party to confirm that all the + personal data requested is strictly necessary to perform the + process that the end user asked for; the request would then be + signed by that trusted third party. The authorization server + then examines the signature and shows the conformance status to + the end user who would have some assurance as to the legitimacy + of the request when authorizing it. In some cases, it may even + be desirable to skip the authorization dialogue under such + circumstances. + + There are a few cases where request by reference is useful, such as: + + 1. when it is desirable to reduce the size of a transmitted request. + The use of application-layer security increases the size of the + request particularly when public-key cryptography is used. + + 2. when the client does not want to do the application-level + cryptography. The authorization server may provide an endpoint + to accept the authorization request through direct communication + with the client, so that the client is authenticated and the + channel is TLS protected. + + This capability is in use by OpenID Connect [OpenID.Core]. + +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. + +2. Terminology + + For the purposes of this specification, the following terms and + definitions apply in addition to what is defined in OAuth 2.0 + Framework [RFC6749], JSON Web Signature [RFC7515], and JSON Web + Encryption [RFC7516]. + +2.1. Request Object + + A Request Object is a JSON Web Token (JWT) [RFC7519] whose JWT Claims + Set holds the JSON-encoded OAuth 2.0 authorization request + parameters. + +2.2. Request Object URI + + A Request Object URI is an absolute URI that references the set of + parameters comprising an OAuth 2.0 authorization request. The + content of the resource referenced by the URI is a Request Object + (Section 2.1), unless the URI was provided to the client by the same + authorization server, in which case the content is an implementation + detail at the discretion of the authorization server. The content + being a Request Object is to ensure interoperability in cases where + the provider of the "request_uri" is a separate entity from the + consumer, such as when a client provides a URI referencing a Request + Object stored on the client's backend service that is made accessible + via HTTPS. In the latter case, where the authorization server is + both provider and consumer of the URI, such as when it offers an + endpoint that provides a URI in exchange for a Request Object, this + interoperability concern does not apply. + +3. Symbols and Abbreviated Terms + + The following abbreviations are common to this specification. + + JSON: JavaScript Object Notation + + JWT: JSON Web Token + + JWS: JSON Web Signature + + JWE: JSON Web Encryption + + URI: Uniform Resource Identifier + + URL: Uniform Resource Locator + +4. Request Object + + A Request Object (Section 2.1) is used to provide authorization + request parameters for an OAuth 2.0 authorization request. It MUST + contain all the parameters (including extension parameters) used to + process the OAuth 2.0 [RFC6749] authorization request except the + "request" and "request_uri" parameters that are defined in this + document. The parameters are represented as the JWT Claims of the + object. Parameter names and string values MUST be included as JSON + strings. Since Request Objects are handled across domains and + potentially outside of a closed ecosystem, per Section 8.1 of + [RFC8259], these JSON strings MUST be encoded using UTF-8 [RFC3629]. + Numerical values MUST be included as JSON numbers. The Request + Object MAY include any extension parameters. This JSON [RFC8259] + object constitutes the JWT Claims Set defined in JWT [RFC7519]. The + JWT Claims Set is then signed or signed and encrypted. + + To sign, JSON Web Signature (JWS) [RFC7515] is used. The result is a + JWS-signed JWT [RFC7519]. If signed, the Authorization Request + Object SHOULD contain the Claims "iss" (issuer) and "aud" (audience) + as members with their semantics being the same as defined in the JWT + [RFC7519] specification. The value of "aud" should be the value of + the authorization server (AS) "issuer", as defined in RFC 8414 + [RFC8414]. + + To encrypt, JWE [RFC7516] is used. When both signature and + encryption are being applied, the JWT MUST be signed, then encrypted, + as described in Section 11.2 of [RFC7519]. The result is a Nested + JWT, as defined in [RFC7519]. + + The client determines the algorithms used to sign and encrypt Request + Objects. The algorithms chosen need to be supported by both the + client and the authorization server. The client can inform the + authorization server of the algorithms that it supports in its + dynamic client registration metadata [RFC7591], specifically, the + metadata values "request_object_signing_alg", + "request_object_encryption_alg", and "request_object_encryption_enc". + Likewise, the authorization server can inform the client of the + algorithms that it supports in its authorization server metadata + [RFC8414], specifically, the metadata values + "request_object_signing_alg_values_supported", + "request_object_encryption_alg_values_supported", and + "request_object_encryption_enc_values_supported". + + The Request Object MAY be sent by value, as described in Section 5.1, + or by reference, as described in Section 5.2. "request" and + "request_uri" parameters MUST NOT be included in Request Objects. + + A Request Object (Section 2.1) has the media type [RFC2046] + "application/oauth-authz-req+jwt". Note that some existing + deployments may alternatively be using the type "application/jwt". + + The following is an example of the Claims in a Request Object before + base64url [RFC7515] encoding and signing. Note that it includes the + extension parameters "nonce" and "max_age". + + { + "iss": "s6BhdRkqt3", + "aud": "https://server.example.com", + "response_type": "code id_token", + "client_id": "s6BhdRkqt3", + "redirect_uri": "https://client.example.org/cb", + "scope": "openid", + "state": "af0ifjsldkj", + "nonce": "n-0S6_WzA2Mj", + "max_age": 86400 + } + + Signing it with the "RS256" algorithm [RFC7518] results in this + Request Object value (with line wraps within values for display + purposes only): + + eyJhbGciOiJSUzI1NiIsImtpZCI6ImsyYmRjIn0.ewogICAgImlzcyI6ICJzNkJoZF + JrcXQzIiwKICAgICJhdWQiOiAiaHR0cHM6Ly9zZXJ2ZXIuZXhhbXBsZS5jb20iLAog + ICAgInJlc3BvbnNlX3R5cGUiOiAiY29kZSBpZF90b2tlbiIsCiAgICAiY2xpZW50X2 + lkIjogInM2QmhkUmtxdDMiLAogICAgInJlZGlyZWN0X3VyaSI6ICJodHRwczovL2Ns + aWVudC5leGFtcGxlLm9yZy9jYiIsCiAgICAic2NvcGUiOiAib3BlbmlkIiwKICAgIC + JzdGF0ZSI6ICJhZjBpZmpzbGRraiIsCiAgICAibm9uY2UiOiAibi0wUzZfV3pBMk1q + IiwKICAgICJtYXhfYWdlIjogODY0MDAKfQ.Nsxa_18VUElVaPjqW_ToI1yrEJ67BgK + b5xsuZRVqzGkfKrOIX7BCx0biSxYGmjK9KJPctH1OC0iQJwXu5YVY-vnW0_PLJb1C2 + HG-ztVzcnKZC2gE4i0vgQcpkUOCpW3SEYXnyWnKzuKzqSb1wAZALo5f89B_p6QA6j6 + JwBSRvdVsDPdulW8lKxGTbH82czCaQ50rLAg3EYLYaCb4ik4I1zGXE4fvim9FIMs8O + CMmzwIB5S-ujFfzwFjoyuPEV4hJnoVUmXR_W9typPf846lGwA8h9G9oNTIuX8Ft2jf + pnZdFmLg3_wr3Wa5q3a-lfbgF3S9H_8nN3j1i7tLR_5Nz-g + + The following RSA public key, represented in JSON Web Key (JWK) + format, can be used to validate the Request Object signature in this + and subsequent Request Object examples (with line wraps within values + for display purposes only): + + { + "kty":"RSA", + "kid":"k2bdc", + "n":"x5RbkAZkmpRxia65qRQ1wwSMSxQUnS7gcpVTV_cdHmfmG2ltd2yabEO9XadD8 + pJNZubINPpmgHh3J1aD9WRwS05ucmFq3CfFsluLt13_7oX5yDRSKX7poXmT_5 + ko8k4NJZPMAO8fPToDTH7kHYbONSE2FYa5GZ60CUsFhSonI-dcMDJ0Ary9lxI + w5k2z4TAdARVWcS7sD07VhlMMshrwsPHBQgTatlkxyIHXbYdtak8fqvNAwr7O + lVEvM_Ipf5OfmdB8Sd-wjzaBsyP4VhJKoi_qdgSzpC694XZeYPq45Sw-q51iF + UlcOlTCI7z6jltUtnR6ySn6XDGFnzH5Fe5ypw", + "e":"AQAB" + } + +5. Authorization Request + + The client constructs the authorization request URI by adding the + following parameters to the query component of the authorization + endpoint URI using the "application/x-www-form-urlencoded" format: + + request + REQUIRED unless "request_uri" is specified. The Request Object + (Section 2.1) that holds authorization request parameters stated + in Section 4 of [RFC6749] (OAuth 2.0). If this parameter is + present in the authorization request, "request_uri" MUST NOT be + present. + + request_uri + REQUIRED unless "request" is specified. The absolute URI, as + defined by RFC 3986 [RFC3986], that is the Request Object URI + (Section 2.2) referencing the authorization request parameters + stated in Section 4 of [RFC6749] (OAuth 2.0). If this parameter + is present in the authorization request, "request" MUST NOT be + present. + + client_id + REQUIRED. OAuth 2.0 [RFC6749] "client_id". The value MUST match + the "request" or "request_uri" Request Object's (Section 2.1) + "client_id". + + The client directs the resource owner to the constructed URI using an + HTTP redirection response or by other means available to it via the + user agent. + + For example, the client directs the end user's user agent to make the + following HTTPS request: + + GET /authz?client_id=s6BhdRkqt3&request=eyJhbG..AlMGzw HTTP/1.1 + Host: server.example.com + + The value for the request parameter is abbreviated for brevity. + + The Authorization Request Object MUST be one of the following: + + (a) JWS signed + + (b) JWS signed and JWE encrypted + + The client MAY send the parameters included in the Request Object + duplicated in the query parameters as well for backward + compatibility, etc. However, the authorization server supporting + this specification MUST only use the parameters included in the + Request Object. + +5.1. Passing a Request Object by Value + + The client sends the authorization request as a Request Object to the + authorization endpoint as the "request" parameter value. + + The following is an example of an authorization request using the + "request" parameter (with line wraps within values for display + purposes only): + + https://server.example.com/authorize?client_id=s6BhdRkqt3& + request=eyJhbGciOiJSUzI1NiIsImtpZCI6ImsyYmRjIn0.ewogICAgImlzcyI6 + ICJzNkJoZFJrcXQzIiwKICAgICJhdWQiOiAiaHR0cHM6Ly9zZXJ2ZXIuZXhhbXBs + ZS5jb20iLAogICAgInJlc3BvbnNlX3R5cGUiOiAiY29kZSBpZF90b2tlbiIsCiAg + ICAiY2xpZW50X2lkIjogInM2QmhkUmtxdDMiLAogICAgInJlZGlyZWN0X3VyaSI6 + ICJodHRwczovL2NsaWVudC5leGFtcGxlLm9yZy9jYiIsCiAgICAic2NvcGUiOiAi + b3BlbmlkIiwKICAgICJzdGF0ZSI6ICJhZjBpZmpzbGRraiIsCiAgICAibm9uY2Ui + OiAibi0wUzZfV3pBMk1qIiwKICAgICJtYXhfYWdlIjogODY0MDAKfQ.Nsxa_18VU + ElVaPjqW_ToI1yrEJ67BgKb5xsuZRVqzGkfKrOIX7BCx0biSxYGmjK9KJPctH1OC + 0iQJwXu5YVY-vnW0_PLJb1C2HG-ztVzcnKZC2gE4i0vgQcpkUOCpW3SEYXnyWnKz + uKzqSb1wAZALo5f89B_p6QA6j6JwBSRvdVsDPdulW8lKxGTbH82czCaQ50rLAg3E + YLYaCb4ik4I1zGXE4fvim9FIMs8OCMmzwIB5S-ujFfzwFjoyuPEV4hJnoVUmXR_W + 9typPf846lGwA8h9G9oNTIuX8Ft2jfpnZdFmLg3_wr3Wa5q3a-lfbgF3S9H_8nN3 + j1i7tLR_5Nz-g + +5.2. Passing a Request Object by Reference + + The "request_uri" authorization request parameter enables OAuth + authorization requests to be passed by reference rather than by + value. This parameter is used identically to the "request" + parameter, except that the Request Object value is retrieved from the + resource identified by the specified URI rather than passed by value. + + The entire Request URI SHOULD NOT exceed 512 ASCII characters. There + are two reasons for this restriction: + + 1. Many phones on the market as of this writing still do not accept + large payloads. The restriction is typically either 512 or 1024 + ASCII characters. + + 2. On a slow connection such as a 2G mobile connection, a large URL + would cause a slow response; therefore, the use of such is not + advisable from the user-experience point of view. + + The contents of the resource referenced by the "request_uri" MUST be + a Request Object and MUST be reachable by the authorization server + unless the URI was provided to the client by the authorization + server. In the first case, the "request_uri" MUST be an "https" URI, + as specified in Section 2.7.2 of [RFC7230]. In the second case, it + MUST be a URN, as specified in [RFC8141]. + + The following is an example of the contents of a Request Object + resource that can be referenced by a "request_uri" (with line wraps + within values for display purposes only): + + eyJhbGciOiJSUzI1NiIsImtpZCI6ImsyYmRjIn0.ewogICAgImlzcyI6ICJzNkJoZF + JrcXQzIiwKICAgICJhdWQiOiAiaHR0cHM6Ly9zZXJ2ZXIuZXhhbXBsZS5jb20iLAog + ICAgInJlc3BvbnNlX3R5cGUiOiAiY29kZSBpZF90b2tlbiIsCiAgICAiY2xpZW50X2 + lkIjogInM2QmhkUmtxdDMiLAogICAgInJlZGlyZWN0X3VyaSI6ICJodHRwczovL2Ns + aWVudC5leGFtcGxlLm9yZy9jYiIsCiAgICAic2NvcGUiOiAib3BlbmlkIiwKICAgIC + JzdGF0ZSI6ICJhZjBpZmpzbGRraiIsCiAgICAibm9uY2UiOiAibi0wUzZfV3pBMk1q + IiwKICAgICJtYXhfYWdlIjogODY0MDAKfQ.Nsxa_18VUElVaPjqW_ToI1yrEJ67BgK + b5xsuZRVqzGkfKrOIX7BCx0biSxYGmjK9KJPctH1OC0iQJwXu5YVY-vnW0_PLJb1C2 + HG-ztVzcnKZC2gE4i0vgQcpkUOCpW3SEYXnyWnKzuKzqSb1wAZALo5f89B_p6QA6j6 + JwBSRvdVsDPdulW8lKxGTbH82czCaQ50rLAg3EYLYaCb4ik4I1zGXE4fvim9FIMs8O + CMmzwIB5S-ujFfzwFjoyuPEV4hJnoVUmXR_W9typPf846lGwA8h9G9oNTIuX8Ft2jf + pnZdFmLg3_wr3Wa5q3a-lfbgF3S9H_8nN3j1i7tLR_5Nz-g + +5.2.1. URI Referencing the Request Object + + The client stores the Request Object resource either locally or + remotely at a URI the authorization server can access. Such a + facility may be provided by the authorization server or a trusted + third party. For example, the authorization server may provide a URL + to which the client POSTs the Request Object and obtains the Request + URI. This URI is the Request Object URI, "request_uri". + + It is possible for the Request Object to include values that are to + be revealed only to the authorization server. As such, the + "request_uri" MUST have appropriate entropy for its lifetime so that + the URI is not guessable if publicly retrievable. For the guidance, + refer to Section 5.1.4.2.2 of [RFC6819] and "Good Practices for + Capability URLs" [CapURLs]. It is RECOMMENDED that the "request_uri" + be removed after a reasonable timeout unless access control measures + are taken. + + The following is an example of a Request Object URI value (with line + wraps within values for display purposes only). In this example, a + trusted third-party service hosts the Request Object. + + https://tfp.example.org/request.jwt/ + GkurKxf5T0Y-mnPFCHqWOMiZi4VS138cQO_V7PZHAdM + +5.2.2. Request Using the "request_uri" Request Parameter + + The client sends the authorization request to the authorization + endpoint. + + The following is an example of an authorization request using the + "request_uri" parameter (with line wraps within values for display + purposes only): + + https://server.example.com/authorize? + client_id=s6BhdRkqt3 + &request_uri=https%3A%2F%2Ftfp.example.org%2Frequest.jwt + %2FGkurKxf5T0Y-mnPFCHqWOMiZi4VS138cQO_V7PZHAdM + +5.2.3. Authorization Server Fetches Request Object + + Upon receipt of the Request, the authorization server MUST send an + HTTP "GET" request to the "request_uri" to retrieve the referenced + Request Object unless the Request Object is stored in a way so that + the server can retrieve it through other mechanisms securely and + parse it to recreate the authorization request parameters. + + The following is an example of this fetch process. In this example, + a trusted third-party service hosts the Request Object. + + GET /request.jwt/GkurKxf5T0Y-mnPFCHqWOMiZi4VS138cQO_V7PZHAdM HTTP/1.1 + Host: tfp.example.org + + The following is an example of the fetch response: + + HTTP/1.1 200 OK + Date: Thu, 20 Aug 2020 23:52:39 GMT + Server: Apache/2.4.43 (tfp.example.org) + Content-type: application/oauth-authz-req+jwt + Content-Length: 797 + Last-Modified: Wed, 19 Aug 2020 23:52:32 GMT + + eyJhbGciOiJSUzI1NiIsImtpZCI6ImsyYmRjIn0.ewogICAgImlzcyI6ICJzNkJoZF + JrcXQzIiwKICAgICJhdWQiOiAiaHR0cHM6Ly9zZXJ2ZXIuZXhhbXBsZS5jb20iLAog + ICAgInJlc3BvbnNlX3R5cGUiOiAiY29kZSBpZF90b2tlbiIsCiAgICAiY2xpZW50X2 + lkIjogInM2QmhkUmtxdDMiLAogICAgInJlZGlyZWN0X3VyaSI6ICJodHRwczovL2Ns + aWVudC5leGFtcGxlLm9yZy9jYiIsCiAgICAic2NvcGUiOiAib3BlbmlkIiwKICAgIC + JzdGF0ZSI6ICJhZjBpZmpzbGRraiIsCiAgICAibm9uY2UiOiAibi0wUzZfV3pBMk1q + IiwKICAgICJtYXhfYWdlIjogODY0MDAKfQ.Nsxa_18VUElVaPjqW_ToI1yrEJ67BgK + b5xsuZRVqzGkfKrOIX7BCx0biSxYGmjK9KJPctH1OC0iQJwXu5YVY-vnW0_PLJb1C2 + HG-ztVzcnKZC2gE4i0vgQcpkUOCpW3SEYXnyWnKzuKzqSb1wAZALo5f89B_p6QA6j6 + JwBSRvdVsDPdulW8lKxGTbH82czCaQ50rLAg3EYLYaCb4ik4I1zGXE4fvim9FIMs8O + CMmzwIB5S-ujFfzwFjoyuPEV4hJnoVUmXR_W9typPf846lGwA8h9G9oNTIuX8Ft2jf + pnZdFmLg3_wr3Wa5q3a-lfbgF3S9H_8nN3j1i7tLR_5Nz-g + +6. Validating JWT-Based Requests + +6.1. JWE Encrypted Request Object + + If the Request Object is encrypted, the authorization server MUST + decrypt the JWT in accordance with the JSON Web Encryption [RFC7516] + specification. + + The result is a signed Request Object. + + If decryption fails, the authorization server MUST return an + "invalid_request_object" error to the client in response to the + authorization request. + +6.2. JWS-Signed Request Object + + The authorization server MUST validate the signature of the JWS- + signed [RFC7515] Request Object. If a "kid" Header Parameter is + present, the key identified MUST be the key used and MUST be a key + associated with the client. The signature MUST be validated using a + key associated with the client and the algorithm specified in the + "alg" Header Parameter. Algorithm verification MUST be performed, as + specified in Sections 3.1 and 3.2 of [RFC8725]. + + If the key is not associated with the client or if signature + validation fails, the authorization server MUST return an + "invalid_request_object" error to the client in response to the + authorization request. + +6.3. Request Parameter Assembly and Validation + + The authorization server MUST extract the set of authorization + request parameters from the Request Object value. The authorization + server MUST only use the parameters in the Request Object, even if + the same parameter is provided in the query parameter. The client ID + values in the "client_id" request parameter and in the Request Object + "client_id" claim MUST be identical. The authorization server then + validates the request, as specified in OAuth 2.0 [RFC6749]. + + If the Client ID check or the request validation fails, then the + authorization server MUST return an error to the client in response + to the authorization request, as specified in Section 5.2 of + [RFC6749] (OAuth 2.0). + +7. Authorization Server Response + + The authorization server response is created and sent to the client + as in Section 4 of [RFC6749] (OAuth 2.0). + + In addition, this document uses these additional error values: + + invalid_request_uri + The "request_uri" in the authorization request returns an error or + contains invalid data. + + invalid_request_object + The request parameter contains an invalid Request Object. + + request_not_supported + The authorization server does not support the use of the "request" + parameter. + + request_uri_not_supported + The authorization server does not support the use of the + "request_uri" parameter. + +8. TLS Requirements + + Client implementations supporting the Request Object URI method MUST + support TLS, following "Recommendations for Secure Use of Transport + Layer Security (TLS) and Datagram Transport Layer Security (DTLS)" + [RFC7525]. + + To protect against information disclosure and tampering, + confidentiality protection MUST be applied using TLS with a cipher + suite that provides confidentiality and integrity protection. + + HTTP clients MUST also verify the TLS server certificate, using DNS- + ID [RFC6125], to avoid man-in-the-middle attacks. The rules and + guidelines defined in [RFC6125] apply here, with the following + considerations: + + * Support for DNS-ID identifier type (that is, the dNSName identity + in the subjectAltName extension) is REQUIRED. Certification + authorities that issue server certificates MUST support the DNS-ID + identifier type, and the DNS-ID identifier type MUST be present in + server certificates. + + * DNS names in server certificates MAY contain the wildcard + character "*". + + * Clients MUST NOT use CN-ID identifiers; a Common Name field (CN + field) may be present in the server certificate's subject name but + MUST NOT be used for authentication within the rules described in + [RFC7525]. + + * SRV-ID and URI-ID as described in Section 6.5 of [RFC6125] MUST + NOT be used for comparison. + +9. IANA Considerations + +9.1. OAuth Parameters Registration + + Since the Request Object is a JWT, the core JWT claims cannot be used + for any purpose in the Request Object other than for what JWT + dictates. Thus, they have been registered as OAuth authorization + request parameters to avoid future OAuth extensions using them with + different meanings. + + This specification adds the following values to the "OAuth + Parameters" registry [IANA.OAuth.Parameters] established by + [RFC6749]. + + Name: "iss" + Parameter Usage Location: authorization request + Change Controller: IETF + Specification Document(s): This document and Section 4.1.1 of + [RFC7519]. + + Name: "sub" + Parameter Usage Location: authorization request + Change Controller: IETF + Specification Document(s): This document and Section 4.1.2 of + [RFC7519]. + + Name: "aud" + Parameter Usage Location: authorization request + Change Controller: IETF + Specification Document(s): This document and Section 4.1.3 of + [RFC7519]. + + Name: "exp" + Parameter Usage Location: authorization request + Change Controller: IETF + Specification Document(s): This document and Section 4.1.4 of + [RFC7519]. + + Name: "nbf" + Parameter Usage Location: authorization request + Change Controller: IETF + Specification Document(s): This document and Section 4.1.5 of + [RFC7519]. + + Name: "iat" + Parameter Usage Location: authorization request + Change Controller: IETF + Specification Document(s): This document and Section 4.1.6 of + [RFC7519]. + + Name: "jti" + Parameter Usage Location: authorization request + Change Controller: IETF + Specification Document(s): This document and Section 4.1.7 of + [RFC7519]. + +9.2. OAuth Authorization Server Metadata Registry + + This specification adds the following value to the "OAuth + Authorization Server Metadata" registry [IANA.OAuth.Parameters] + established by [RFC8414]. + + Metadata Name: "require_signed_request_object" + Metadata Description: Indicates where authorization request needs to + be protected as Request Object and provided through either + "request" or "request_uri parameter". + Change Controller: IETF + Specification Document(s): Section 10.5 of this document. + +9.3. OAuth Dynamic Client Registration Metadata Registry + + This specification adds the following value to the "OAuth Dynamic + Client Registration Metadata" registry [IANA.OAuth.Parameters] + established by [RFC7591]. + + Metadata Name: "require_signed_request_object" + Metadata Description: Indicates where authorization request needs to + be protected as Request Object and provided through either + "request" or "request_uri parameter". + Change Controller: IETF + Specification Document(s): Section 10.5 of this document. + +9.4. Media Type Registration + +9.4.1. Registry Contents + + This section registers the "application/oauth-authz-req+jwt" media + type [RFC2046] in the "Media Types" registry [IANA.MediaTypes] in the + manner described in [RFC6838]. It can be used to indicate that the + content is a JWT containing Request Object claims. + + Type name: application + Subtype name: oauth-authz-req+jwt + Required parameters: N/A + Optional parameters: N/A + Encoding considerations: binary; a Request Object is a JWT; JWT + values are encoded as a series of base64url-encoded values (some + of which may be the empty string) separated by period (".") + characters. + Security considerations: See Section 10 of RFC 9101 + Interoperability considerations: N/A + Published specification: Section 4 of RFC 9101 + Applications that use this media type: Applications that use Request + Objects to make an OAuth 2.0 authorization request + Fragment identifier considerations: N/A + Additional information: + Deprecated alias names for this type: N/A + Magic number(s): N/A + File extension(s): N/A + Macintosh file type code(s): N/A + Person & email address to contact for further information: + Nat Sakimura + Intended usage: COMMON + Restrictions on usage: none + Author: Nat Sakimura + Change controller: IETF + Provisional registration? No + +10. Security Considerations + + In addition to all the security considerations discussed in OAuth 2.0 + [RFC6819], the security considerations in [RFC7515], [RFC7516], + [RFC7518], and [RFC8725] need to be considered. Also, there are + several academic papers such as [BASIN] that provide useful insight + into the security properties of protocols like OAuth. + + In consideration of the above, this document advises taking the + following security considerations into account. + +10.1. Choice of Algorithms + + When sending the Authorization Request Object through the "request" + parameter, it MUST be either signed using JWS [RFC7515] or signed and + then encrypted using JWS [RFC7515] and JWE [RFC7516], respectively, + with algorithms considered appropriate at the time. + +10.2. Request Source Authentication + + The source of the authorization request MUST always be verified. + There are several ways to do it: + + (a) Verifying the JWS Signature of the Request Object. + + (b) Verifying that the symmetric key for the JWE encryption is the + correct one if the JWE is using symmetric encryption. Note, + however, that if public key encryption is used, no source + authentication is enabled by the encryption, as any party can + encrypt to the public key. + + (c) Verifying the TLS Server Identity of the Request Object URI. In + this case, the authorization server MUST know out-of-band that + the client uses the Request Object URI and only the client is + covered by the TLS certificate. In general, this is not a + reliable method. + + (d) When an authorization server implements a service that returns a + Request Object URI in exchange for a Request Object, the + authorization server MUST perform client authentication to + accept the Request Object and bind the client identifier to the + Request Object URI it is providing. It MUST validate the + signature, per (a). Since the Request Object URI can be + replayed, the lifetime of the Request Object URI MUST be short + and preferably one-time use. The entropy of the Request Object + URI MUST be sufficiently large. The adequate shortness of the + validity and the entropy of the Request Object URI depends on + the risk calculation based on the value of the resource being + protected. A general guidance for the validity time would be + less than a minute, and the Request Object URI is to include a + cryptographic random value of 128 bits or more at the time of + the writing of this specification. + + (e) When a trusted third-party service returns a Request Object URI + in exchange for a Request Object, it MUST validate the + signature, per (a). In addition, the authorization server MUST + be trusted by the third-party service and MUST know out-of-band + that the client is also trusted by it. + +10.3. Explicit Endpoints + + Although this specification does not require them, research such as + [BASIN] points out that it is a good practice to explicitly state the + intended interaction endpoints and the message position in the + sequence in a tamper-evident manner so that the intent of the + initiator is unambiguous. It is RECOMMENDED by this specification to + use this practice for the following endpoints defined in [RFC6749], + [RFC6750], and [RFC8414]: + + (a) Protected resources ("protected_resources") + + (b) Authorization endpoint ("authorization_endpoint") + + (c) Redirection URI ("redirect_uri") + + (d) Token endpoint ("token_endpoint") + + Further, if dynamic discovery is used, then this practice also + applies to the discovery-related endpoints. + + In [RFC6749], while the redirection URI is included in the + authorization request, others are not. As a result, the same applies + to the Authorization Request Object. + +10.4. Risks Associated with request_uri + + The introduction of "request_uri" introduces several attack + possibilities. Consult the security considerations in Section 7 of + [RFC3986] for more information regarding risks associated with URIs. + +10.4.1. DDoS Attack on the Authorization Server + + A set of malicious clients can launch a DoS attack to the + authorization server by pointing the "request_uri" to a URI that + returns extremely large content or is extremely slow to respond. + Under such an attack, the server may use up its resource and start + failing. + + Similarly, a malicious client can specify a "request_uri" value that + itself points to an authorization request URI that uses "request_uri" + to cause the recursive lookup. + + To prevent such an attack from succeeding, the server should a) check + that the value of the "request_uri" parameter does not point to an + unexpected location, b) check that the media type of the response is + "application/oauth-authz-req+jwt", c) implement a timeout for + obtaining the content of "request_uri", and d) not perform recursive + GET on the "request_uri". + +10.4.2. Request URI Rewrite + + The value of "request_uri" is not signed; thus, it can be tampered + with by a man-in-the-browser attacker. Several attack possibilities + arise because of this. For example, a) an attacker may create + another file that the rewritten URI points to, making it possible to + request extra scope, or b) an attacker may launch a DoS attack on a + victim site by setting the value of "request_uri" to be that of the + victim. + + To prevent such an attack from succeeding, the server should a) check + that the value of the "request_uri" parameter does not point to an + unexpected location, b) check that the media type of the response is + "application/oauth-authz-req+jwt", and c) implement a timeout for + obtaining the content of "request_uri". + +10.5. Downgrade Attack + + Unless the protocol used by the client and the server is locked down + to use an OAuth JWT-Secured Authorization Request (JAR), it is + possible for an attacker to use RFC 6749 requests to bypass all the + protection provided by this specification. + + To prevent this kind of attack, this specification defines new client + metadata and server metadata values, both named + "require_signed_request_object", whose values are both booleans. + + When the value of it as client metadata is "true", then the server + MUST reject the authorization request from the client that does not + conform to this specification. It MUST also reject the request if + the Request Object uses an "alg" value of "none" when this server + metadata value is "true". If omitted, the default value is "false". + + When the value of it as server metadata is "true", then the server + MUST reject the authorization request from any client that does not + conform to this specification. It MUST also reject the request if + the Request Object uses an "alg" value of "none". If omitted, the + default value is "false". + + Note that even if "require_signed_request_object" metadata values are + not present, the client MAY use signed Request Objects, provided that + there are signing algorithms mutually supported by the client and the + server. Use of signing algorithm metadata is described in Section 4. + +10.6. TLS Security Considerations + + Current security considerations can be found in "Recommendations for + Secure Use of Transport Layer Security (TLS) and Datagram Transport + Layer Security (DTLS)" [RFC7525]. This supersedes the TLS version + recommendations in OAuth 2.0 [RFC6749]. + +10.7. Parameter Mismatches + + Given that OAuth parameter values are being sent in two different + places, as normal OAuth parameters and as Request Object claims, + implementations must guard against attacks that could use mismatching + parameter values to obtain unintended outcomes. That is the reason + that the two client ID values MUST match, the reason that only the + parameter values from the Request Object are to be used, and the + reason that neither "request" nor "request_uri" can appear in a + Request Object. + +10.8. Cross-JWT Confusion + + As described in Section 2.8 of [RFC8725], attackers may attempt to + use a JWT issued for one purpose in a context that it was not + intended for. The mitigations described for these attacks can be + applied to Request Objects. + + One way that an attacker might attempt to repurpose a Request Object + is to try to use it as a client authentication JWT, as described in + Section 2.2 of [RFC7523]. A simple way to prevent this is to never + use the client ID as the "sub" value in a Request Object. + + Another way to prevent cross-JWT confusion is to use explicit typing, + as described in Section 3.11 of [RFC8725]. One would explicitly type + a Request Object by including a "typ" Header Parameter with the value + "oauth-authz-req+jwt" (which is registered in Section 9.4.1). Note, + however, that requiring explicitly typed Request Objects at existing + authorization servers will break most existing deployments, as + existing clients are already commonly using untyped Request Objects, + especially with OpenID Connect [OpenID.Core]. However, requiring + explicit typing would be a good idea for new OAuth deployment + profiles where compatibility with existing deployments is not a + consideration. + + Finally, yet another way to prevent cross-JWT confusion is to use a + key management regime in which keys used to sign Request Objects are + identifiably distinct from those used for other purposes. Then, if + an adversary attempts to repurpose the Request Object in another + context, a key mismatch will occur, thwarting the attack. + +11. Privacy Considerations + + When the client is being granted access to a protected resource + containing personal data, both the client and the authorization + server need to adhere to Privacy Principles. "Privacy Considerations + for Internet Protocols" [RFC6973] gives excellent guidance on the + enhancement of protocol design and implementation. The provisions + listed in it should be followed. + + Most of the provisions would apply to "The OAuth 2.0 Authorization + Framework" [RFC6749] and "The OAuth 2.0 Authorization Framework: + Bearer Token Usage" [RFC6750] and are not specific to this + specification. In what follows, only the provisions specific to this + specification are noted. + +11.1. Collection Limitation + + When the client is being granted access to a protected resource + containing personal data, the client SHOULD limit the collection of + personal data to that which is within the bounds of applicable law + and strictly necessary for the specified purpose(s). + + It is often hard for the user to find out if the personal data asked + for is strictly necessary. A trusted third-party service can help + the user by examining the client request, comparing it to the + proposed processing by the client, and certifying the request. After + the certification, the client, when making an authorization request, + can submit an authorization request to the trusted third-party + service to obtain the Request Object URI. This process has two + steps: + + (1) (Certification Process) The trusted third-party service examines + the business process of the client and determines what claims + they need; this is the certification process. Once the client + is certified, they are issued a client credential to + authenticate against to push Request Objects to the trusted + third-party service to get the "request_uri". + + (2) (Translation Process) The client uses the client credential that + it got to push the Request Object to the trusted third-party + service to get the "request_uri". The trusted third-party + service also verifies that the Request Object is consistent with + the claims that the client is eligible for, per the prior step. + + Upon receiving such a Request Object URI in the authorization + request, the authorization server first verifies that the authority + portion of the Request Object URI is a legitimate one for the trusted + third-party service. Then, the authorization server issues an HTTP + GET request to the Request Object URI. Upon connecting, the + authorization server MUST verify that the server identity represented + in the TLS certificate is legitimate for the Request Object URI. + Then, the authorization server can obtain the Request Object, which + includes the "client_id" representing the client. + + The Consent screen MUST indicate the client and SHOULD indicate that + the request has been vetted by the trusted third-party service for + the adherence to the collection limitation principle. + +11.2. Disclosure Limitation + +11.2.1. Request Disclosure + + This specification allows extension parameters. These may include + potentially sensitive information. Since URI query parameters may + leak through various means but most notably through referrer and + browser history, if the authorization request contains a potentially + sensitive parameter, the client SHOULD encrypt the Request Object + using JWE [RFC7516]. + + Where the Request Object URI method is being used, if the Request + Object contains personally identifiable or sensitive information, the + "request_uri" SHOULD be used only once and have a short validity + period, and it MUST have sufficient entropy for the applicable + security policies unless the Request Object itself is encrypted using + JWE [RFC7516]. The adequate shortness of the validity and the + entropy of the Request Object URI depends on the risk calculation + based on the value of the resource being protected. A general + guidance for the validity time would be less than a minute, and the + Request Object URI is to include a cryptographic random value of 128 + bits or more at the time of the writing of this specification. + +11.2.2. Tracking Using Request Object URI + + Even if the protected resource does not include personally + identifiable information, it is sometimes possible to identify the + user through the Request Object URI if persistent static per-user + Request Object URIs are used. A third party may observe it through + browser history, etc. and start correlating the user's activity using + it. In a way, it is a data disclosure as well and should be avoided. + + Therefore, per-user persistent Request Object URIs should be avoided. + Single-use Request Object URIs are one alternative. + +12. References + +12.1. Normative References + + [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate + Requirement Levels", BCP 14, RFC 2119, + DOI 10.17487/RFC2119, March 1997, + . + + [RFC3629] Yergeau, F., "UTF-8, a transformation format of ISO + 10646", STD 63, RFC 3629, DOI 10.17487/RFC3629, November + 2003, . + + [RFC3986] Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform + Resource Identifier (URI): Generic Syntax", STD 66, + RFC 3986, DOI 10.17487/RFC3986, January 2005, + . + + [RFC6125] Saint-Andre, P. and J. Hodges, "Representation and + Verification of Domain-Based Application Service Identity + within Internet Public Key Infrastructure Using X.509 + (PKIX) Certificates in the Context of Transport Layer + Security (TLS)", RFC 6125, DOI 10.17487/RFC6125, March + 2011, . + + [RFC6749] Hardt, D., Ed., "The OAuth 2.0 Authorization Framework", + RFC 6749, DOI 10.17487/RFC6749, October 2012, + . + + [RFC6750] Jones, M. and D. Hardt, "The OAuth 2.0 Authorization + Framework: Bearer Token Usage", RFC 6750, + DOI 10.17487/RFC6750, October 2012, + . + + [RFC7230] Fielding, R., Ed. and J. Reschke, Ed., "Hypertext Transfer + Protocol (HTTP/1.1): Message Syntax and Routing", + RFC 7230, DOI 10.17487/RFC7230, June 2014, + . + + [RFC7515] Jones, M., Bradley, J., and N. Sakimura, "JSON Web + Signature (JWS)", RFC 7515, DOI 10.17487/RFC7515, May + 2015, . + + [RFC7516] Jones, M. and J. Hildebrand, "JSON Web Encryption (JWE)", + RFC 7516, DOI 10.17487/RFC7516, May 2015, + . + + [RFC7518] Jones, M., "JSON Web Algorithms (JWA)", RFC 7518, + DOI 10.17487/RFC7518, May 2015, + . + + [RFC7519] Jones, M., Bradley, J., and N. Sakimura, "JSON Web Token + (JWT)", RFC 7519, DOI 10.17487/RFC7519, May 2015, + . + + [RFC7525] Sheffer, Y., Holz, R., and P. Saint-Andre, + "Recommendations for Secure Use of Transport Layer + Security (TLS) and Datagram Transport Layer Security + (DTLS)", BCP 195, RFC 7525, DOI 10.17487/RFC7525, May + 2015, . + + [RFC8141] Saint-Andre, P. and J. Klensin, "Uniform Resource Names + (URNs)", RFC 8141, DOI 10.17487/RFC8141, April 2017, + . + + [RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC + 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174, + May 2017, . + + [RFC8259] Bray, T., Ed., "The JavaScript Object Notation (JSON) Data + Interchange Format", STD 90, RFC 8259, + DOI 10.17487/RFC8259, December 2017, + . + + [RFC8414] Jones, M., Sakimura, N., and J. Bradley, "OAuth 2.0 + Authorization Server Metadata", RFC 8414, + DOI 10.17487/RFC8414, June 2018, + . + +12.2. Informative References + + [BASIN] Basin, D., Cremers, C., and S. Meier, "Provably Repairing + the ISO/IEC 9798 Standard for Entity Authentication", + Journal of Computer Security - Security and Trust + Principles, Volume 21, Issue 6, pp. 817-846, November + 2013, + . + + [CapURLs] Tennison, J., Ed., "Good Practices for Capability URLs", + W3C First Public Working Draft, 18 February 2014, + . + + [IANA.JWT.Claims] + IANA, "JSON Web Token (JWT)", + . + + [IANA.MediaTypes] + IANA, "Media Types", + . + + [IANA.OAuth.Parameters] + IANA, "OAuth Parameters", + . + + [OpenID.Core] + Sakimura, N., Bradley, J., Jones, M.B., de Medeiros, B., + and C. Mortimore, "OpenID Connect Core 1.0 incorporating + errata set 1", OpenID Foundation Standards, 8 November + 2014, + . + + [RFC2046] Freed, N. and N. Borenstein, "Multipurpose Internet Mail + Extensions (MIME) Part Two: Media Types", RFC 2046, + DOI 10.17487/RFC2046, November 1996, + . + + [RFC6819] Lodderstedt, T., Ed., McGloin, M., and P. Hunt, "OAuth 2.0 + Threat Model and Security Considerations", RFC 6819, + DOI 10.17487/RFC6819, January 2013, + . + + [RFC6838] Freed, N., Klensin, J., and T. Hansen, "Media Type + Specifications and Registration Procedures", BCP 13, + RFC 6838, DOI 10.17487/RFC6838, January 2013, + . + + [RFC6973] Cooper, A., Tschofenig, H., Aboba, B., Peterson, J., + Morris, J., Hansen, M., and R. Smith, "Privacy + Considerations for Internet Protocols", RFC 6973, + DOI 10.17487/RFC6973, July 2013, + . + + [RFC7523] Jones, M., Campbell, B., and C. Mortimore, "JSON Web Token + (JWT) Profile for OAuth 2.0 Client Authentication and + Authorization Grants", RFC 7523, DOI 10.17487/RFC7523, May + 2015, . + + [RFC7591] Richer, J., Ed., Jones, M., Bradley, J., Machulak, M., and + P. Hunt, "OAuth 2.0 Dynamic Client Registration Protocol", + RFC 7591, DOI 10.17487/RFC7591, July 2015, + . + + [RFC8725] Sheffer, Y., Hardt, D., and M. Jones, "JSON Web Token Best + Current Practices", BCP 225, RFC 8725, + DOI 10.17487/RFC8725, February 2020, + . + +Acknowledgements + + The following people contributed to the creation of this document in + the OAuth Working Group and other IETF roles. (Affiliations at the + time of the contribution are used.) + + Annabelle Backman (Amazon), Dirk Balfanz (Google), Sergey Beryozkin, + Ben Campbell (as AD), Brian Campbell (Ping Identity), Roman Danyliw + (as AD), Martin Duke (as AD), Vladimir Dzhuvinov (Connect2id), Lars + Eggert (as AD), Joel Halpern (as GENART), Benjamin Kaduk (as AD), + Stephen Kent (as SECDIR), Murray Kucherawy (as AD), Warren Kumari (as + OPSDIR), Watson Ladd (as SECDIR), Torsten Lodderstedt (yes.com), Jim + Manico, James H. Manger (Telstra), Kathleen Moriarty (as AD), Axel + Nennker (Deutsche Telecom), John Panzer (Google), Francesca Palombini + (as AD), David Recordon (Facebook), Marius Scurtescu (Google), Luke + Shepard (Facebook), Filip Skokan (Auth0), Hannes Tschofenig (ARM), + Éric Vyncke (as AD), and Robert Wilton (as AD). + + The following people contributed to creating this document through + the OpenID Connect Core 1.0 [OpenID.Core]. + + Brian Campbell (Ping Identity), George Fletcher (AOL), Ryo Itou + (Mixi), Edmund Jay (Illumila), Breno de Medeiros (Google), Hideki + Nara (TACT), and Justin Richer (MITRE). + +Authors' Addresses + + Nat Sakimura + NAT.Consulting + 2-22-17 Naka + Kunitachi, Tokyo 186-0004 + Japan + + Phone: +81-42-580-7401 + Email: nat@nat.consulting + URI: https://nat.sakimura.org/ + + + John Bradley + Yubico + Sucursal Talagante + Casilla 177 + Talagante + RM + Chile + + Phone: +1.202.630.5272 + Email: rfc9101@ve7jtb.com + URI: http://www.thread-safe.com/ + + + Michael B. Jones + Microsoft + One Microsoft Way + Redmond, Washington 98052 + United States of America + + Email: mbj@microsoft.com + URI: https://self-issued.info/ -- cgit v1.2.3