rfc9700.original | rfc9700.txt | |||
---|---|---|---|---|
Web Authorization Protocol T. Lodderstedt | Internet Engineering Task Force (IETF) T. Lodderstedt | |||
Internet-Draft SPRIND | Request for Comments: 9700 SPRIND | |||
Updates: 6749, 6750, 6819 (if approved) J. Bradley | BCP: 240 J. Bradley | |||
Intended status: Best Current Practice Yubico | Updates: 6749, 6750, 6819 Yubico | |||
Expires: 5 December 2024 A. Labunets | Category: Best Current Practice A. Labunets | |||
Independent Researcher | ISSN: 2070-1721 Independent Researcher | |||
D. Fett | D. Fett | |||
Authlete | Authlete | |||
3 June 2024 | November 2024 | |||
OAuth 2.0 Security Best Current Practice | Best Current Practice for OAuth 2.0 Security | |||
draft-ietf-oauth-security-topics-29 | ||||
Abstract | Abstract | |||
This document describes best current security practice for OAuth 2.0. | This document describes best current security practice for OAuth 2.0. | |||
It updates and extends the threat model and security advice given in | It updates and extends the threat model and security advice given in | |||
RFC 6749, RFC 6750, and RFC 6819 to incorporate practical experiences | RFCs 6749, 6750, and 6819 to incorporate practical experiences | |||
gathered since OAuth 2.0 was published and covers new threats | gathered since OAuth 2.0 was published and covers new threats | |||
relevant due to the broader application of OAuth 2.0. Further, it | relevant due to the broader application of OAuth 2.0. Further, it | |||
deprecates some modes of operation that are deemed less secure or | deprecates some modes of operation that are deemed less secure or | |||
even insecure. | even insecure. | |||
Discussion Venues | ||||
This note is to be removed before publishing as an RFC. | ||||
Discussion of this document takes place on the Web Authorization | ||||
Protocol Working Group mailing list (oauth@ietf.org), which is | ||||
archived at https://mailarchive.ietf.org/arch/browse/oauth/. | ||||
Source for this draft and an issue tracker can be found at | ||||
https://github.com/oauthstuff/draft-ietf-oauth-security-topics. | ||||
Status of This Memo | Status of This Memo | |||
This Internet-Draft is submitted in full conformance with the | This memo documents an Internet Best Current Practice. | |||
provisions of BCP 78 and BCP 79. | ||||
Internet-Drafts are working documents of the Internet Engineering | ||||
Task Force (IETF). Note that other groups may also distribute | ||||
working documents as Internet-Drafts. The list of current Internet- | ||||
Drafts is at https://datatracker.ietf.org/drafts/current/. | ||||
Internet-Drafts are draft documents valid for a maximum of six months | This document is a product of the Internet Engineering Task Force | |||
and may be updated, replaced, or obsoleted by other documents at any | (IETF). It represents the consensus of the IETF community. It has | |||
time. It is inappropriate to use Internet-Drafts as reference | received public review and has been approved for publication by the | |||
material or to cite them other than as "work in progress." | Internet Engineering Steering Group (IESG). Further information on | |||
BCPs is available in Section 2 of RFC 7841. | ||||
This Internet-Draft will expire on 5 December 2024. | 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/rfc9700. | ||||
Copyright Notice | Copyright Notice | |||
Copyright (c) 2024 IETF Trust and the persons identified as the | Copyright (c) 2024 IETF Trust and the persons identified as the | |||
document authors. All rights reserved. | document authors. All rights reserved. | |||
This document is subject to BCP 78 and the IETF Trust's Legal | This document is subject to BCP 78 and the IETF Trust's Legal | |||
Provisions Relating to IETF Documents (https://trustee.ietf.org/ | Provisions Relating to IETF Documents | |||
license-info) in effect on the date of publication of this document. | (https://trustee.ietf.org/license-info) in effect on the date of | |||
Please review these documents carefully, as they describe your rights | publication of this document. Please review these documents | |||
and restrictions with respect to this document. Code Components | carefully, as they describe your rights and restrictions with respect | |||
extracted from this document must include Revised BSD License text as | to this document. Code Components extracted from this document must | |||
described in Section 4.e of the Trust Legal Provisions and are | include Revised BSD License text as described in Section 4.e of the | |||
provided without warranty as described in the Revised BSD License. | Trust Legal Provisions and are provided without warranty as described | |||
in the Revised BSD License. | ||||
Table of Contents | Table of Contents | |||
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 4 | 1. Introduction | |||
1.1. Structure . . . . . . . . . . . . . . . . . . . . . . . . 5 | 1.1. Structure | |||
1.2. Conventions and Terminology . . . . . . . . . . . . . . . 5 | 1.2. Conventions and Terminology | |||
2. Best Practices . . . . . . . . . . . . . . . . . . . . . . . 6 | 2. Best Practices | |||
2.1. Protecting Redirect-Based Flows . . . . . . . . . . . . . 6 | 2.1. Protecting Redirect-Based Flows | |||
2.1.1. Authorization Code Grant . . . . . . . . . . . . . . 7 | 2.1.1. Authorization Code Grant | |||
2.1.2. Implicit Grant . . . . . . . . . . . . . . . . . . . 8 | 2.1.2. Implicit Grant | |||
2.2. Token Replay Prevention . . . . . . . . . . . . . . . . . 9 | 2.2. Token Replay Prevention | |||
2.2.1. Access Tokens . . . . . . . . . . . . . . . . . . . . 9 | 2.2.1. Access Tokens | |||
2.2.2. Refresh Tokens . . . . . . . . . . . . . . . . . . . 9 | 2.2.2. Refresh Tokens | |||
2.3. Access Token Privilege Restriction . . . . . . . . . . . 9 | 2.3. Access Token Privilege Restriction | |||
2.4. Resource Owner Password Credentials Grant . . . . . . . . 10 | 2.4. Resource Owner Password Credentials Grant | |||
2.5. Client Authentication . . . . . . . . . . . . . . . . . . 10 | 2.5. Client Authentication | |||
2.6. Other Recommendations . . . . . . . . . . . . . . . . . . 10 | 2.6. Other Recommendations | |||
3. The Updated OAuth 2.0 Attacker Model . . . . . . . . . . . . 11 | 3. The Updated OAuth 2.0 Attacker Model | |||
4. Attacks and Mitigations . . . . . . . . . . . . . . . . . . . 14 | 4. Attacks and Mitigations | |||
4.1. Insufficient Redirect URI Validation . . . . . . . . . . 14 | 4.1. Insufficient Redirection URI Validation | |||
4.1.1. Redirect URI Validation Attacks on Authorization Code | 4.1.1. Redirect URI Validation Attacks on Authorization Code | |||
Grant . . . . . . . . . . . . . . . . . . . . . . . . 14 | Grant | |||
4.1.2. Redirect URI Validation Attacks on Implicit Grant . . 16 | 4.1.2. Redirect URI Validation Attacks on Implicit Grant | |||
4.1.3. Countermeasures . . . . . . . . . . . . . . . . . . . 17 | 4.1.3. Countermeasures | |||
4.2. Credential Leakage via Referer Headers . . . . . . . . . 18 | 4.2. Credential Leakage via Referer Headers | |||
4.2.1. Leakage from the OAuth Client . . . . . . . . . . . . 18 | 4.2.1. Leakage from the OAuth Client | |||
4.2.2. Leakage from the Authorization Server . . . . . . . . 19 | 4.2.2. Leakage from the Authorization Server | |||
4.2.3. Consequences . . . . . . . . . . . . . . . . . . . . 19 | 4.2.3. Consequences | |||
4.2.4. Countermeasures . . . . . . . . . . . . . . . . . . . 19 | 4.2.4. Countermeasures | |||
4.3. Credential Leakage via Browser History . . . . . . . . . 20 | 4.3. Credential Leakage via Browser History | |||
4.3.1. Authorization Code in Browser History . . . . . . . . 20 | 4.3.1. Authorization Code in Browser History | |||
4.3.2. Access Token in Browser History . . . . . . . . . . . 20 | 4.3.2. Access Token in Browser History | |||
4.4. Mix-Up Attacks . . . . . . . . . . . . . . . . . . . . . 21 | 4.4. Mix-Up Attacks | |||
4.4.1. Attack Description . . . . . . . . . . . . . . . . . 21 | 4.4.1. Attack Description | |||
4.4.2. Countermeasures . . . . . . . . . . . . . . . . . . . 23 | 4.4.2. Countermeasures | |||
4.4.2.1. Mix-Up Defense via Issuer Identification . . . . 24 | 4.4.2.1. Mix-Up Defense via Issuer Identification | |||
4.4.2.2. Mix-Up Defense via Distinct Redirect URIs . . . . 24 | 4.4.2.2. Mix-Up Defense via Distinct Redirect URIs | |||
4.5. Authorization Code Injection . . . . . . . . . . . . . . 25 | 4.5. Authorization Code Injection | |||
4.5.1. Attack Description . . . . . . . . . . . . . . . . . 25 | 4.5.1. Attack Description | |||
4.5.2. Discussion . . . . . . . . . . . . . . . . . . . . . 26 | 4.5.2. Discussion | |||
4.5.3. Countermeasures . . . . . . . . . . . . . . . . . . . 27 | 4.5.3. Countermeasures | |||
4.5.3.1. PKCE . . . . . . . . . . . . . . . . . . . . . . 27 | 4.5.3.1. PKCE | |||
4.5.3.2. Nonce . . . . . . . . . . . . . . . . . . . . . . 28 | 4.5.3.2. Nonce | |||
4.5.3.3. Other Solutions . . . . . . . . . . . . . . . . . 28 | 4.5.3.3. Other Solutions | |||
4.5.4. Limitations . . . . . . . . . . . . . . . . . . . . . 29 | 4.5.4. Limitations | |||
4.6. Access Token Injection . . . . . . . . . . . . . . . . . 29 | 4.6. Access Token Injection | |||
4.6.1. Countermeasures . . . . . . . . . . . . . . . . . . . 29 | 4.6.1. Countermeasures | |||
4.7. Cross-Site Request Forgery . . . . . . . . . . . . . . . 30 | 4.7. Cross-Site Request Forgery | |||
4.7.1. Countermeasures . . . . . . . . . . . . . . . . . . . 30 | 4.7.1. Countermeasures | |||
4.8. PKCE Downgrade Attack . . . . . . . . . . . . . . . . . . 31 | 4.8. PKCE Downgrade Attack | |||
4.8.1. Attack Description . . . . . . . . . . . . . . . . . 31 | 4.8.1. Attack Description | |||
4.8.2. Countermeasures . . . . . . . . . . . . . . . . . . . 32 | 4.8.2. Countermeasures | |||
4.9. Access Token Leakage at the Resource Server . . . . . . . 33 | 4.9. Access Token Leakage at the Resource Server | |||
4.9.1. Access Token Phishing by Counterfeit Resource | 4.9.1. Access Token Phishing by Counterfeit Resource Server | |||
Server . . . . . . . . . . . . . . . . . . . . . . . 33 | 4.9.2. Compromised Resource Server | |||
4.9.2. Compromised Resource Server . . . . . . . . . . . . . 33 | 4.9.3. Countermeasures | |||
4.9.3. Countermeasures . . . . . . . . . . . . . . . . . . . 34 | 4.10. Misuse of Stolen Access Tokens | |||
4.10. Misuse of Stolen Access Tokens . . . . . . . . . . . . . 34 | 4.10.1. Sender-Constrained Access Tokens | |||
4.10.1. Sender-Constrained Access Tokens . . . . . . . . . . 34 | 4.10.2. Audience-Restricted Access Tokens | |||
4.10.2. Audience-Restricted Access Tokens . . . . . . . . . 36 | 4.10.3. Discussion: Preventing Leakage via Metadata | |||
4.10.3. Discussion: Preventing Leakage via Metadata . . . . 37 | 4.11. Open Redirection | |||
4.11. Open Redirection . . . . . . . . . . . . . . . . . . . . 38 | 4.11.1. Client as Open Redirector | |||
4.11.1. Client as Open Redirector . . . . . . . . . . . . . 38 | 4.11.2. Authorization Server as Open Redirector | |||
4.11.2. Authorization Server as Open Redirector . . . . . . 39 | 4.12. 307 Redirect | |||
4.12. 307 Redirect . . . . . . . . . . . . . . . . . . . . . . 40 | 4.13. TLS Terminating Reverse Proxies | |||
4.13. TLS Terminating Reverse Proxies . . . . . . . . . . . . . 41 | 4.14. Refresh Token Protection | |||
4.14. Refresh Token Protection . . . . . . . . . . . . . . . . 42 | 4.14.1. Discussion | |||
4.14.1. Discussion . . . . . . . . . . . . . . . . . . . . . 42 | 4.14.2. Recommendations | |||
4.14.2. Recommendations . . . . . . . . . . . . . . . . . . 42 | 4.15. Client Impersonating Resource Owner | |||
4.15. Client Impersonating Resource Owner . . . . . . . . . . . 44 | 4.15.1. Countermeasures | |||
4.15.1. Countermeasures . . . . . . . . . . . . . . . . . . 44 | 4.16. Clickjacking | |||
4.16. Clickjacking . . . . . . . . . . . . . . . . . . . . . . 44 | 4.17. Attacks on In-Browser Communication Flows | |||
4.17. Attacks on In-Browser Communication Flows . . . . . . . . 46 | 4.17.1. Examples | |||
4.17.1. Examples . . . . . . . . . . . . . . . . . . . . . . 46 | 4.17.1.1. Insufficient Limitation of Receiver Origins | |||
4.17.1.1. Insufficient Limitation of Receiver Origins . . 46 | 4.17.1.2. Insufficient URI Validation | |||
4.17.1.2. Insufficient URI Validation . . . . . . . . . . 46 | ||||
4.17.1.3. Injection after Insufficient Validation of Sender | 4.17.1.3. Injection after Insufficient Validation of Sender | |||
Origin . . . . . . . . . . . . . . . . . . . . . . 47 | Origin | |||
4.17.2. Recommendations . . . . . . . . . . . . . . . . . . 47 | 4.17.2. Recommendations | |||
5. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 48 | 5. IANA Considerations | |||
6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 48 | 6. Security Considerations | |||
7. Security Considerations . . . . . . . . . . . . . . . . . . . 48 | 7. References | |||
8. References . . . . . . . . . . . . . . . . . . . . . . . . . 48 | 7.1. Normative References | |||
8.1. Normative References . . . . . . . . . . . . . . . . . . 48 | 7.2. Informative References | |||
8.2. Informative References . . . . . . . . . . . . . . . . . 49 | Acknowledgements | |||
Appendix A. Document History . . . . . . . . . . . . . . . . . . 54 | Authors' Addresses | |||
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 59 | ||||
1. Introduction | 1. Introduction | |||
Since its publication in [RFC6749] and [RFC6750], OAuth 2.0 (referred | Since its publication in [RFC6749] and [RFC6750], OAuth 2.0 (referred | |||
to as simply "OAuth" in the following) has gained massive traction in | to as simply "OAuth" in this document) has gained massive traction in | |||
the market and became the standard for API protection and the basis | the market and became the standard for API protection and the basis | |||
for federated login using OpenID Connect [OpenID.Core]. While OAuth | for federated login using OpenID Connect [OpenID.Core]. While OAuth | |||
is used in a variety of scenarios and different kinds of deployments, | is used in a variety of scenarios and different kinds of deployments, | |||
the following challenges can be observed: | the following challenges can be observed: | |||
* OAuth implementations are being attacked through known | * OAuth implementations are being attacked through known | |||
implementation weaknesses and anti-patterns (i.e., well-known | implementation weaknesses and anti-patterns (i.e., well-known | |||
patterns that are considered insecure). Although most of these | patterns that are considered insecure). Although most of these | |||
threats are discussed in the OAuth 2.0 Threat Model and Security | threats are discussed in the OAuth 2.0 Threat Model and Security | |||
Considerations [RFC6819], continued exploitation demonstrates a | Considerations [RFC6819], continued exploitation demonstrates a | |||
need for more specific recommendations, easier to implement | need for more specific recommendations, easier to implement | |||
mitigations, and more defense in depth. | mitigations, and more defense in depth. | |||
* OAuth is being used in environments with higher security | * OAuth is being used in environments with higher security | |||
requirements than considered initially, such as Open Banking, | requirements than considered initially, such as open banking, | |||
eHealth, eGovernment, and Electronic Signatures. Those use cases | eHealth, eGovernment, and electronic signatures. Those use cases | |||
call for stricter guidelines and additional protection. | call for stricter guidelines and additional protection. | |||
* OAuth is being used in much more dynamic setups than originally | * OAuth is being used in much more dynamic setups than originally | |||
anticipated, creating new challenges with respect to security. | anticipated, creating new challenges with respect to security. | |||
Those challenges go beyond the original scope of [RFC6749], | Those challenges go beyond the original scope of [RFC6749], | |||
[RFC6750], and [RFC6819]. | [RFC6750], and [RFC6819]. | |||
OAuth initially assumed static relationships between clients, | OAuth initially assumed static relationships between clients, | |||
authorization servers, and resource servers. The URLs of the | authorization servers, and resource servers. The URLs of the | |||
servers were known to the client at deployment time and built an | servers were known to the client at deployment time and built an | |||
anchor for the trust relationships among those parties. The | anchor for the trust relationships among those parties. The | |||
validation of whether the client is talking to a legitimate server | validation of whether the client is talking to a legitimate server | |||
was based on TLS server authentication (see [RFC6819], | was based on TLS server authentication (see Section 4.5.4 of | |||
Section 4.5.4). With the increasing adoption of OAuth, this | [RFC6819]). With the increasing adoption of OAuth, this simple | |||
simple model dissolved and, in several scenarios, was replaced by | model dissolved and, in several scenarios, was replaced by a | |||
a dynamic establishment of the relationship between clients on one | dynamic establishment of the relationship between clients on one | |||
side and the authorization and resource servers of a particular | side and the authorization and resource servers of a particular | |||
deployment on the other side. This way, the same client could be | deployment on the other side. This way, the same client could be | |||
used to access services of different providers (in case of | used to access services of different providers (in case of | |||
standard APIs, such as e-mail or OpenID Connect) or serve as a | standard APIs, such as email or OpenID Connect) or serve as a | |||
front end to a particular tenant in a multi-tenant environment. | front end to a particular tenant in a multi-tenant environment. | |||
Extensions of OAuth, such as the OAuth 2.0 Dynamic Client | Extensions of OAuth, such as the OAuth 2.0 Dynamic Client | |||
Registration Protocol [RFC7591] and OAuth 2.0 Authorization Server | Registration Protocol [RFC7591] and OAuth 2.0 Authorization Server | |||
Metadata [RFC8414] were developed to support the use of OAuth in | Metadata [RFC8414] were developed to support the use of OAuth in | |||
dynamic scenarios. | dynamic scenarios. | |||
* Technology has changed. For example, the way browsers treat | * Technology has changed. For example, the way browsers treat | |||
fragments when redirecting requests has changed, and with it, the | fragments when redirecting requests has changed, and with it, the | |||
implicit grant's underlying security model. | implicit grant's underlying security model. | |||
This document provides updated security recommendations to address | This document provides updated security recommendations to address | |||
these challenges. It introduces new requirements beyond those | these challenges. It introduces new requirements beyond those | |||
defined in existing specifications such as OAuth 2.0 [RFC6749] and | defined in existing specifications such as OAuth 2.0 [RFC6749] and | |||
OpenID Connect [OpenID.Core] and deprecates some modes of operation | OpenID Connect [OpenID.Core] and deprecates some modes of operation | |||
that are deemed less secure or even insecure. However, this document | that are deemed less secure or even insecure. However, this document | |||
does not supplant the security advice given in [RFC6749], [RFC6750], | does not supplant the security advice given in [RFC6749], [RFC6750], | |||
and [RFC6819], but complements those documents. | and [RFC6819], but complements those documents. | |||
Naturally, not all existing ecosystems and implementations are | Naturally, not all existing ecosystems and implementations are | |||
compatible with the new requirements and following the best practices | compatible with the new requirements, and following the best | |||
described in this document may break interoperability. Nonetheless, | practices described in this document may break interoperability. | |||
it is RECOMMENDED that implementers upgrade their implementations and | Nonetheless, it is RECOMMENDED that implementers upgrade their | |||
ecosystems as soon as feasible. | implementations and ecosystems as soon as feasible. | |||
OAuth 2.1, under developement as [I-D.ietf-oauth-v2-1], will | OAuth 2.1, under development as [OAUTH-V2.1], will incorporate | |||
incorporate security recommendations from this document. | security recommendations from this document. | |||
1.1. Structure | 1.1. Structure | |||
The remainder of this document is organized as follows: The next | The remainder of this document is organized as follows: Section 2 | |||
section summarizes the most important best practices for every OAuth | summarizes the most important best practices for every OAuth | |||
implementor. Afterwards, the updated OAuth attacker model is | implementer. Section 3 presents the updated OAuth attacker model. | |||
presented. Subsequently, a detailed analysis of the threats and | Section 4 is a detailed analysis of the threats and implementation | |||
implementation issues that can be found in the wild today is given | issues that can be found in the wild (at the time of writing) along | |||
along with a discussion of potential countermeasures. | with a discussion of potential countermeasures. | |||
1.2. Conventions and Terminology | 1.2. Conventions and Terminology | |||
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", | The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", | |||
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and | "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and | |||
"OPTIONAL" in this document are to be interpreted as described in BCP | "OPTIONAL" in this document are to be interpreted as described in | |||
14 [RFC2119] [RFC8174] when, and only when, they appear in all | BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all | |||
capitals, as shown here. | capitals, as shown here. | |||
This specification uses the terms "access token", "authorization | This specification uses the terms "access token", "authorization | |||
endpoint", "authorization grant", "authorization server", "client", | endpoint", "authorization grant", "authorization server", "client", | |||
"client identifier" (client ID), "protected resource", "refresh | "client identifier" (client ID), "protected resource", "refresh | |||
token", "resource owner", "resource server", and "token endpoint" | token", "resource owner", "resource server", and "token endpoint" | |||
defined by OAuth 2.0 [RFC6749]. | defined by OAuth 2.0 [RFC6749]. | |||
An "open redirector" is an endpoint on a web server that forwards a | An "open redirector" is an endpoint on a web server that forwards a | |||
user’s browser to an arbitrary URI obtained from a query parameter. | user's browser to an arbitrary URI obtained from a query parameter. | |||
2. Best Practices | 2. Best Practices | |||
This section describes the core set of security mechanisms and | This section describes the core set of security mechanisms and | |||
measures that are considered to be best practices at the time of | measures that are considered to be best practices at the time of | |||
writing. Details about these security mechanisms and measures | writing. Details about these security mechanisms and measures | |||
(including detailed attack descriptions) and requirements for less | (including detailed attack descriptions) and requirements for less | |||
commonly used options are provided in Section 4. | commonly used options are provided in Section 4. | |||
2.1. Protecting Redirect-Based Flows | 2.1. Protecting Redirect-Based Flows | |||
When comparing client redirect URIs against pre-registered URIs, | When comparing client redirection URIs against pre-registered URIs, | |||
authorization servers MUST utilize exact string matching except for | authorization servers MUST utilize exact string matching except for | |||
port numbers in localhost redirection URIs of native apps (see | port numbers in localhost redirection URIs of native apps (see | |||
Section 4.1.3). This measure contributes to the prevention of | Section 4.1.3). This measure contributes to the prevention of | |||
leakage of authorization codes and access tokens (see Section 4.1). | leakage of authorization codes and access tokens (see Section 4.1). | |||
It can also help to detect mix-up attacks (see Section 4.4). | It can also help to detect mix-up attacks (see Section 4.4). | |||
Clients and authorization servers MUST NOT expose URLs that forward | Clients and authorization servers MUST NOT expose URLs that forward | |||
the user's browser to arbitrary URIs obtained from a query parameter | the user's browser to arbitrary URIs obtained from a query parameter | |||
(open redirectors) as described in Section 4.11. Open redirectors | (open redirectors) as described in Section 4.11. Open redirectors | |||
can enable exfiltration of authorization codes and access tokens. | can enable exfiltration of authorization codes and access tokens. | |||
Clients MUST prevent Cross-Site Request Forgery (CSRF). In this | Clients MUST prevent Cross-Site Request Forgery (CSRF). In this | |||
context, CSRF refers to requests to the redirection endpoint that do | context, CSRF refers to requests to the redirection endpoint that do | |||
not originate at the authorization server, but a malicious third | not originate at the authorization server, but at a malicious third | |||
party (see Section 4.4.1.8. of [RFC6819] for details). Clients that | party (see Section 4.4.1.8 of [RFC6819] for details). Clients that | |||
have ensured that the authorization server supports Proof Key for | have ensured that the authorization server supports Proof Key for | |||
Code Exchange (PKCE, [RFC7636]) MAY rely on the CSRF protection | Code Exchange (PKCE) [RFC7636] MAY rely on the CSRF protection | |||
provided by PKCE. In OpenID Connect flows, the nonce parameter | provided by PKCE. In OpenID Connect flows, the nonce parameter | |||
provides CSRF protection. Otherwise, one-time use CSRF tokens | provides CSRF protection. Otherwise, one-time use CSRF tokens | |||
carried in the state parameter that are securely bound to the user | carried in the state parameter that are securely bound to the user | |||
agent MUST be used for CSRF protection (see Section 4.7.1). | agent MUST be used for CSRF protection (see Section 4.7.1). | |||
When an OAuth client can interact with more than one authorization | When an OAuth client can interact with more than one authorization | |||
server, a defense against mix-up attacks (see Section 4.4) is | server, a defense against mix-up attacks (see Section 4.4) is | |||
REQUIRED. To this end, clients SHOULD | REQUIRED. To this end, clients SHOULD | |||
* use the iss parameter as a countermeasure according to [RFC9207], | * use the iss parameter as a countermeasure according to [RFC9207], | |||
skipping to change at page 7, line 4 ¶ | skipping to change at line 270 ¶ | |||
provides CSRF protection. Otherwise, one-time use CSRF tokens | provides CSRF protection. Otherwise, one-time use CSRF tokens | |||
carried in the state parameter that are securely bound to the user | carried in the state parameter that are securely bound to the user | |||
agent MUST be used for CSRF protection (see Section 4.7.1). | agent MUST be used for CSRF protection (see Section 4.7.1). | |||
When an OAuth client can interact with more than one authorization | When an OAuth client can interact with more than one authorization | |||
server, a defense against mix-up attacks (see Section 4.4) is | server, a defense against mix-up attacks (see Section 4.4) is | |||
REQUIRED. To this end, clients SHOULD | REQUIRED. To this end, clients SHOULD | |||
* use the iss parameter as a countermeasure according to [RFC9207], | * use the iss parameter as a countermeasure according to [RFC9207], | |||
or | or | |||
* use an alternative countermeasure based on an iss value in the | * use an alternative countermeasure based on an iss value in the | |||
authorization response (such as the iss Claim in the ID Token in | authorization response (such as the iss claim in the ID Token in | |||
[OpenID.Core] or in [OpenID.JARM] responses), processing it as | [OpenID.Core] or in [OpenID.JARM] responses), processing that | |||
described in [RFC9207]. | value as described in [RFC9207]. | |||
In the absence of these options, clients MAY instead use distinct | In the absence of these options, clients MAY instead use distinct | |||
redirect URIs to identify authorization endpoints and token | redirection URIs to identify authorization endpoints and token | |||
endpoints, as described in Section 4.4.2. | endpoints, as described in Section 4.4.2. | |||
An authorization server that redirects a request potentially | An authorization server that redirects a request potentially | |||
containing user credentials MUST avoid forwarding these user | containing user credentials MUST avoid forwarding these user | |||
credentials accidentally (see Section 4.12 for details). | credentials accidentally (see Section 4.12 for details). | |||
2.1.1. Authorization Code Grant | 2.1.1. Authorization Code Grant | |||
Clients MUST prevent authorization code injection attacks (see | Clients MUST prevent authorization code injection attacks (see | |||
Section 4.5) and misuse of authorization codes using one of the | Section 4.5) and misuse of authorization codes using one of the | |||
following options: | following options: | |||
* Public clients MUST use PKCE [RFC7636] to this end, as motivated | * Public clients MUST use PKCE [RFC7636] to this end, as motivated | |||
in Section 4.5.3.1. | in Section 4.5.3.1. | |||
* For confidential clients, the use of PKCE [RFC7636] is | * For confidential clients, the use of PKCE [RFC7636] is | |||
RECOMMENDED, as it provides strong protection against misuse and | RECOMMENDED, as it provides strong protection against misuse and | |||
injection of authorization codes as described in Section 4.5.3.1 | injection of authorization codes as described in Section 4.5.3.1. | |||
and, as a side-effect, prevents CSRF even in the presence of | Also, as a side effect, it prevents CSRF even in the presence of | |||
strong attackers as described in Section 4.7.1. | strong attackers as described in Section 4.7.1. | |||
* With additional precautions, described in Section 4.5.3.2, | * With additional precautions, described in Section 4.5.3.2, | |||
confidential OpenID Connect [OpenID.Core] clients MAY use the | confidential OpenID Connect [OpenID.Core] clients MAY use the | |||
nonce parameter and the respective Claim in the ID Token instead. | nonce parameter and the respective Claim in the ID Token instead. | |||
In any case, the PKCE challenge or OpenID Connect nonce MUST be | In any case, the PKCE challenge or OpenID Connect nonce MUST be | |||
transaction-specific and securely bound to the client and the user | transaction-specific and securely bound to the client and the user | |||
agent in which the transaction was started. Authorization servers | agent in which the transaction was started. Authorization servers | |||
are encouraged to make a reasonable effort at detecting and | are encouraged to make a reasonable effort at detecting and | |||
preventing the use of constant PKCE challenge or OpenID Connect nonce | preventing the use of constant values for the PKCE challenge or | |||
values. | OpenID Connect nonce. | |||
Note: Although PKCE was designed as a mechanism to protect native | Note: Although PKCE was designed as a mechanism to protect native | |||
apps, this advice applies to all kinds of OAuth clients, including | apps, this advice applies to all kinds of OAuth clients, including | |||
web applications. | web applications. | |||
When using PKCE, clients SHOULD use PKCE code challenge methods that | When using PKCE, clients SHOULD use PKCE code challenge methods that | |||
do not expose the PKCE verifier in the authorization request. | do not expose the PKCE verifier in the authorization request. | |||
Otherwise, attackers that can read the authorization request (cf. | Otherwise, attackers that can read the authorization request (cf. | |||
Attacker A4 in Section 3) can break the security provided by PKCE. | Attacker (A4) in Section 3) can break the security provided by PKCE. | |||
Currently, S256 is the only such method. | Currently, S256 is the only such method. | |||
Authorization servers MUST support PKCE [RFC7636]. | Authorization servers MUST support PKCE [RFC7636]. | |||
If a client sends a valid PKCE [RFC7636] code_challenge parameter in | If a client sends a valid PKCE code_challenge parameter in the | |||
the authorization request, the authorization server MUST enforce the | authorization request, the authorization server MUST enforce the | |||
correct usage of code_verifier at the token endpoint. | correct usage of code_verifier at the token endpoint. | |||
Authorization servers MUST mitigate PKCE Downgrade Attacks by | Authorization servers MUST mitigate PKCE downgrade attacks by | |||
ensuring that a token request containing a code_verifier parameter is | ensuring that a token request containing a code_verifier parameter is | |||
accepted only if a code_challenge parameter was present in the | accepted only if a code_challenge parameter was present in the | |||
authorization request, see Section 4.8.2 for details. | authorization request; see Section 4.8.2 for details. | |||
Authorization servers MUST provide a way to detect their support for | Authorization servers MUST provide a way to detect their support for | |||
PKCE. It is RECOMMENDED for authorization servers to publish the | PKCE. It is RECOMMENDED for authorization servers to publish the | |||
element code_challenge_methods_supported in their Authorization | element code_challenge_methods_supported in their Authorization | |||
Server Metadata ([RFC8414]) containing the supported PKCE challenge | Server Metadata [RFC8414] containing the supported PKCE challenge | |||
methods (which can be used by the client to detect PKCE support). | methods (which can be used by the client to detect PKCE support). | |||
Authorization servers MAY instead provide a deployment-specific way | Authorization servers MAY instead provide a deployment-specific way | |||
to ensure or determine PKCE support by the authorization server. | to ensure or determine PKCE support by the authorization server. | |||
2.1.2. Implicit Grant | 2.1.2. Implicit Grant | |||
The implicit grant (response type "token") and other response types | The implicit grant (response type token) and other response types | |||
causing the authorization server to issue access tokens in the | causing the authorization server to issue access tokens in the | |||
authorization response are vulnerable to access token leakage and | authorization response are vulnerable to access token leakage and | |||
access token replay as described in Section 4.1, Section 4.2, | access token replay as described in Sections 4.1, 4.2, 4.3, and 4.6. | |||
Section 4.3, and Section 4.6. | ||||
Moreover, no standardized method for sender-constraining exists to | Moreover, no standardized method for sender-constraining exists to | |||
bind access tokens to a specific client (as recommended in | bind access tokens to a specific client (as recommended in | |||
Section 2.2) when the access tokens are issued in the authorization | Section 2.2) when the access tokens are issued in the authorization | |||
response. This means that an attacker can use the leaked or stolen | response. This means that an attacker can use the leaked or stolen | |||
access token at a resource endpoint. | access token at a resource endpoint. | |||
In order to avoid these issues, clients SHOULD NOT use the implicit | In order to avoid these issues, clients SHOULD NOT use the implicit | |||
grant (response type "token") or other response types issuing access | grant (response type token) or other response types issuing access | |||
tokens in the authorization response, unless access token injection | tokens in the authorization response, unless access token injection | |||
in the authorization response is prevented and the aforementioned | in the authorization response is prevented and the aforementioned | |||
token leakage vectors are mitigated. | token leakage vectors are mitigated. | |||
Clients SHOULD instead use the response type code (i.e., | Clients SHOULD instead use the response type code (i.e., | |||
authorization code grant type) as specified in Section 2.1.1 or any | authorization code grant type) as specified in Section 2.1.1 or any | |||
other response type that causes the authorization server to issue | other response type that causes the authorization server to issue | |||
access tokens in the token response, such as the code id_token | access tokens in the token response, such as the code id_token | |||
response type. This allows the authorization server to detect replay | response type. This allows the authorization server to detect replay | |||
attempts by attackers and generally reduces the attack surface since | attempts by attackers and generally reduces the attack surface since | |||
access tokens are not exposed in URLs. It also allows the | access tokens are not exposed in URLs. It also allows the | |||
authorization server to sender-constrain the issued tokens (see next | authorization server to sender-constrain the issued tokens (see | |||
section). | Section 2.2. | |||
2.2. Token Replay Prevention | 2.2. Token Replay Prevention | |||
2.2.1. Access Tokens | 2.2.1. Access Tokens | |||
A sender-constrained access token scopes the applicability of an | A sender-constrained access token scopes the applicability of an | |||
access token to a certain sender. This sender is obliged to | access token to a certain sender. This sender is obliged to | |||
demonstrate knowledge of a certain secret as a prerequisite for the | demonstrate knowledge of a certain secret as a prerequisite for the | |||
acceptance of that token at the recipient (e.g., a resource server). | acceptance of that token at the recipient (e.g., a resource server). | |||
Authorization and resource servers SHOULD use mechanisms for sender- | Authorization and resource servers SHOULD use mechanisms for sender- | |||
constraining access tokens, such as Mutual TLS for OAuth 2.0 | constraining access tokens, such as mutual TLS for OAuth 2.0 | |||
[RFC8705] or OAuth 2.0 Demonstrating Proof of Possession (DPoP) | [RFC8705] or OAuth 2.0 Demonstrating Proof of Possession (DPoP) | |||
[RFC9449] (see Section 4.10.1), to prevent misuse of stolen and | [RFC9449] (see Section 4.10.1), to prevent misuse of stolen and | |||
leaked access tokens. | leaked access tokens. | |||
2.2.2. Refresh Tokens | 2.2.2. Refresh Tokens | |||
Refresh tokens for public clients MUST be sender-constrained or use | Refresh tokens for public clients MUST be sender-constrained or use | |||
refresh token rotation as described in Section 4.14. [RFC6749] | refresh token rotation as described in Section 4.14. [RFC6749] | |||
already mandates that refresh tokens for confidential clients can | already mandates that refresh tokens for confidential clients can | |||
only be used by the client for which they were issued. | only be used by the client for which they were issued. | |||
skipping to change at page 9, line 37 ¶ | skipping to change at line 397 ¶ | |||
2.3. Access Token Privilege Restriction | 2.3. Access Token Privilege Restriction | |||
The privileges associated with an access token SHOULD be restricted | The privileges associated with an access token SHOULD be restricted | |||
to the minimum required for the particular application or use case. | to the minimum required for the particular application or use case. | |||
This prevents clients from exceeding the privileges authorized by the | This prevents clients from exceeding the privileges authorized by the | |||
resource owner. It also prevents users from exceeding their | resource owner. It also prevents users from exceeding their | |||
privileges authorized by the respective security policy. Privilege | privileges authorized by the respective security policy. Privilege | |||
restrictions also help to reduce the impact of access token leakage. | restrictions also help to reduce the impact of access token leakage. | |||
In particular, access tokens SHOULD be audience-restricted to a | In particular, access tokens SHOULD be audience-restricted to a | |||
specific resource server, or, if that is not feasible, to a small set | specific resource server or, if that is not feasible, to a small set | |||
of resource servers. To put this into effect, the authorization | of resource servers. To put this into effect, the authorization | |||
server associates the access token with certain resource servers and | server associates the access token with certain resource servers, and | |||
every resource server is obliged to verify, for every request, | every resource server is obliged to verify, for every request, | |||
whether the access token sent with that request was meant to be used | whether the access token sent with that request was meant to be used | |||
for that particular resource server. If it was not, the resource | for that particular resource server. If it was not, the resource | |||
server MUST refuse to serve the respective request. The aud claim as | server MUST refuse to serve the respective request. The aud claim as | |||
defined in [RFC9068] MAY be used to audience-restrict access tokens. | defined in [RFC9068] MAY be used to audience-restrict access tokens. | |||
Clients and authorization servers MAY utilize the parameters scope or | Clients and authorization servers MAY utilize the parameters scope or | |||
resource as specified in [RFC6749] and [RFC8707], respectively, to | resource as specified in [RFC6749] and [RFC8707], respectively, to | |||
determine the resource server they want to access. | determine the resource server they want to access. | |||
Additionally, access tokens SHOULD be restricted to certain resources | Additionally, access tokens SHOULD be restricted to certain resources | |||
skipping to change at page 10, line 16 ¶ | skipping to change at line 425 ¶ | |||
particular resource. If not, the resource server must refuse to | particular resource. If not, the resource server must refuse to | |||
serve the respective request. Clients and authorization servers MAY | serve the respective request. Clients and authorization servers MAY | |||
utilize the parameter scope as specified in [RFC6749] and | utilize the parameter scope as specified in [RFC6749] and | |||
authorization_details as specified in [RFC9396] to determine those | authorization_details as specified in [RFC9396] to determine those | |||
resources and/or actions. | resources and/or actions. | |||
2.4. Resource Owner Password Credentials Grant | 2.4. Resource Owner Password Credentials Grant | |||
The resource owner password credentials grant [RFC6749] MUST NOT be | The resource owner password credentials grant [RFC6749] MUST NOT be | |||
used. This grant type insecurely exposes the credentials of the | used. This grant type insecurely exposes the credentials of the | |||
resource owner to the client. Even if the client is benign, this | resource owner to the client. Even if the client is benign, usage of | |||
results in an increased attack surface (credentials can leak in more | this grant results in an increased attack surface (i.e., credentials | |||
places than just the authorization server) and users are trained to | can leak in more places than just the authorization server) and in | |||
enter their credentials in places other than the authorization | training users to enter their credentials in places other than the | |||
server. | authorization server. | |||
Furthermore, the resource owner password credentials grant is not | Furthermore, the resource owner password credentials grant is not | |||
designed to work with two-factor authentication and authentication | designed to work with two-factor authentication and authentication | |||
processes that require multiple user interaction steps. | processes that require multiple user interaction steps. | |||
Authentication with cryptographic credentials (cf. WebCrypto | Authentication with cryptographic credentials (cf. WebCrypto | |||
[W3C.WebCrypto], WebAuthn [W3C.WebAuthn]) may be impossible to | [W3C.WebCrypto], WebAuthn [W3C.WebAuthn]) may be impossible to | |||
implement with this grant type, as it is usually bound to a specific | implement with this grant type, as it is usually bound to a specific | |||
web origin. | web origin. | |||
2.5. Client Authentication | 2.5. Client Authentication | |||
Authorization servers SHOULD enforce client authentication if it is | Authorization servers SHOULD enforce client authentication if it is | |||
feasible, in the particular deployment, to establish a process for | feasible, in the particular deployment, to establish a process for | |||
issuance/registration of credentials for clients and ensuring the | issuance/registration of credentials for clients and ensuring the | |||
confidentiality of those credentials. | confidentiality of those credentials. | |||
It is RECOMMENDED to use asymmetric cryptography for client | It is RECOMMENDED to use asymmetric cryptography for client | |||
authentication, such as mTLS [RFC8705] or signed JWTs ("Private Key | authentication, such as mutual TLS for OAuth 2.0 [RFC8705] or signed | |||
JWT") in accordance with [RFC7521] and [RFC7523] (in [OpenID.Core] | JWTs ("Private Key JWT") in accordance with [RFC7521] and [RFC7523]. | |||
defined as the client authentication method private_key_jwt). When | The latter is defined in [OpenID.Core] as the client authentication | |||
asymmetric cryptography for client authentication is used, | method private_key_jwt). When asymmetric cryptography for client | |||
authorization servers do not need to store sensitive symmetric keys, | authentication is used, authorization servers do not need to store | |||
making these methods more robust against leakage of keys. | sensitive symmetric keys, making these methods more robust against | |||
leakage of keys. | ||||
2.6. Other Recommendations | 2.6. Other Recommendations | |||
The use of OAuth Authorization Server Metadata [RFC8414] can help to | The use of OAuth Authorization Server Metadata [RFC8414] can help to | |||
improve the security of OAuth deployments: | improve the security of OAuth deployments: | |||
* It ensures that security features and other new OAuth features can | * It ensures that security features and other new OAuth features can | |||
be enabled automatically by compliant software libraries. | be enabled automatically by compliant software libraries. | |||
* It reduces chances for misconfigurations -- for example, | ||||
* It reduces chances for misconfigurations, for example | ||||
misconfigured endpoint URLs (that might belong to an attacker) or | misconfigured endpoint URLs (that might belong to an attacker) or | |||
misconfigured security features. | misconfigured security features. | |||
* It can help to facilitate rotation of cryptographic keys and to | * It can help to facilitate rotation of cryptographic keys and to | |||
ensure cryptographic agility. | ensure cryptographic agility. | |||
It is therefore RECOMMENDED that authorization servers publish OAuth | It is therefore RECOMMENDED that authorization servers publish OAuth | |||
Authorization Server Metadata according to [RFC8414] and that clients | Authorization Server Metadata according to [RFC8414] and that clients | |||
make use of this Authorization Server Metadata to configure | make use of this Authorization Server Metadata (when available) to | |||
themselves when available. | configure themselves. | |||
Under the conditions described in Section 4.15.1, authorization | Under the conditions described in Section 4.15.1, authorization | |||
servers SHOULD NOT allow clients to influence their client_id or any | servers SHOULD NOT allow clients to influence their client_id or any | |||
claim that could cause confusion with a genuine resource owner. | other claim that could cause confusion with a genuine resource owner. | |||
It is RECOMMENDED to use end-to-end TLS according to [BCP195] between | It is RECOMMENDED to use end-to-end TLS according to [BCP195] between | |||
the client and the resource server. If TLS traffic needs to be | the client and the resource server. If TLS traffic needs to be | |||
terminated at an intermediary, refer to Section 4.13 for further | terminated at an intermediary, refer to Section 4.13 for further | |||
security advice. | security advice. | |||
Authorization responses MUST NOT be transmitted over unencrypted | Authorization responses MUST NOT be transmitted over unencrypted | |||
network connections. To this end, authorization servers MUST NOT | network connections. To this end, authorization servers MUST NOT | |||
allow redirect URIs that use the http scheme except for native | allow redirection URIs that use the http scheme except for native | |||
clients that use Loopback Interface Redirection as described in | clients that use loopback interface redirection as described in | |||
[RFC8252], Section 7.3. | Section 7.3 of [RFC8252]. | |||
If the authorization response is sent with in-browser communication | If the authorization response is sent with in-browser communication | |||
techniques like postMessage [WHATWG.postmessage_api] instead of HTTP | techniques like postMessage [WHATWG.postmessage_api] instead of HTTP | |||
redirects, both the initiator and receiver of the in-browser message | redirects, both the initiator and receiver of the in-browser message | |||
MUST be strictly verified as described in Section 4.17. | MUST be strictly verified as described in Section 4.17. | |||
To support browser-based clients, endpoints directly accessed by such | To support browser-based clients, endpoints directly accessed by such | |||
clients including the Token Endpoint, Authorization Server Metadata | clients including the Token Endpoint, Authorization Server Metadata | |||
Endpoint, jwks_uri Endpoint, and the Dynamic Client Registration | Endpoint, jwks_uri Endpoint, and Dynamic Client Registration Endpoint | |||
Endpoint MAY support the use of Cross-Origin Resource Sharing (CORS, | MAY support the use of Cross-Origin Resource Sharing (CORS) | |||
[WHATWG.CORS]). However, CORS MUST NOT be supported at the | [WHATWG.CORS]. However, CORS MUST NOT be supported at the | |||
Authorization Endpoint, as the client does not access this endpoint | authorization endpoint, as the client does not access this endpoint | |||
directly; instead, the client redirects the user agent to it. | directly; instead, the client redirects the user agent to it. | |||
3. The Updated OAuth 2.0 Attacker Model | 3. The Updated OAuth 2.0 Attacker Model | |||
In [RFC6819], a threat model is laid out that describes the threats | In [RFC6819], a threat model is laid out that describes the threats | |||
against which OAuth deployments must be protected. While doing so, | against which OAuth deployments must be protected. While doing so, | |||
[RFC6819] makes certain assumptions about attackers and their | [RFC6819] makes certain assumptions about attackers and their | |||
capabilities, i.e., implicitly establishes an attacker model. In the | capabilities, i.e., it implicitly establishes an attacker model. In | |||
following, this attacker model is made explicit and is updated and | the following, this attacker model is made explicit and is updated | |||
expanded to account for the potentially dynamic relationships | and expanded to account for the potentially dynamic relationships | |||
involving multiple parties (as described in Section 1), to include | involving multiple parties (as described in Section 1), to include | |||
new types of attackers and to define the attacker model more clearly. | new types of attackers, and to define the attacker model more | |||
clearly. | ||||
The goal of this document is to ensure that the authorization of a | The goal of this document is to ensure that the authorization of a | |||
resource owner (with a user agent) at an authorization server and the | resource owner (with a user agent) at an authorization server and the | |||
subsequent usage of the access token at a resource server is | subsequent usage of the access token at a resource server is | |||
protected, as well as practically possible, at least against the | protected, as well as practically possible, at least against the | |||
following attackers: | following attackers. | |||
* (A1) Web Attackers that can set up and operate an arbitrary number | (A1) Web attackers that can set up and operate an arbitrary number | |||
of network endpoints (besides the "honest" ones) including | of network endpoints (besides the "honest" ones) including | |||
browsers and servers. Web attackers may set up web sites that are | browsers and servers. Web attackers may set up websites that | |||
visited by the resource owner, operate their own user agents, and | are visited by the resource owner, operate their own user | |||
participate in the protocol. | agents, and participate in the protocol. | |||
Web attackers may, in particular, operate OAuth clients that are | In particular, web attackers may operate OAuth clients that are | |||
registered at the authorization server, and operate their own | registered at the authorization server, and they may operate | |||
authorization and resource servers that can be used (in parallel | their own authorization and resource servers that can be used | |||
to the "honest" ones) by the resource owner and other resource | (in parallel to the "honest" ones) by the resource owner and | |||
owners. | other resource owners. | |||
It must also be assumed that web attackers can lure the user to | It must also be assumed that web attackers can lure the user to | |||
navigate their browser to arbitrary attacker-chosen URIs at any | navigate their browser to arbitrary attacker-chosen URIs at any | |||
time. In practice, this can be achieved in many ways, for | time. In practice, this can be achieved in many ways, for | |||
example, by injecting malicious advertisements into advertisement | example, by injecting malicious advertisements into | |||
networks, or by sending legitimate-looking emails. | advertisement networks or by sending legitimate-looking emails. | |||
Web attackers can use their own user credentials to create new | Web attackers can use their own user credentials to create new | |||
messages as well as any secrets they learned previously. For | messages as well as any secrets they learned previously. For | |||
example, if a web attacker learns an authorization code of a user | example, if a web attacker learns an authorization code of a | |||
through a misconfigured redirect URI, the web attacker can then | user through a misconfigured redirection URI, the web attacker | |||
try to redeem that code for an access token. | can then try to redeem that code for an access token. | |||
They cannot, however, read or manipulate messages that are not | They cannot, however, read or manipulate messages that are not | |||
targeted towards them (e.g., sent to a URL controlled by a non- | targeted towards them (e.g., sent to a URL of an authorization | |||
attacker controlled authorization server). | server not under control of an attacker). | |||
* (A2) Network Attackers that additionally have full control over | (A2) Network attackers that additionally have full control over the | |||
the network over which protocol participants communicate. They | network over which protocol participants communicate. They can | |||
can eavesdrop on, manipulate, and spoof messages, except when | eavesdrop on, manipulate, and spoof messages, except when these | |||
these are properly protected by cryptographic methods (e.g., TLS). | are properly protected by cryptographic methods (e.g., TLS). | |||
Network attackers can also block arbitrary messages. | Network attackers can also block arbitrary messages. | |||
While an example for a web attacker would be a customer of an | While an example for a web attacker would be a customer of an | |||
internet service provider, network attackers could be the internet | internet service provider, network attackers could be the internet | |||
service provider itself, an attacker in a public (Wi-Fi) network | service provider itself, an attacker in a public (Wi-Fi) network | |||
using ARP spoofing, or a state-sponsored attacker with access to | using ARP spoofing, or a state-sponsored attacker with access to | |||
internet exchange points, for instance. | internet exchange points, for instance. | |||
The aforementioned attackers (A1) and (A2) conform to the attacker | The aforementioned attackers (A1) and (A2) conform to the attacker | |||
model that was used in formal analysis efforts for OAuth | model that was used in formal analysis efforts for OAuth | |||
[arXiv.1601.01229]. This is a minimal attacker model. Implementers | [arXiv.1601.01229]. This is a minimal attacker model. Implementers | |||
skipping to change at page 13, line 20 ¶ | skipping to change at line 574 ¶ | |||
[arXiv.1901.11520], a very strong attacker model is used that | [arXiv.1901.11520], a very strong attacker model is used that | |||
includes attackers that have full control over the token endpoint. | includes attackers that have full control over the token endpoint. | |||
This models effects of a possible misconfiguration of endpoints in | This models effects of a possible misconfiguration of endpoints in | |||
the ecosystem, which can be avoided by using authorization server | the ecosystem, which can be avoided by using authorization server | |||
metadata as described in Section 2.6. Such an attacker is therefore | metadata as described in Section 2.6. Such an attacker is therefore | |||
not listed here. | not listed here. | |||
However, previous attacks on OAuth have shown that the following | However, previous attacks on OAuth have shown that the following | |||
types of attackers are relevant in particular: | types of attackers are relevant in particular: | |||
* (A3) Attackers that can read, but not modify, the contents of the | (A3) Attackers that can read, but not modify, the contents of the | |||
authorization response (i.e., the authorization response can leak | authorization response (i.e., the authorization response can | |||
to an attacker). | leak to an attacker). | |||
Examples for such attacks include open redirector attacks, | Examples of such attacks include open redirector attacks and | |||
insufficient checking of redirect URIs (see Section 4.1), problems | mix-up attacks (see Section 4.4), where the client is tricked | |||
existing on mobile operating systems (where different apps can | into sending credentials to an attacker-controlled | |||
register themselves on the same URI), mix-up attacks (see | authorization server. | |||
Section 4.4), where the client is tricked into sending credentials | ||||
to an attacker-controlled authorization server, and the fact that | ||||
URLs are often stored/logged by browsers (history), proxy servers, | ||||
and operating systems. | ||||
* (A4) Attackers that can read, but not modify, the contents of the | Also, this includes attacks that take advantage of: | |||
authorization request (i.e., the authorization request can leak, | ||||
in the same manner as above, to an attacker). | ||||
* (A5) Attackers that can acquire an access token issued by an | * insufficient checking of redirect URIs (see Section 4.1); | |||
authorization server. For example, a resource server can be | * problems existing on mobile operating systems, where | |||
compromised by an attacker, an access token may be sent to an | different apps can register themselves on the same URI; and | |||
attacker-controlled resource server due to a misconfiguration, or | * URLs stored/logged by browsers (history), proxy servers, and | |||
a resource owner is social-engineered into using an attacker- | operating systems. | |||
controlled resource server. Also see Section 4.9.2. | ||||
(A3), (A4) and (A5) typically occur together with either (A1) or | (A4) Attackers that can read, but not modify, the contents of the | |||
authorization request (i.e., the authorization request can | ||||
leak, in the same manner as above, to an attacker). | ||||
(A5) Attackers that can acquire an access token issued by an | ||||
authorization server. For example, a resource server may be | ||||
compromised by an attacker, an access token may be sent to an | ||||
attacker-controlled resource server due to a misconfiguration, | ||||
or social engineering may be used to get a resource owner to | ||||
use an attacker-controlled resource server. Also see | ||||
Section 4.9.2. | ||||
(A3), (A4), and (A5) typically occur together with either (A1) or | ||||
(A2). Attackers can collaborate to reach a common goal. | (A2). Attackers can collaborate to reach a common goal. | |||
Note that an attacker (A1) or (A2) can be a resource owner or act as | Note that an Attacker (A1) or (A2) can be a resource owner or act as | |||
one. For example, such an attacker can use their own browser to | one. For example, such an attacker can use their own browser to | |||
replay tokens or authorization codes obtained by any of the attacks | replay tokens or authorization codes obtained by any of the attacks | |||
described above at the client or resource server. | described above at the client or resource server. | |||
This document focuses on threats resulting from attackers (A1) to | This document focuses on threats resulting from Attackers (A1) to | |||
(A5). | (A5). | |||
4. Attacks and Mitigations | 4. Attacks and Mitigations | |||
This section gives a detailed description of attacks on OAuth | This section gives a detailed description of attacks on OAuth | |||
implementations, along with potential countermeasures. Attacks and | implementations, along with potential countermeasures. Attacks and | |||
mitigations already covered in [RFC6819] are not listed here, except | mitigations already covered in [RFC6819] are not listed here, except | |||
where new recommendations are made. | where new recommendations are made. | |||
This section further defines additional requirements beyond those | This section further defines additional requirements (beyond those | |||
defined in Section 2 for certain cases and protocol options. | defined in Section 2) for certain cases and protocol options. | |||
4.1. Insufficient Redirect URI Validation | 4.1. Insufficient Redirection URI Validation | |||
Some authorization servers allow clients to register redirect URI | Some authorization servers allow clients to register redirection URI | |||
patterns instead of complete redirect URIs. The authorization | patterns instead of complete redirection URIs. The authorization | |||
servers then match the redirect URI parameter value at the | servers then match the redirection URI parameter value at the | |||
authorization endpoint against the registered patterns at runtime. | authorization endpoint against the registered patterns at runtime. | |||
This approach allows clients to encode transaction state into | This approach allows clients to encode transaction state into | |||
additional redirect URI parameters or to register a single pattern | additional redirect URI parameters or to register a single pattern | |||
for multiple redirect URIs. | for multiple redirection URIs. | |||
This approach turned out to be more complex to implement and more | This approach turned out to be more complex to implement and more | |||
error-prone to manage than exact redirect URI matching. Several | error-prone to manage than exact redirection URI matching. Several | |||
successful attacks exploiting flaws in the pattern-matching | successful attacks exploiting flaws in the pattern-matching | |||
implementation or concrete configurations have been observed in the | implementation or concrete configurations have been observed in the | |||
wild (see, e.g., [research.rub2]). Insufficient validation of the | wild (see, e.g., [research.rub2]). Insufficient validation of the | |||
redirect URI effectively breaks client identification or | redirection URI effectively breaks client identification or | |||
authentication (depending on grant and client type) and allows the | authentication (depending on grant and client type) and allows the | |||
attacker to obtain an authorization code or access token, either | attacker to obtain an authorization code or access token, either | |||
* by directly sending the user agent to a URI under the attacker's | * by directly sending the user agent to a URI under the attacker's | |||
control, or | control, or | |||
* by exposing the OAuth credentials to an attacker by utilizing an | * by exposing the OAuth credentials to an attacker by utilizing an | |||
open redirector at the client in conjunction with the way user | open redirector at the client in conjunction with the way user | |||
agents handle URL fragments. | agents handle URL fragments. | |||
These attacks are shown in detail in the following subsections. | These attacks are shown in detail in the following subsections. | |||
4.1.1. Redirect URI Validation Attacks on Authorization Code Grant | 4.1.1. Redirect URI Validation Attacks on Authorization Code Grant | |||
For a client using the grant type code, an attack may work as | For a client using the grant type code, an attack may work as | |||
follows: | follows: | |||
Assume the redirect URL pattern https://*.somesite.example/* is | Assume the redirection URL pattern https://*.somesite.example/* is | |||
registered for the client with the client ID s6BhdRkqt3. The | registered for the client with the client ID s6BhdRkqt3. The | |||
intention is to allow any subdomain of somesite.example to be a valid | intention is to allow any subdomain of somesite.example to be a valid | |||
redirect URI for the client, for example | redirection URI for the client, for example, | |||
https://app1.somesite.example/redirect. A naive implementation on | https://app1.somesite.example/redirect. However, a naive | |||
the authorization server, however, might interpret the wildcard * as | implementation on the authorization server might interpret the | |||
"any character" and not "any character valid for a domain name". The | wildcard * as "any character" and not "any character valid for a | |||
authorization server, therefore, might permit | domain name". The authorization server, therefore, might permit | |||
https://attacker.example/.somesite.example as a redirect URI, | https://attacker.example/.somesite.example as a redirection URI, | |||
although attacker.example is a different domain potentially | although attacker.example is a different domain potentially | |||
controlled by a malicious party. | controlled by a malicious party. | |||
The attack can then be conducted as follows: | The attack can then be conducted as follows: | |||
To begin, the attacker needs to trick the user into opening a | To begin, the attacker needs to trick the user into opening a | |||
tampered URL in their browser that launches a page under the | tampered URL in their browser that launches a page under the | |||
attacker's control, say https://www.evil.example (see Attacker A1 in | attacker's control, say, https://www.evil.example (see attacker A1 in | |||
Section 3). | Section 3). | |||
This URL initiates the following authorization request with the | This URL initiates the following authorization request with the | |||
client ID of a legitimate client to the authorization endpoint (line | client ID of a legitimate client to the authorization endpoint (line | |||
breaks for display only): | breaks for display only): | |||
GET /authorize?response_type=code&client_id=s6BhdRkqt3&state=9ad67f13 | GET /authorize?response_type=code&client_id=s6BhdRkqt3&state=9ad67f13 | |||
&redirect_uri=https%3A%2F%2Fattacker.example%2F.somesite.example | &redirect_uri=https%3A%2F%2Fattacker.example%2F.somesite.example | |||
HTTP/1.1 | HTTP/1.1 | |||
Host: server.somesite.example | Host: server.somesite.example | |||
The authorization server validates the redirect URI and compares it | The authorization server validates the redirection URI and compares | |||
to the registered redirect URL patterns for the client s6BhdRkqt3. | it to the registered redirection URL patterns for the client | |||
The authorization request is processed and presented to the user. | s6BhdRkqt3. The authorization request is processed and presented to | |||
the user. | ||||
If the user does not see the redirect URI or does not recognize the | If the user does not see the redirection URI or does not recognize | |||
attack, the code is issued and immediately sent to the attacker's | the attack, the code is issued and immediately sent to the attacker's | |||
domain. If an automatic approval of the authorization is enabled | domain. If an automatic approval of the authorization is enabled | |||
(which is not recommended for public clients according to [RFC6749]), | (which is not recommended for public clients according to [RFC6749]), | |||
the attack can be performed even without user interaction. | the attack can be performed even without user interaction. | |||
If the attacker impersonates a public client, the attacker can | If the attacker impersonates a public client, the attacker can | |||
exchange the code for tokens at the respective token endpoint. | exchange the code for tokens at the respective token endpoint. | |||
This attack will not work as easily for confidential clients, since | This attack will not work as easily for confidential clients, since | |||
the code exchange requires authentication with the legitimate | the code exchange requires authentication with the legitimate | |||
client's secret. The attacker can, however, use the legitimate | client's secret. However, the attacker can use the legitimate | |||
confidential client to redeem the code by performing an authorization | confidential client to redeem the code by performing an authorization | |||
code injection attack, see Section 4.5. | code injection attack; see Section 4.5. | |||
It is important to note that redirect URI validation vulnerabilities | It is important to note that redirection URI validation | |||
can also exist if the authorization server handles wildcards | vulnerabilities can also exist if the authorization server handles | |||
properly. For example, assume that the client registers the redirect | wildcards properly. For example, assume that the client registers | |||
URL pattern https://*.somesite.example/* and the authorization server | the redirection URL pattern https://*.somesite.example/* and the | |||
interprets this as "allow redirect URIs pointing to any host residing | authorization server interprets this as "allow redirection URIs | |||
in the domain somesite.example". If an attacker manages to establish | pointing to any host residing in the domain somesite.example". If an | |||
a host or subdomain in somesite.example, the attacker can impersonate | attacker manages to establish a host or subdomain in | |||
the legitimate client. This could be caused, for example, by a | somesite.example, the attacker can impersonate the legitimate client. | |||
subdomain takeover attack [research.udel], where an outdated CNAME | For example, this could be caused by a subdomain takeover attack | |||
record (say, external-service.somesite.example) points to an external | [research.udel], where an outdated CNAME record (say, external- | |||
DNS name that does no longer exist (say, customer- | service.somesite.example) points to an external DNS name that no | |||
abc.service.example) and can be taken over by an attacker (e.g., by | longer exists (say, customer-abc.service.example) and can be taken | |||
registering as customer-abc with the external service). | over by an attacker (e.g., by registering as customer-abc with the | |||
external service). | ||||
4.1.2. Redirect URI Validation Attacks on Implicit Grant | 4.1.2. Redirect URI Validation Attacks on Implicit Grant | |||
The attack described above works for the implicit grant as well. If | The attack described above works for the implicit grant as well. If | |||
the attacker is able to send the authorization response to an | the attacker is able to send the authorization response to an | |||
attacker-controlled URI, the attacker will directly get access to the | attacker-controlled URI, the attacker will directly get access to the | |||
fragment carrying the access token. | fragment carrying the access token. | |||
Additionally, implicit grants (and also other grants when using | Additionally, implicit grants (and also other grants when using | |||
response_mode=fragment as defined in [OAuth.Responses]) can be | response_mode=fragment as defined in [OAuth.Responses]) can be | |||
subject to a further kind of attack. It utilizes the fact that user | subject to a further kind of attack. The attack utilizes the fact | |||
agents re-attach fragments to the destination URL of a redirect if | that user agents reattach fragments to the destination URL of a | |||
the location header does not contain a fragment (see [RFC9110], | redirect if the location header does not contain a fragment (see | |||
Section 17.11). The attack described here combines this behavior | Section 17.11 of [RFC9110]). The attack described here combines this | |||
with the client as an open redirector (see Section 4.11.1) in order | behavior with the client as an open redirector (see Section 4.11.1) | |||
to obtain access tokens. This allows circumvention even of very | in order to obtain access tokens. This allows circumvention even of | |||
narrow redirect URI patterns, but not strict URL matching. | very narrow redirection URI patterns, but not of strict URL matching. | |||
Assume the registered URL pattern for client s6BhdRkqt3 is | Assume the registered URL pattern for client s6BhdRkqt3 is | |||
https://client.somesite.example/cb?*, i.e., any parameter is allowed | https://client.somesite.example/cb?*, i.e., any parameter is allowed | |||
for redirects to https://client.somesite.example/cb. Unfortunately, | for redirects to https://client.somesite.example/cb. Unfortunately, | |||
the client exposes an open redirector. This endpoint supports a | the client exposes an open redirector. This endpoint supports a | |||
parameter redirect_to which takes a target URL and will send the | parameter redirect_to which takes a target URL and will send the | |||
browser to this URL using an HTTP Location header redirect 303. | browser to this URL using an HTTP Location header redirect 303. | |||
The attack can now be conducted as follows: | The attack can now be conducted as follows: | |||
To begin, as above, the attacker needs to trick the user into opening | To begin, as above, the attacker needs to trick the user into opening | |||
a tampered URL in their browser that launches a page under the | a tampered URL in their browser that launches a page under the | |||
attacker's control, say https://www.evil.example. | attacker's control, say, https://www.evil.example. | |||
Afterwards, the website initiates an authorization request that is | Afterwards, the website initiates an authorization request that is | |||
very similar to the one in the attack on the code flow. Different to | very similar to the one in the attack on the code flow. Different to | |||
above, it utilizes the open redirector by encoding | above, it utilizes the open redirector by encoding | |||
redirect_to=https://attacker.example into the parameters of the | redirect_to=https://attacker.example into the parameters of the | |||
redirect URI and it uses the response type "token" (line breaks for | redirection URI, and it uses the response type token (line breaks for | |||
display only): | display only): | |||
GET /authorize?response_type=token&state=9ad67f13 | GET /authorize?response_type=token&state=9ad67f13 | |||
&client_id=s6BhdRkqt3 | &client_id=s6BhdRkqt3 | |||
&redirect_uri=https%3A%2F%2Fclient.somesite.example | &redirect_uri=https%3A%2F%2Fclient.somesite.example | |||
%2Fcb%26redirect_to%253Dhttps%253A%252F | %2Fcb%26redirect_to%253Dhttps%253A%252F | |||
%252Fattacker.example%252F HTTP/1.1 | %252Fattacker.example%252F HTTP/1.1 | |||
Host: server.somesite.example | Host: server.somesite.example | |||
Now, since the redirect URI matches the registered pattern, the | Then, since the redirection URI matches the registered pattern, the | |||
authorization server permits the request and sends the resulting | authorization server permits the request and sends the resulting | |||
access token in a 303 redirect (some response parameters omitted for | access token in a 303 redirect (some response parameters omitted for | |||
readability): | readability): | |||
HTTP/1.1 303 See Other | HTTP/1.1 303 See Other | |||
Location: https://client.somesite.example/cb? | Location: https://client.somesite.example/cb? | |||
redirect_to%3Dhttps%3A%2F%2Fattacker.example%2Fcb | redirect_to%3Dhttps%3A%2F%2Fattacker.example%2Fcb | |||
#access_token=2YotnFZFEjr1zCsicMWpAA&... | #access_token=2YotnFZFEjr1zCsicMWpAA&... | |||
At client.somesite.example, the request arrives at the open | At client.somesite.example, the request arrives at the open | |||
redirector. The endpoint will read the redirect parameter and will | redirector. The endpoint will read the redirect parameter and will | |||
issue an HTTP 303 Location header redirect to the URL | issue an HTTP 303 Location header redirect to the URL | |||
https://attacker.example/. | https://attacker.example/. | |||
HTTP/1.1 303 See Other | HTTP/1.1 303 See Other | |||
Location: https://attacker.example/ | Location: https://attacker.example/ | |||
Since the redirector at client.somesite.example does not include a | Since the redirector at client.somesite.example does not include a | |||
fragment in the Location header, the user agent will re-attach the | fragment in the Location header, the user agent will reattach the | |||
original fragment #access_token=2YotnFZFEjr1zCsicMWpAA&... to the | original fragment #access_token=2YotnFZFEjr1zCsicMWpAA&... to the | |||
URL and will navigate to the following URL: | URL and will navigate to the following URL: | |||
https://attacker.example/#access_token=2YotnFZFEjr1z... | https://attacker.example/#access_token=2YotnFZFEjr1z... | |||
The attacker's page at attacker.example can now access the fragment | The attacker's page at attacker.example can then access the fragment | |||
and obtain the access token. | and obtain the access token. | |||
4.1.3. Countermeasures | 4.1.3. Countermeasures | |||
The complexity of implementing and managing pattern matching | The complexity of implementing and managing pattern matching | |||
correctly obviously causes security issues. This document therefore | correctly obviously causes security issues. This document therefore | |||
advises simplifying the required logic and configuration by using | advises simplifying the required logic and configuration by using | |||
exact redirect URI matching. This means the authorization server | exact redirection URI matching. This means the authorization server | |||
MUST ensure that the two URIs are equal, see [RFC3986], | MUST ensure that the two URIs are equal; see Section 6.2.1 of | |||
Section 6.2.1, Simple String Comparison, for details. The only | [RFC3986], Simple String Comparison, for details. The only exception | |||
exception is native apps using a localhost URI: In this case, the | is native apps using a localhost URI: In this case, the authorization | |||
authorization server MUST allow variable port numbers as described in | server MUST allow variable port numbers as described in Section 7.3 | |||
[RFC8252], Section 7.3. | of [RFC8252]. | |||
Additional recommendations: | Additional recommendations: | |||
* Web servers on which redirect URIs are hosted MUST NOT expose open | * Web servers on which redirection URIs are hosted MUST NOT expose | |||
redirectors (see Section 4.11). | open redirectors (see Section 4.11). | |||
* Browsers reattach URL fragments to Location redirection URLs only | * Browsers reattach URL fragments to Location redirection URLs only | |||
if the URL in the Location header does not already contain a | if the URL in the Location header does not already contain a | |||
fragment. Therefore, servers MAY prevent browsers from | fragment. Therefore, servers MAY prevent browsers from | |||
reattaching fragments to redirection URLs by attaching an | reattaching fragments to redirection URLs by attaching an | |||
arbitrary fragment identifier, for example #_, to URLs in Location | arbitrary fragment identifier, for example #_, to URLs in Location | |||
headers. | headers. | |||
* Clients SHOULD use the authorization code response type instead of | * Clients SHOULD use the authorization code response type instead of | |||
response types causing access token issuance at the authorization | response types that cause access token issuance at the | |||
endpoint. This offers countermeasures against the reuse of leaked | authorization endpoint. This offers countermeasures against the | |||
credentials through the exchange process with the authorization | reuse of leaked credentials through the exchange process with the | |||
server and token replay through sender-constraining of the access | authorization server and against token replay through sender- | |||
tokens. | constraining of the access tokens. | |||
If the origin and integrity of the authorization request containing | If the origin and integrity of the authorization request containing | |||
the redirect URI can be verified, for example when using [RFC9101] or | the redirection URI can be verified, for example, when using | |||
[RFC9126] with client authentication, the authorization server MAY | [RFC9101] or [RFC9126] with client authentication, the authorization | |||
trust the redirect URI without further checks. | server MAY trust the redirection URI without further checks. | |||
4.2. Credential Leakage via Referer Headers | 4.2. Credential Leakage via Referer Headers | |||
The contents of the authorization request URI or the authorization | The contents of the authorization request URI or the authorization | |||
response URI can unintentionally be disclosed to attackers through | response URI can unintentionally be disclosed to attackers through | |||
the Referer HTTP header (see [RFC9110], Section 10.1.3), by leaking | the Referer HTTP header (see Section 10.1.3 of [RFC9110]), by leaking | |||
either from the authorization server's or the client's website, | from either the authorization server's or the client's website, | |||
respectively. Most importantly, authorization codes or state values | respectively. Most importantly, authorization codes or state values | |||
can be disclosed in this way. Although specified otherwise in | can be disclosed in this way. Although specified otherwise in | |||
[RFC9110], Section 10.1.3, the same may happen to access tokens | Section 10.1.3 of [RFC9110], the same may happen to access tokens | |||
conveyed in URI fragments due to browser implementation issues, as | conveyed in URI fragments due to browser implementation issues, as | |||
illustrated by a (now fixed) issue in the Chromium project | illustrated by a (now fixed) issue in the Chromium project | |||
[bug.chromium]. | [bug.chromium]. | |||
4.2.1. Leakage from the OAuth Client | 4.2.1. Leakage from the OAuth Client | |||
Leakage from the OAuth client requires that the client, as a result | Leakage from the OAuth client requires that the client, as a result | |||
of a successful authorization request, renders a page that | of a successful authorization request, renders a page that | |||
* contains links to other pages under the attacker's control and a | * contains links to other pages under the attacker's control and a | |||
skipping to change at page 19, line 14 ¶ | skipping to change at line 862 ¶ | |||
4.2.2. Leakage from the Authorization Server | 4.2.2. Leakage from the Authorization Server | |||
In a similar way, an attacker can learn state from the authorization | In a similar way, an attacker can learn state from the authorization | |||
request if the authorization endpoint at the authorization server | request if the authorization endpoint at the authorization server | |||
contains links or third-party content as above. | contains links or third-party content as above. | |||
4.2.3. Consequences | 4.2.3. Consequences | |||
An attacker that learns a valid code or access token through a | An attacker that learns a valid code or access token through a | |||
Referer header can perform the attacks as described in Section 4.1.1, | Referer header can perform the attacks as described in Sections | |||
Section 4.5, and Section 4.6. If the attacker learns state, the CSRF | 4.1.1, 4.5 and 4.6. If the attacker learns state, the CSRF | |||
protection achieved by using state is lost, resulting in CSRF attacks | protection achieved by using state is lost, resulting in CSRF attacks | |||
as described in [RFC6819], Section 4.4.1.8. | as described in Section 4.4.1.8 of [RFC6819]. | |||
4.2.4. Countermeasures | 4.2.4. Countermeasures | |||
The page rendered as a result of the OAuth authorization response and | The page rendered as a result of the OAuth authorization response and | |||
the authorization endpoint SHOULD NOT include third-party resources | the authorization endpoint SHOULD NOT include third-party resources | |||
or links to external sites. | or links to external sites. | |||
The following measures further reduce the chances of a successful | The following measures further reduce the chances of a successful | |||
attack: | attack: | |||
skipping to change at page 19, line 42 ¶ | skipping to change at line 890 ¶ | |||
referrer in the response completely suppresses the Referer header | referrer in the response completely suppresses the Referer header | |||
in all requests originating from the resulting document. | in all requests originating from the resulting document. | |||
* Use authorization code instead of response types causing access | * Use authorization code instead of response types causing access | |||
token issuance from the authorization endpoint. | token issuance from the authorization endpoint. | |||
* Bind the authorization code to a confidential client or PKCE | * Bind the authorization code to a confidential client or PKCE | |||
challenge. In this case, the attacker lacks the secret to request | challenge. In this case, the attacker lacks the secret to request | |||
the code exchange. | the code exchange. | |||
* As described in [RFC6749], Section 4.1.2, authorization codes MUST | * As described in Section 4.1.2 of [RFC6749], authorization codes | |||
be invalidated by the authorization server after their first use | MUST be invalidated by the authorization server after their first | |||
at the token endpoint. For example, if an authorization server | use at the token endpoint. For example, if an authorization | |||
invalidated the code after the legitimate client redeemed it, the | server invalidated the code after the legitimate client redeemed | |||
attacker would fail to exchange this code later. | it, the attacker would fail to exchange this code later. | |||
This does not mitigate the attack if the attacker manages to | This does not mitigate the attack if the attacker manages to | |||
exchange the code for a token before the legitimate client does | exchange the code for a token before the legitimate client does | |||
so. Therefore, [RFC6749] further recommends that, when an attempt | so. Therefore, [RFC6749] further recommends that, when an attempt | |||
is made to redeem a code twice, the authorization server SHOULD | is made to redeem a code twice, the authorization server SHOULD | |||
revoke all tokens issued previously based on that code. | revoke all tokens issued previously based on that code. | |||
* The state value SHOULD be invalidated by the client after its | * The state value SHOULD be invalidated by the client after its | |||
first use at the redirection endpoint. If this is implemented, | first use at the redirection endpoint. If this is implemented, | |||
and an attacker receives a token through the Referer header from | and an attacker receives a token through the Referer header from | |||
skipping to change at page 20, line 33 ¶ | skipping to change at line 930 ¶ | |||
4.3.1. Authorization Code in Browser History | 4.3.1. Authorization Code in Browser History | |||
When a browser navigates to client.example/ | When a browser navigates to client.example/ | |||
redirection_endpoint?code=abcd as a result of a redirect from a | redirection_endpoint?code=abcd as a result of a redirect from a | |||
provider's authorization endpoint, the URL including the | provider's authorization endpoint, the URL including the | |||
authorization code may end up in the browser's history. An attacker | authorization code may end up in the browser's history. An attacker | |||
with access to the device could obtain the code and try to replay it. | with access to the device could obtain the code and try to replay it. | |||
Countermeasures: | Countermeasures: | |||
* Authorization code replay prevention as described in [RFC6819], | * Authorization code replay prevention as described in | |||
Section 4.4.1.1, and Section 4.5. | Section 4.4.1.1 of [RFC6819], and Section 4.5. | |||
* Use form post response mode instead of redirect for the | * Use the form post response mode instead of redirect for the | |||
authorization response (see [OAuth.Post]). | authorization response (see [OAuth.Post]). | |||
4.3.2. Access Token in Browser History | 4.3.2. Access Token in Browser History | |||
An access token may end up in the browser history if a client or a | An access token may end up in the browser history if a client or a | |||
web site that already has a token deliberately navigates to a page | website that already has a token deliberately navigates to a page | |||
like provider.com/get_user_profile?access_token=abcdef. [RFC6750] | like provider.com/get_user_profile?access_token=abcdef. [RFC6750] | |||
discourages this practice and advises transferring tokens via a | discourages this practice and advises transferring tokens via a | |||
header, but in practice web sites often pass access tokens in query | header, but in practice websites often pass access tokens in query | |||
parameters. | parameters. | |||
In the case of implicit grant, a URL like client.example/ | In the case of implicit grant, a URL like client.example/ | |||
redirection_endpoint#access_token=abcdef may also end up in the | redirection_endpoint#access_token=abcdef may also end up in the | |||
browser history as a result of a redirect from a provider's | browser history as a result of a redirect from a provider's | |||
authorization endpoint. | authorization endpoint. | |||
Countermeasures: | Countermeasures: | |||
* Clients MUST NOT pass access tokens in a URI query parameter in | * Clients MUST NOT pass access tokens in a URI query parameter in | |||
the way described in Section 2.3 of [RFC6750]. The authorization | the way described in Section 2.3 of [RFC6750]. The authorization | |||
code grant or alternative OAuth response modes like the form post | code grant or alternative OAuth response modes like the form post | |||
response mode [OAuth.Post] can be used to this end. | response mode [OAuth.Post] can be used to this end. | |||
4.4. Mix-Up Attacks | 4.4. Mix-Up Attacks | |||
Mix-up is an attack on scenarios where an OAuth client interacts with | Mix-up attacks can occur in scenarios where an OAuth client interacts | |||
two or more authorization servers and at least one authorization | with two or more authorization servers and at least one authorization | |||
server is under the control of the attacker. This can be the case, | server is under the control of the attacker. This can be the case, | |||
for example, if the attacker uses dynamic registration to register | for example, if the attacker uses dynamic registration to register | |||
the client at their own authorization server or if an authorization | the client at their own authorization server or if an authorization | |||
server becomes compromised. | server becomes compromised. | |||
The goal of the attack is to obtain an authorization code or an | The goal of the attack is to obtain an authorization code or an | |||
access token for an uncompromised authorization server. This is | access token for an uncompromised authorization server. This is | |||
achieved by tricking the client into sending those credentials to the | achieved by tricking the client into sending those credentials to the | |||
compromised authorization server (the attacker) instead of using them | compromised authorization server (the attacker) instead of using them | |||
at the respective endpoint of the uncompromised authorization/ | at the respective endpoint of the uncompromised authorization/ | |||
skipping to change at page 21, line 45 ¶ | skipping to change at line 991 ¶ | |||
authorization servers of which one is considered "honest" (H-AS) | authorization servers of which one is considered "honest" (H-AS) | |||
and one is operated by the attacker (A-AS), and | and one is operated by the attacker (A-AS), and | |||
* the client stores the authorization server chosen by the user in a | * the client stores the authorization server chosen by the user in a | |||
session bound to the user's browser and uses the same redirection | session bound to the user's browser and uses the same redirection | |||
endpoint URI for each authorization server. | endpoint URI for each authorization server. | |||
In the following, it is further assumed that the client is registered | In the following, it is further assumed that the client is registered | |||
with H-AS (URI: https://honest.as.example, client ID: 7ZGZldHQ) and | with H-AS (URI: https://honest.as.example, client ID: 7ZGZldHQ) and | |||
with A-AS (URI: https://attacker.example, client ID: 666RVZJTA). | with A-AS (URI: https://attacker.example, client ID: 666RVZJTA). | |||
URLs shown in the following example are shortened for presentation to | URLs shown in the following example are shortened for presentation to | |||
only include parameters relevant to the attack. | include only parameters relevant to the attack. | |||
Attack on the authorization code grant: | Attack on the authorization code grant: | |||
1. The user selects to start the grant using A-AS (e.g., by clicking | 1. The user selects to start the grant using A-AS (e.g., by clicking | |||
on a button on the client's website). | on a button on the client's website). | |||
2. The client stores in the user's session that the user selected | 2. The client stores in the user's session that the user selected | |||
"A-AS" and redirects the user to A-AS's authorization endpoint | "A-AS" and redirects the user to A-AS's authorization endpoint | |||
with a Location header containing the URL | with a Location header containing the URL | |||
https://attacker.example/ | https://attacker.example/ | |||
skipping to change at page 22, line 23 ¶ | skipping to change at line 1016 ¶ | |||
authorization endpoint of H-AS. In the authorization request, | authorization endpoint of H-AS. In the authorization request, | |||
the attacker replaces the client ID of the client at A-AS with | the attacker replaces the client ID of the client at A-AS with | |||
the client's ID at H-AS. Therefore, the browser receives a | the client's ID at H-AS. Therefore, the browser receives a | |||
redirection (303 See Other) with a Location header pointing to | redirection (303 See Other) with a Location header pointing to | |||
https://honest.as.example/ | https://honest.as.example/ | |||
authorize?response_type=code&client_id=7ZGZldHQ | authorize?response_type=code&client_id=7ZGZldHQ | |||
4. The user authorizes the client to access their resources at H-AS. | 4. The user authorizes the client to access their resources at H-AS. | |||
(Note that a vigilant user might at this point detect that they | (Note that a vigilant user might at this point detect that they | |||
intended to use A-AS instead of H-AS. The first attack variant | intended to use A-AS instead of H-AS. The first attack variant | |||
listed below avoids this.) H-AS issues a code and sends it (via | listed does not have this limitation.) H-AS issues a code and | |||
the browser) back to the client. | sends it (via the browser) back to the client. | |||
5. Since the client still assumes that the code was issued by A-AS, | 5. Since the client still assumes that the code was issued by A-AS, | |||
it will try to redeem the code at A-AS's token endpoint. | it will try to redeem the code at A-AS's token endpoint. | |||
6. The attacker therefore obtains code and can either exchange the | 6. The attacker therefore obtains code and can either exchange the | |||
code for an access token (for public clients) or perform an | code for an access token (for public clients) or perform an | |||
authorization code injection attack as described in Section 4.5. | authorization code injection attack as described in Section 4.5. | |||
Variants: | Variants: | |||
* Mix-Up With Interception: This variant works only if the attacker | * Mix-Up with Interception: This variant works only if the attacker | |||
can intercept and manipulate the first request/response pair from | can intercept and manipulate the first request/response pair from | |||
a user's browser to the client (in which the user selects a | a user's browser to the client (in which the user selects a | |||
certain authorization server and is then redirected by the client | certain authorization server and is then redirected by the client | |||
to that authorization server), as in Attacker A2 (see Section 3). | to that authorization server), as in Attacker (A2) (see | |||
This capability can, for example, be the result of a attacker-in- | Section 3). This capability can, for example, be the result of a | |||
the-middle attack on the user's connection to the client. In the | attacker-in-the-middle attack on the user's connection to the | |||
attack, the user starts the flow with H-AS. The attacker | client. In the attack, the user starts the flow with H-AS. The | |||
intercepts this request and changes the user's selection to A-AS. | attacker intercepts this request and changes the user's selection | |||
The rest of the attack proceeds as in Steps 2 and following above. | to A-AS. The rest of the attack proceeds as in Step 2 and | |||
following above. | ||||
* Implicit Grant: In the implicit grant, the attacker receives an | * Implicit Grant: In the implicit grant, the attacker receives an | |||
access token instead of the code in Step 4. The attacker's | access token instead of the code in Step 4. The attacker's | |||
authorization server receives the access token when the client | authorization server receives the access token when the client | |||
makes a request to the A-AS userinfo endpoint, or since the client | makes either a request to the A-AS userinfo endpoint or a request | |||
believes it has completed the flow with A-AS, a request to the | to the attacker's resource server (since the client believes it | |||
attacker's resource server. | has completed the flow with A-AS). | |||
* Per-AS Redirect URIs: If clients use different redirection URIs | ||||
* Per-AS Redirect URIs: If clients use different redirect URIs for | for different authorization servers, clients do not store the | |||
different authorization servers, do not store the selected | selected authorization server in the user's session, and | |||
authorization server in the user's session, and authorization | authorization servers do not check the redirection URIs properly, | |||
servers do not check the redirect URIs properly, attackers can | attackers can mount an attack called "Cross-Social Network Request | |||
mount an attack called "Cross-Social Network Request Forgery". | Forgery". These attacks have been observed in practice. Refer to | |||
These attacks have been observed in practice. Refer to | ||||
[research.jcs_14] for details. | [research.jcs_14] for details. | |||
* OpenID Connect: Some variants can be used to attack OpenID | * OpenID Connect: Some variants can be used to attack OpenID | |||
Connect. In these attacks, the attacker misuses features of the | Connect. In these attacks, the attacker misuses features of the | |||
OpenID Connect Discovery [OpenID.Discovery] mechanism or replays | OpenID Connect Discovery [OpenID.Discovery] mechanism or replays | |||
access tokens or ID Tokens to conduct a mix-up attack. The | access tokens or ID Tokens to conduct a mix-up attack. The | |||
attacks are described in detail in [arXiv.1704.08539], Appendix A, | attacks are described in detail in Appendix A of | |||
and [arXiv.1508.04324v2], Section 6 ("Malicious Endpoints | [arXiv.1704.08539] and Section 6 of [arXiv.1508.04324v2] | |||
Attacks"). | ("Malicious Endpoints Attacks"). | |||
4.4.2. Countermeasures | 4.4.2. Countermeasures | |||
When an OAuth client can only interact with one authorization server, | When an OAuth client can only interact with one authorization server, | |||
a mix-up defense is not required. In scenarios where an OAuth client | a mix-up defense is not required. In scenarios where an OAuth client | |||
interacts with two or more authorization servers, however, clients | interacts with two or more authorization servers, however, clients | |||
MUST prevent mix-up attacks. Two different methods are discussed in | MUST prevent mix-up attacks. Two different methods are discussed | |||
the following. | below. | |||
For both defenses, clients MUST store, for each authorization | For both defenses, clients MUST store, for each authorization | |||
request, the issuer they sent the authorization request to and bind | request, the issuer they sent the authorization request to and bind | |||
this information to the user agent. The issuer serves, via the | this information to the user agent. The issuer serves, via the | |||
associated metadata, as an abstract identifier for the combination of | associated metadata, as an abstract identifier for the combination of | |||
the authorization endpoint and token endpoint that are to be used in | the authorization endpoint and token endpoint that are to be used in | |||
the flow. If an issuer identifier is not available, for example, if | the flow. If an issuer identifier is not available (for example, if | |||
neither OAuth Authorization Server Metadata [RFC8414] nor OpenID | neither OAuth Authorization Server Metadata [RFC8414] nor OpenID | |||
Connect Discovery [OpenID.Discovery] is used, a different unique | Connect Discovery [OpenID.Discovery] is used), a different unique | |||
identifier for this tuple or the tuple itself can be used instead. | identifier for this tuple or the tuple itself can be used instead. | |||
For brevity of presentation, such a deployment-specific identifier | For brevity of presentation, such a deployment-specific identifier | |||
will be subsumed under the issuer (or issuer identifier) in the | will be subsumed under the issuer (or issuer identifier) in the | |||
following. | following. | |||
It is important to note that just storing the authorization server | It is important to note that just storing the authorization server | |||
URL is not sufficient to identify mix-up attacks. An attacker might | URL is not sufficient to identify mix-up attacks. An attacker might | |||
declare an uncompromised authorization server's authorization | declare an uncompromised authorization server's authorization | |||
endpoint URL as "their" authorization server URL, but declare a token | endpoint URL as "their" authorization server URL, but declare a token | |||
endpoint under their own control. | endpoint under their own control. | |||
skipping to change at page 24, line 31 ¶ | skipping to change at line 1113 ¶ | |||
In both cases, the iss value MUST be evaluated according to | In both cases, the iss value MUST be evaluated according to | |||
[RFC9207]. | [RFC9207]. | |||
While this defense may require deploying new OAuth features to | While this defense may require deploying new OAuth features to | |||
transport the issuer information, it is a robust and relatively | transport the issuer information, it is a robust and relatively | |||
simple defense against mix-up. | simple defense against mix-up. | |||
4.4.2.2. Mix-Up Defense via Distinct Redirect URIs | 4.4.2.2. Mix-Up Defense via Distinct Redirect URIs | |||
For this defense, clients MUST use a distinct redirect URI for each | For this defense, clients MUST use a distinct redirection URI for | |||
issuer they interact with. | each issuer they interact with. | |||
Clients MUST check that the authorization response was received from | Clients MUST check that the authorization response was received from | |||
the correct issuer by comparing the distinct redirect URI for the | the correct issuer by comparing the distinct redirection URI for the | |||
issuer to the URI where the authorization response was received on. | issuer to the URI where the authorization response was received on. | |||
If there is a mismatch, the client MUST abort the flow. | If there is a mismatch, the client MUST abort the flow. | |||
While this defense builds upon existing OAuth functionality, it | While this defense builds upon existing OAuth functionality, it | |||
cannot be used in scenarios where clients only register once for the | cannot be used in scenarios where clients only register once for the | |||
use of many different issuers (as in some open banking schemes) and | use of many different issuers (as in some open banking schemes) and | |||
due to the tight integration with the client registration, it is | due to the tight integration with the client registration, it is | |||
harder to deploy automatically. | harder to deploy automatically. | |||
Furthermore, an attacker might be able to circumvent the protection | Furthermore, an attacker might be able to circumvent the protection | |||
skipping to change at page 25, line 11 ¶ | skipping to change at line 1140 ¶ | |||
to the attacker's authorization server. The attacker could then run | to the attacker's authorization server. The attacker could then run | |||
the attack as described above, replacing the client ID with the | the attack as described above, replacing the client ID with the | |||
client ID of their newly created client. | client ID of their newly created client. | |||
This defense SHOULD therefore only be used if other options are not | This defense SHOULD therefore only be used if other options are not | |||
available. | available. | |||
4.5. Authorization Code Injection | 4.5. Authorization Code Injection | |||
An attacker who has gained access to an authorization code contained | An attacker who has gained access to an authorization code contained | |||
in an authorization response (see Attacker A3 in Section 3) can try | in an authorization response (see Attacker (A3) in Section 3) can try | |||
to redeem the authorization code for an access token or otherwise | to redeem the authorization code for an access token or otherwise | |||
make use of the authorization code. | make use of the authorization code. | |||
In the case that the authorization code was created for a public | In the case that the authorization code was created for a public | |||
client, the attacker can send the authorization code to the token | client, the attacker can send the authorization code to the token | |||
endpoint of the authorization server and thereby get an access token. | endpoint of the authorization server and thereby get an access token. | |||
This attack was described in Section 4.4.1.1 of [RFC6819]. | This attack was described in Section 4.4.1.1 of [RFC6819]. | |||
For confidential clients, or in some special situations, the attacker | For confidential clients, or in some special situations, the attacker | |||
can execute an authorization code injection attack, as described in | can execute an authorization code injection attack, as described in | |||
skipping to change at page 25, line 48 ¶ | skipping to change at line 1177 ¶ | |||
Except in these special cases, authorization code injection is | Except in these special cases, authorization code injection is | |||
usually not interesting when the code is created for a public client, | usually not interesting when the code is created for a public client, | |||
as sending the code to the token endpoint is a simpler and more | as sending the code to the token endpoint is a simpler and more | |||
powerful attack, as described above. | powerful attack, as described above. | |||
4.5.1. Attack Description | 4.5.1. Attack Description | |||
The authorization code injection attack works as follows: | The authorization code injection attack works as follows: | |||
1. The attacker obtains an authorization code (see attacker A3 in | 1. The attacker obtains an authorization code (see Attacker (A3) in | |||
Section 3). For the rest of the attack, only the capabilities of | Section 3). For the rest of the attack, only the capabilities of | |||
a web attacker (A1) are required. | a web attacker (A1) are required. | |||
2. From the attacker's device, the attacker starts a regular OAuth | 2. From the attacker's device, the attacker starts a regular OAuth | |||
authorization process with the legitimate client. | authorization process with the legitimate client. | |||
3. In the response of the authorization server to the legitimate | 3. In the response of the authorization server to the legitimate | |||
client, the attacker replaces the newly created authorization | client, the attacker replaces the newly created authorization | |||
code with the stolen authorization code. Since this response is | code with the stolen authorization code. Since this response is | |||
passing through the attacker's device, the attacker can use any | passing through the attacker's device, the attacker can use any | |||
tool that can intercept and manipulate the authorization response | tool that can intercept and manipulate the authorization response | |||
to this end. The attacker does not need to control the network. | to this end. The attacker does not need to control the network. | |||
4. The legitimate client sends the code to the authorization | 4. The legitimate client sends the code to the authorization | |||
server's token endpoint, along with the redirect_uri and the | server's token endpoint, along with the redirect_uri and the | |||
client's client ID and client secret (or other means of client | client's client ID and client secret (or other means of client | |||
authentication). | authentication). | |||
5. The authorization server checks the client secret, whether the | 5. The authorization server checks the client secret, whether the | |||
code was issued to the particular client, and whether the actual | code was issued to the particular client, and whether the actual | |||
redirect URI matches the redirect_uri parameter (see [RFC6749]). | redirection URI matches the redirect_uri parameter (see | |||
[RFC6749]). | ||||
6. All checks succeed and the authorization server issues access and | 6. All checks succeed and the authorization server issues access and | |||
other tokens to the client. The attacker has now associated | other tokens to the client. The attacker has now associated | |||
their session with the legitimate client with the victim's | their session with the legitimate client with the victim's | |||
resources and/or identity. | resources and/or identity. | |||
4.5.2. Discussion | 4.5.2. Discussion | |||
Obviously, the check-in step (5.) will fail if the code was issued to | Obviously, the check-in step (Step 5) will fail if the code was | |||
another client ID, e.g., a client set up by the attacker. The check | issued to another client ID, e.g., a client set up by the attacker. | |||
will also fail if the authorization code was already redeemed by the | The check will also fail if the authorization code was already | |||
legitimate user and was one-time use only. | redeemed by the legitimate user and was one-time use only. | |||
An attempt to inject a code obtained via a manipulated redirect URI | An attempt to inject a code obtained via a manipulated redirection | |||
should also be detected if the authorization server stored the | URI should also be detected if the authorization server stored the | |||
complete redirect URI used in the authorization request and compares | complete redirection URI used in the authorization request and | |||
it with the redirect_uri parameter. | compares it with the redirect_uri parameter. | |||
[RFC6749], Section 4.1.3, requires the authorization server to "... | Section 4.1.3 of [RFC6749] requires the authorization server to | |||
ensure that the redirect_uri parameter is present if the redirect_uri | ||||
parameter was included in the initial authorization request as | | ensure that the "redirect_uri" parameter is present if the | |||
described in Section 4.1.1, and if included ensure that their values | | "redirect_uri" parameter was included in the initial authorization | |||
are identical.". In the attack scenario described above, the | | request as described in Section 4.1.1, and if included ensure that | |||
legitimate client would use the correct redirect URI it always uses | | their values are identical. | |||
for authorization requests. But this URI would not match the | ||||
tampered redirect URI used by the attacker (otherwise, the redirect | In the attack scenario described in Section 4.5.1, the legitimate | |||
would not land at the attacker's page). So the authorization server | client would use the correct redirection URI it always uses for | |||
would detect the attack and refuse to exchange the code. | authorization requests. But this URI would not match the tampered | |||
redirection URI used by the attacker (otherwise, the redirect would | ||||
not land at the attacker's page). So, the authorization server would | ||||
detect the attack and refuse to exchange the code. | ||||
This check could also detect attempts to inject an authorization code | This check could also detect attempts to inject an authorization code | |||
that had been obtained from another instance of the same client on | that had been obtained from another instance of the same client on | |||
another device if certain conditions are fulfilled: | another device if certain conditions are fulfilled: | |||
* the redirect URI itself needs to contain a nonce or another kind | * the redirection URI itself contains a nonce or another kind of | |||
of one-time use, secret data and | one-time use, secret data and | |||
* the client has bound this data to this particular instance of the | * the client has bound this data to this particular instance of the | |||
client. | client. | |||
But this approach conflicts with the idea of enforcing exact redirect | But, this approach conflicts with the idea of enforcing exact | |||
URI matching at the authorization endpoint. Moreover, it has been | redirect URI matching at the authorization endpoint. Moreover, it | |||
observed that providers very often ignore the redirect_uri check | has been observed that providers very often ignore the redirect_uri | |||
requirement at this stage, maybe because it doesn't seem to be | check requirement at this stage, maybe because it doesn't seem to be | |||
security-critical from reading the specification. | security-critical from reading the specification. | |||
Other providers just pattern match the redirect_uri parameter against | Other providers just pattern match the redirect_uri parameter against | |||
the registered redirect URI pattern. This saves the authorization | the registered redirection URI pattern. This saves the authorization | |||
server from storing the link between the actual redirect URI and the | server from storing the link between the actual redirect URI and the | |||
respective authorization code for every transaction. But this kind | respective authorization code for every transaction. However, this | |||
of check obviously does not fulfill the intent of the specification, | kind of check obviously does not fulfill the intent of the | |||
since the tampered redirect URI is not considered. So any attempt to | specification, since the tampered redirection URI is not considered. | |||
inject an authorization code obtained using the client_id of a | So, any attempt to inject an authorization code obtained using the | |||
legitimate client or by utilizing the legitimate client on another | client_id of a legitimate client or by utilizing the legitimate | |||
device will not be detected in the respective deployments. | client on another device will not be detected in the respective | |||
deployments. | ||||
It is also assumed that the requirements defined in [RFC6749], | It is also assumed that the requirements defined in Section 4.1.3 of | |||
Section 4.1.3, increase client implementation complexity as clients | [RFC6749] increase client implementation complexity as clients need | |||
need to store or re-construct the correct redirect URI for the call | to store or reconstruct the correct redirection URI for the call to | |||
to the token endpoint. | the token endpoint. | |||
Asymmetric methods for client authentication do not stop this attack, | Asymmetric methods for client authentication do not stop this attack, | |||
as the legitimate client authenticates at the token endpoint. | as the legitimate client authenticates at the token endpoint. | |||
This document therefore recommends instead binding every | This document therefore recommends instead binding every | |||
authorization code to a certain client instance on a certain device | authorization code to a certain client instance on a certain device | |||
(or in a certain user agent) in the context of a certain transaction | (or in a certain user agent) in the context of a certain transaction | |||
using one of the mechanisms described next. | using one of the mechanisms described next. | |||
4.5.3. Countermeasures | 4.5.3. Countermeasures | |||
There are two good technical solutions to binding authorization codes | There are two good technical solutions to binding authorization codes | |||
to client instances, outlined in the following. | to client instances, as follows. | |||
4.5.3.1. PKCE | 4.5.3.1. PKCE | |||
The PKCE mechanism specified in [RFC7636] can be used as a | The PKCE mechanism specified in [RFC7636] can be used as a | |||
countermeasure (even though it was originally designed to secure | countermeasure (even though it was originally designed to secure | |||
native apps). When the attacker attempts to inject an authorization | native apps). When the attacker attempts to inject an authorization | |||
code, the check of the code_verifier fails: the client uses its | code, the check of the code_verifier fails: the client uses its | |||
correct verifier, but the code is associated with a code_challenge | correct verifier, but the code is associated with a code_challenge | |||
that does not match this verifier. | that does not match this verifier. | |||
PKCE does not only protect against the authorization code injection | PKCE not only protects against the authorization code injection | |||
attack but also protects authorization codes created for public | attack but also protects authorization codes created for public | |||
clients: PKCE ensures that an attacker cannot redeem a stolen | clients: PKCE ensures that an attacker cannot redeem a stolen | |||
authorization code at the token endpoint of the authorization server | authorization code at the token endpoint of the authorization server | |||
without knowledge of the code_verifier. | without knowledge of the code_verifier. | |||
4.5.3.2. Nonce | 4.5.3.2. Nonce | |||
OpenID Connect's existing nonce parameter can protect against | OpenID Connect's existing nonce parameter can protect against | |||
authorization code injection attacks. The nonce value is one-time | authorization code injection attacks. The nonce value is one-time | |||
use and is created by the client. The client is supposed to bind it | use and is created by the client. The client is supposed to bind it | |||
to the user agent session and send it with the initial request to the | to the user agent session and send it with the initial request to the | |||
OpenID Provider (OP). The OP puts the received nonce value into the | OpenID Provider (OP). The OP puts the received nonce value into the | |||
ID Token that is issued as part of the code exchange at the token | ID Token that is issued as part of the code exchange at the token | |||
endpoint. If an attacker injects an authorization code in the | endpoint. If an attacker injects an authorization code in the | |||
authorization response, the nonce value in the client session and the | authorization response, the nonce value in the client session and the | |||
nonce value in the ID token received from the token endpoint will not | nonce value in the ID Token received from the token endpoint will not | |||
match and the attack is detected. The assumption is that an attacker | match, and the attack is detected. The assumption is that an | |||
cannot get hold of the user agent state on the victim's device (from | attacker cannot get hold of the user agent state on the victim's | |||
which the attacker has stolen the respective authorization code). | device (from which the attacker has stolen the respective | |||
authorization code). | ||||
It is important to note that this countermeasure only works if the | It is important to note that this countermeasure only works if the | |||
client properly checks the nonce parameter in the ID Token obtained | client properly checks the nonce parameter in the ID Token obtained | |||
from the token endpoint and does not use any issued token until this | from the token endpoint and does not use any issued token until this | |||
check has succeeded. More precisely, a client protecting itself | check has succeeded. More precisely, a client protecting itself | |||
against code injection using the nonce parameter | against code injection using the nonce parameter | |||
1. MUST validate the nonce in the ID Token obtained from the token | 1. MUST validate the nonce in the ID Token obtained from the token | |||
endpoint, even if another ID Token was obtained from the | endpoint, even if another ID Token was obtained from the | |||
authorization response (e.g., response_type=code+id_token), and | authorization response (e.g., response_type=code+id_token), and | |||
skipping to change at page 28, line 46 ¶ | skipping to change at line 1322 ¶ | |||
tokens (ID Tokens and the access token) are disregarded and not | tokens (ID Tokens and the access token) are disregarded and not | |||
used for any other purpose. | used for any other purpose. | |||
It is important to note that nonce does not protect authorization | It is important to note that nonce does not protect authorization | |||
codes of public clients, as an attacker does not need to execute an | codes of public clients, as an attacker does not need to execute an | |||
authorization code injection attack. Instead, an attacker can | authorization code injection attack. Instead, an attacker can | |||
directly call the token endpoint with the stolen authorization code. | directly call the token endpoint with the stolen authorization code. | |||
4.5.3.3. Other Solutions | 4.5.3.3. Other Solutions | |||
Other solutions, like binding state to the code, sender-constraining | Other solutions like binding state to the code, sender-constraining | |||
the code using cryptographic means, or per-instance client | the code using cryptographic means, or per-instance client | |||
credentials are conceivable, but lack support and bring new security | credentials are conceivable, but lack support and bring new security | |||
requirements. | requirements. | |||
PKCE is the most obvious solution for OAuth clients as it is | PKCE is the most obvious solution for OAuth clients, as it is | |||
available today, while nonce is appropriate for OpenID Connect | available at the time of writing, while nonce is appropriate for | |||
clients. | OpenID Connect clients. | |||
4.5.4. Limitations | 4.5.4. Limitations | |||
An attacker can circumvent the countermeasures described above if he | An attacker can circumvent the countermeasures described above if | |||
can modify the nonce or code_challenge values that are used in the | they can modify the nonce or code_challenge values that are used in | |||
victim's authorization request. The attacker can modify these values | the victim's authorization request. The attacker can modify these | |||
to be the same ones as those chosen by the client in their own | values to be the same ones as those chosen by the client in their own | |||
session in Step 2 of the attack above. (This requires that the | session in Step 2 of the attack above. (This requires that the | |||
victim's session with the client begins after the attacker started | victim's session with the client begins after the attacker started | |||
their session with the client.) If the attacker is then able to | their session with the client.) If the attacker is then able to | |||
capture the authorization code from the victim, the attacker will be | capture the authorization code from the victim, the attacker will be | |||
able to inject the stolen code in Step 3 even if PKCE or nonce are | able to inject the stolen code in Step 3 even if PKCE or nonce are | |||
used. | used. | |||
This attack is complex and requires a close interaction between the | This attack is complex and requires a close interaction between the | |||
attacker and the victim's session. Nonetheless, measures to prevent | attacker and the victim's session. Nonetheless, measures to prevent | |||
attackers from reading the contents of the authorization response | attackers from reading the contents of the authorization response | |||
still need to be taken, as described in Section 4.1, Section 4.2, | still need to be taken, as described in Sections 4.1, 4.2, 4.3, 4.4, | |||
Section 4.3, Section 4.4, and Section 4.11. | and 4.11. | |||
4.6. Access Token Injection | 4.6. Access Token Injection | |||
In an access token injection attack, the attacker attempts to inject | In an access token injection attack, the attacker attempts to inject | |||
a stolen access token into a legitimate client (that is not under the | a stolen access token into a legitimate client (that is not under the | |||
attacker's control). This will typically happen if the attacker | attacker's control). This will typically happen if the attacker | |||
wants to utilize a leaked access token to impersonate a user in a | wants to utilize a leaked access token to impersonate a user in a | |||
certain client. | certain client. | |||
To conduct the attack, the attacker starts an OAuth flow with the | To conduct the attack, the attacker starts an OAuth flow with the | |||
skipping to change at page 30, line 11 ¶ | skipping to change at line 1379 ¶ | |||
There is no way to detect such an injection attack in pure-OAuth | There is no way to detect such an injection attack in pure-OAuth | |||
flows since the token is issued without any binding to the | flows since the token is issued without any binding to the | |||
transaction or the particular user agent. | transaction or the particular user agent. | |||
In OpenID Connect, the attack can be mitigated, as the authorization | In OpenID Connect, the attack can be mitigated, as the authorization | |||
response additionally contains an ID Token containing the at_hash | response additionally contains an ID Token containing the at_hash | |||
claim. The attacker therefore needs to replace both the access token | claim. The attacker therefore needs to replace both the access token | |||
as well as the ID Token in the response. The attacker cannot forge | as well as the ID Token in the response. The attacker cannot forge | |||
the ID Token, as it is signed or encrypted with authentication. The | the ID Token, as it is signed or encrypted with authentication. The | |||
attacker also cannot inject a leaked ID Token matching the stolen | attacker also cannot inject a leaked ID Token matching the stolen | |||
access token, as the nonce claim in the leaked ID Token will (with a | access token, as the nonce claim in the leaked ID Token will contain | |||
very high probability) contain a different value than the one | (with a very high probability) a different value than the one | |||
expected in the authorization response. | expected in the authorization response. | |||
Note that further protection, like sender-constrained access tokens, | Note that further protection, like sender-constrained access tokens, | |||
is still required to prevent attackers from using the access token at | is still required to prevent attackers from using the access token at | |||
the resource endpoint directly. | the resource endpoint directly. | |||
The recommendations in Section 2.1.2 follow from this. | The recommendations in Section 2.1.2 follow from this. | |||
4.7. Cross-Site Request Forgery | 4.7. Cross-Site Request Forgery | |||
An attacker might attempt to inject a request to the redirect URI of | An attacker might attempt to inject a request to the redirection URI | |||
the legitimate client on the victim's device, e.g., to cause the | of the legitimate client on the victim's device, e.g., to cause the | |||
client to access resources under the attacker's control. This is a | client to access resources under the attacker's control. This is a | |||
variant of an attack known as Cross-Site Request Forgery (CSRF). | variant of an attack known as Cross-Site Request Forgery (CSRF). | |||
4.7.1. Countermeasures | 4.7.1. Countermeasures | |||
The long-established countermeasure is that clients pass a random | The long-established countermeasure is that clients pass a random | |||
value, also known as a CSRF Token, in the state parameter that links | value, also known as a CSRF Token, in the state parameter that links | |||
the request to the redirect URI to the user agent session as | the request to the redirection URI to the user agent session as | |||
described. This countermeasure is described in detail in [RFC6819], | described. This countermeasure is described in detail in | |||
Section 5.3.5. The same protection is provided by PKCE or the OpenID | Section 5.3.5 of [RFC6819]. The same protection is provided by PKCE | |||
Connect nonce value. | or the OpenID Connect nonce value. | |||
When using PKCE instead of state or nonce for CSRF protection, it is | When using PKCE instead of state or nonce for CSRF protection, it is | |||
important to note that: | important to note that: | |||
* Clients MUST ensure that the authorization server supports PKCE | * Clients MUST ensure that the authorization server supports PKCE | |||
before using PKCE for CSRF protection. If an authorization server | before using PKCE for CSRF protection. If an authorization server | |||
does not support PKCE, state or nonce MUST be used for CSRF | does not support PKCE, state or nonce MUST be used for CSRF | |||
protection. | protection. | |||
* If state is used for carrying application state, and the integrity | * If state is used for carrying application state, and the integrity | |||
of its contents is a concern, clients MUST protect state against | of its contents is a concern, clients MUST protect state against | |||
tampering and swapping. This can be achieved by binding the | tampering and swapping. This can be achieved by binding the | |||
contents of state to the browser session and/or signed/encrypted | contents of state to the browser session and/or by signing/ | |||
state values. One example of this is discussed in the now-expired | encrypting state values. One example of this is discussed in the | |||
draft [I-D.bradley-oauth-jwt-encoded-state]. | expired Internet-Draft [JWT-ENCODED-STATE]. | |||
The authorization server therefore MUST provide a way to detect their | The authorization server therefore MUST provide a way to detect their | |||
support for PKCE. Using Authorization Server Metadata according to | support for PKCE. Using Authorization Server Metadata according to | |||
[RFC8414] is RECOMMENDED, but authorization servers MAY instead | [RFC8414] is RECOMMENDED, but authorization servers MAY instead | |||
provide a deployment-specific way to ensure or determine PKCE | provide a deployment-specific way to ensure or determine PKCE | |||
support. | support. | |||
PKCE provides robust protection against CSRF attacks even in presence | PKCE provides robust protection against CSRF attacks even in the | |||
of an attacker that can read the authorization response (see Attacker | presence of an attacker that can read the authorization response (see | |||
A3 in Section 3). When state is used or an ID Token is returned in | Attacker (A3) in Section 3). When state is used or an ID Token is | |||
the authorization response (e.g., response_type=code+id_token), the | returned in the authorization response (e.g., | |||
attacker either learns the state value and can replay it into the | response_type=code+id_token), the attacker either learns the state | |||
forged authorization response, or can extract the nonce from the ID | value and can replay it into the forged authorization response, or | |||
Token and use it in a new request to the authorization server to mint | can extract the nonce from the ID Token and use it in a new request | |||
an ID Token with the same nonce. The new ID Token can then be used | to the authorization server to mint an ID Token with the same nonce. | |||
for the CSRF attack. | The new ID Token can then be used for the CSRF attack. | |||
4.8. PKCE Downgrade Attack | 4.8. PKCE Downgrade Attack | |||
An authorization server that supports PKCE but does not make its use | An authorization server that supports PKCE but does not make its use | |||
mandatory for all flows can be susceptible to a PKCE downgrade | mandatory for all flows can be susceptible to a PKCE downgrade | |||
attack. | attack. | |||
The first prerequisite for this attack is that there is an attacker- | The first prerequisite for this attack is that there is an attacker- | |||
controllable flag in the authorization request that enables or | controllable flag in the authorization request that enables or | |||
disables PKCE for the particular flow. The presence or absence of | disables PKCE for the particular flow. The presence or absence of | |||
the code_challenge parameter lends itself for this purpose, i.e., the | the code_challenge parameter lends itself for this purpose, i.e., the | |||
authorization server enables and enforces PKCE if this parameter is | authorization server enables and enforces PKCE if this parameter is | |||
present in the authorization request, but does not enforce PKCE if | present in the authorization request, but it does not enforce PKCE if | |||
the parameter is missing. | the parameter is missing. | |||
The second prerequisite for this attack is that the client is not | The second prerequisite for this attack is that the client is not | |||
using state at all (e.g., because the client relies on PKCE for CSRF | using state at all (e.g., because the client relies on PKCE for CSRF | |||
prevention) or that the client is not checking state correctly. | prevention) or that the client is not checking state correctly. | |||
Roughly speaking, this attack is a variant of a CSRF attack. The | Roughly speaking, this attack is a variant of a CSRF attack. The | |||
attacker achieves the same goal as in the attack described in | attacker achieves the same goal as in the attack described in | |||
Section 4.7: The attacker injects an authorization code (and with | Section 4.7: The attacker injects an authorization code (and with | |||
that, an access token) that is bound to the attacker's resources into | that, an access token) that is bound to the attacker's resources into | |||
skipping to change at page 32, line 4 ¶ | skipping to change at line 1468 ¶ | |||
a session between their victim and the client. | a session between their victim and the client. | |||
4.8.1. Attack Description | 4.8.1. Attack Description | |||
1. The user has started an OAuth session using some client at an | 1. The user has started an OAuth session using some client at an | |||
authorization server. In the authorization request, the client | authorization server. In the authorization request, the client | |||
has set the parameter code_challenge=hash(abc) as the PKCE code | has set the parameter code_challenge=hash(abc) as the PKCE code | |||
challenge (with the hash function and parameter encoding as | challenge (with the hash function and parameter encoding as | |||
defined in [RFC7636]). The client is now waiting to receive the | defined in [RFC7636]). The client is now waiting to receive the | |||
authorization response from the user's browser. | authorization response from the user's browser. | |||
2. To conduct the attack, the attacker uses their own device to | 2. To conduct the attack, the attacker uses their own device to | |||
start an authorization flow with the targeted client. The client | start an authorization flow with the targeted client. The client | |||
now uses another PKCE code challenge, say | now uses another PKCE code challenge, say, | |||
code_challenge=hash(xyz), in the authorization request. The | code_challenge=hash(xyz), in the authorization request. The | |||
attacker intercepts the request and removes the entire | attacker intercepts the request and removes the entire | |||
code_challenge parameter from the request. Since this step is | code_challenge parameter from the request. Since this step is | |||
performed on the attacker's device, the attacker has full access | performed on the attacker's device, the attacker has full access | |||
to the request contents, for example using browser debug tools. | to the request contents, for example, using browser debug tools. | |||
3. If the authorization server allows for flows without PKCE, it | 3. If the authorization server allows for flows without PKCE, it | |||
will create a code that is not bound to any PKCE code challenge. | will create a code that is not bound to any PKCE code challenge. | |||
4. The attacker now redirects the user's browser to an authorization | 4. The attacker now redirects the user's browser to an authorization | |||
response URL that contains the code for the attacker's session | response URL that contains the code for the attacker's session | |||
with the authorization server. | with the authorization server. | |||
5. The user's browser sends the authorization code to the client, | 5. The user's browser sends the authorization code to the client, | |||
which will now try to redeem the code for an access token at the | which will now try to redeem the code for an access token at the | |||
authorization server. The client will send code_verifier=abc as | authorization server. The client will send code_verifier=abc as | |||
the PKCE code verifier in the token request. | the PKCE code verifier in the token request. | |||
6. Since the authorization server sees that this code is not bound | 6. Since the authorization server sees that this code is not bound | |||
to any PKCE code challenge, it will not check the presence or | to any PKCE code challenge, it will not check the presence or | |||
contents of the code_verifier parameter. It will issue an access | contents of the code_verifier parameter. It will issue an access | |||
token that belongs to the attacker's resource to the client under | token (which belongs to the attacker's resource) to the client | |||
the user's control. | under the user's control. | |||
4.8.2. Countermeasures | 4.8.2. Countermeasures | |||
Using state properly would prevent this attack. However, practice | Using state properly would prevent this attack. However, practice | |||
has shown that many OAuth clients do not use or check state properly. | has shown that many OAuth clients do not use or check state properly. | |||
Therefore, authorization servers MUST mitigate this attack. | Therefore, authorization servers MUST mitigate this attack. | |||
Note that from the view of the authorization server, in the attack | Note that from the view of the authorization server, in the attack | |||
described above, a code_verifier parameter is received at the token | described above, a code_verifier parameter is received at the token | |||
skipping to change at page 33, line 10 ¶ | skipping to change at line 1520 ¶ | |||
* when a code arrives at the token endpoint, and there was a | * when a code arrives at the token endpoint, and there was a | |||
code_challenge in the authorization request for which this code | code_challenge in the authorization request for which this code | |||
was issued, there must be a valid code_verifier in the token | was issued, there must be a valid code_verifier in the token | |||
request. | request. | |||
Beyond this, to prevent PKCE downgrade attacks, the authorization | Beyond this, to prevent PKCE downgrade attacks, the authorization | |||
server MUST ensure that if there was no code_challenge in the | server MUST ensure that if there was no code_challenge in the | |||
authorization request, a request to the token endpoint containing a | authorization request, a request to the token endpoint containing a | |||
code_verifier is rejected. | code_verifier is rejected. | |||
Authorization servers that mandate the use of PKCE in general or for | Authorization servers that mandate the use of PKCE (in general or for | |||
particular clients implicitly implement this security measure. | particular clients) implicitly implement this security measure. | |||
4.9. Access Token Leakage at the Resource Server | 4.9. Access Token Leakage at the Resource Server | |||
Access tokens can leak from a resource server under certain | Access tokens can leak from a resource server under certain | |||
circumstances. | circumstances. | |||
4.9.1. Access Token Phishing by Counterfeit Resource Server | 4.9.1. Access Token Phishing by Counterfeit Resource Server | |||
An attacker may set up their own resource server and trick a client | An attacker may set up their own resource server and trick a client | |||
into sending access tokens to it that are valid for other resource | into sending access tokens to it that are valid for other resource | |||
servers (see Attackers A1 and A5 in Section 3). If the client sends | servers (see Attackers (A1) and (A5) in Section 3). If the client | |||
a valid access token to this counterfeit resource server, the | sends a valid access token to this counterfeit resource server, the | |||
attacker in turn may use that token to access other services on | attacker in turn may use that token to access other services on | |||
behalf of the resource owner. | behalf of the resource owner. | |||
This attack assumes the client is not bound to one specific resource | This attack assumes the client is not bound to one specific resource | |||
server (and its URL) at development time, but client instances are | server (and its URL) at development time, but client instances are | |||
provided with the resource server URL at runtime. This kind of late | provided with the resource server URL at runtime. This kind of late | |||
binding is typical in situations where the client uses a service | binding is typical in situations where the client uses a service | |||
implementing a standardized API (e.g., for e-mail, calendar, health, | implementing a standardized API (e.g., for email, calendaring, | |||
or banking) and where the client is configured by a user or | eHealth, or open banking) and where the client is configured by a | |||
administrator for a service that this user or company uses. | user or administrator. | |||
4.9.2. Compromised Resource Server | 4.9.2. Compromised Resource Server | |||
An attacker may compromise a resource server to gain access to the | An attacker may compromise a resource server to gain access to the | |||
resources of the respective deployment. Such a compromise may range | resources of the respective deployment. Such a compromise may range | |||
from partial access to the system, e.g., its log files, to full | from partial access to the system, e.g., its log files, to full | |||
control over the respective server, in which case all controls can be | control over the respective server, in which case all controls can be | |||
circumvented and all resources can be accessed. The attacker would | circumvented and all resources can be accessed. The attacker would | |||
also be able to obtain other access tokens held on the compromised | also be able to obtain other access tokens held on the compromised | |||
system that would potentially be valid to access other resource | system that would potentially be valid to access other resource | |||
servers. | servers. | |||
Preventing server breaches by hardening and monitoring server systems | Preventing server breaches by hardening and monitoring server systems | |||
is considered a standard operational procedure and, therefore, out of | is considered a standard operational procedure and, therefore, out of | |||
the scope of this document. This section focuses on the impact of | the scope of this document. Section 4.9 focuses on the impact of | |||
OAuth-related breaches and the replaying of captured access tokens. | OAuth-related breaches and the replaying of captured access tokens. | |||
4.9.3. Countermeasures | 4.9.3. Countermeasures | |||
The following measures should be taken into account by implementers | The following measures should be taken into account by implementers | |||
in order to cope with access token replay by malicious actors: | in order to cope with access token replay by malicious actors: | |||
* Sender-constrained access tokens, as described in Section 4.10.1, | * Sender-constrained access tokens, as described in Section 4.10.1, | |||
SHOULD be used to prevent the attacker from replaying the access | SHOULD be used to prevent the attacker from replaying the access | |||
tokens on other resource servers. If an attacker has only partial | tokens on other resource servers. If an attacker has only partial | |||
access to the compromised system, like a read-only access to web | access to the compromised system, like a read-only access to web | |||
server logs, sender-constrained access tokens may also prevent | server logs, sender-constrained access tokens may also prevent | |||
replay on the compromised system. | replay on the compromised system. | |||
* Audience restriction as described in Section 4.10.2 SHOULD be used | * Audience restriction as described in Section 4.10.2 SHOULD be used | |||
to prevent replay of captured access tokens on other resource | to prevent replay of captured access tokens on other resource | |||
servers. | servers. | |||
* The resource server MUST treat access tokens like other sensitive | * The resource server MUST treat access tokens like other sensitive | |||
secrets and not store or transfer them in plain text. | secrets and not store or transfer them in plaintext. | |||
The first and second recommendations also apply to other scenarios | The first and second recommendations also apply to other scenarios | |||
where access tokens leak (see Attacker A5 in Section 3). | where access tokens leak (see Attacker (A5) in Section 3). | |||
4.10. Misuse of Stolen Access Tokens | 4.10. Misuse of Stolen Access Tokens | |||
Access tokens can be stolen by an attacker in various ways, for | Access tokens can be stolen by an attacker in various ways, for | |||
example, via the attacks described in Section 4.1, Section 4.2, | example, via the attacks described in Sections 4.1, 4.2, 4.3, 4.4, | |||
Section 4.3, Section 4.4 and Section 4.9. Some of these attacks can | and 4.9. Some of these attacks can be mitigated by specific security | |||
be mitigated by specific security measures, as described in the | measures, as described in the respective sections. However, in some | |||
respective sections. However, in some cases, these measures are not | cases, these measures are not sufficient or are not implemented | |||
sufficient or are not implemented correctly. Authorization servers | correctly. Authorization servers therefore SHOULD ensure that access | |||
therefore SHOULD ensure that access tokens are sender-constrained and | tokens are sender-constrained and audience-restricted as described in | |||
audience-restricted as described in the following. Architecture and | the following. Architecture and performance reasons may prevent the | |||
performance reasons may prevent the use of these measures in some | use of these measures in some deployments. | |||
deployments. | ||||
4.10.1. Sender-Constrained Access Tokens | 4.10.1. Sender-Constrained Access Tokens | |||
As the name suggests, sender-constrained access tokens scope the | As the name suggests, sender-constrained access tokens scope the | |||
applicability of an access token to a certain sender. This sender is | applicability of an access token to a certain sender. This sender is | |||
obliged to demonstrate knowledge of a certain secret as a | obliged to demonstrate knowledge of a certain secret as a | |||
prerequisite for the acceptance of that token at a resource server. | prerequisite for the acceptance of that token at a resource server. | |||
A typical flow looks like this: | A typical flow looks like this: | |||
skipping to change at page 35, line 4 ¶ | skipping to change at line 1607 ¶ | |||
obliged to demonstrate knowledge of a certain secret as a | obliged to demonstrate knowledge of a certain secret as a | |||
prerequisite for the acceptance of that token at a resource server. | prerequisite for the acceptance of that token at a resource server. | |||
A typical flow looks like this: | A typical flow looks like this: | |||
1. The authorization server associates data with the access token | 1. The authorization server associates data with the access token | |||
that binds this particular token to a certain client. The | that binds this particular token to a certain client. The | |||
binding can utilize the client's identity, but in most cases, the | binding can utilize the client's identity, but in most cases, the | |||
authorization server utilizes key material (or data derived from | authorization server utilizes key material (or data derived from | |||
the key material) known to the client. | the key material) known to the client. | |||
2. This key material must be distributed somehow. Either the key | 2. This key material must be distributed somehow. Either the key | |||
material already exists before the authorization server creates | material already exists before the authorization server creates | |||
the binding or the authorization server creates ephemeral keys. | the binding or the authorization server creates ephemeral keys. | |||
The way pre-existing key material is distributed varies among the | The way preexisting key material is distributed varies among the | |||
different approaches. For example, X.509 Certificates can be | different approaches. For example, X.509 certificates can be | |||
used, in which case the distribution happens explicitly during | used, in which case the distribution happens explicitly during | |||
the enrollment process. Or the key material is created and | the enrollment process. Or, the key material is created and | |||
distributed at the TLS layer, in which case it might | distributed at the TLS layer, in which case it might | |||
automatically happen during the setup of a TLS connection. | automatically happen during the setup of a TLS connection. | |||
3. The resource server must implement the actual proof of possession | 3. The resource server must implement the actual proof-of-possession | |||
check. This is typically done on the application level, often | check. This is typically done on the application level, often | |||
tied to specific material provided by transport layer (e.g., | tied to specific material provided by the transport layer (e.g., | |||
TLS). The resource server must also ensure that a replay of the | TLS). The resource server must also ensure that a replay of the | |||
proof of possession is not possible. | proof of possession is not possible. | |||
Two methods for sender-constrained access tokens using proof-of- | Two methods for sender-constrained access tokens using proof of | |||
possession have been defined by the OAuth working group and are in | possession have been defined by the OAuth working group and are in | |||
use in practice: | use in practice: | |||
* OAuth 2.0 Mutual-TLS Client Authentication and Certificate-Bound | * "OAuth 2.0 Mutual-TLS Client Authentication and Certificate-Bound | |||
Access Tokens ([RFC8705]): The approach specified in this document | Access Tokens" [RFC8705]: The approach specified in this) document | |||
allows the use of mutual TLS (mTLS) for both client authentication | allows the use of mutual TLS for both client authentication and | |||
and sender-constrained access tokens. For the purpose of sender- | sender-constrained access tokens. For the purpose of sender- | |||
constrained access tokens, the client is identified towards the | constrained access tokens, the client is identified towards the | |||
resource server by the fingerprint of its public key. During the | resource server by the fingerprint of its public key. During the | |||
processing of an access token request, the authorization server | processing of an access token request, the authorization server | |||
obtains the client's public key from the TLS stack and associates | obtains the client's public key from the TLS stack and associates | |||
its fingerprint with the respective access tokens. The resource | its fingerprint with the respective access tokens. The resource | |||
server in the same way obtains the public key from the TLS stack | server in the same way obtains the public key from the TLS stack | |||
and compares its fingerprint with the fingerprint associated with | and compares its fingerprint with the fingerprint associated with | |||
the access token. | the access token. | |||
* OAuth 2.0 Demonstrating Proof of Possession (DPoP) ([RFC9449]): | * "OAuth 2.0 Demonstrating Proof of Possession (DPoP)" [RFC9449]: | |||
DPoP outlines an application-level sender-constraining for access | DPoP outlines an application-level mechanism for sender- | |||
and refresh tokens. It uses proof-of-possession based on a | constraining access and refresh tokens. It uses proof-of- | |||
public/private key pair and application-level signing. DPoP can | possession based on a public/private key pair and application- | |||
be used with public clients and, in the case of confidential | level signing. DPoP can be used with public clients and, in the | |||
clients, can be combined with any client authentication method. | case of confidential clients, can be combined with any client | |||
authentication method. | ||||
Note that the security of sender-constrained tokens is undermined | Note that the security of sender-constrained tokens is undermined | |||
when an attacker gets access to the token and the key material. This | when an attacker gets access to the token and the key material. This | |||
is, in particular, the case for corrupted client software and cross- | is, in particular, the case for corrupted client software and cross- | |||
site scripting attacks (when the client is running in the browser). | site scripting attacks (when the client is running in the browser). | |||
If the key material is protected in a hardware or software security | If the key material is protected in a hardware or software security | |||
module or only indirectly accessible (like in a TLS stack), sender- | module or only indirectly accessible (like in a TLS stack), sender- | |||
constrained tokens at least protect against the use of the token when | constrained tokens at least protect against the use of the token when | |||
the client is offline, i.e., when the security module or interface is | the client is offline, i.e., when the security module or interface is | |||
not available to the attacker. This applies to access tokens as well | not available to the attacker. This applies to access tokens as well | |||
as to refresh tokens (see Section 4.14). | as to refresh tokens (see Section 4.14). | |||
4.10.2. Audience-Restricted Access Tokens | 4.10.2. Audience-Restricted Access Tokens | |||
Audience restriction essentially restricts access tokens to a | Audience restriction essentially restricts access tokens to a | |||
particular resource server. The authorization server associates the | particular resource server. The authorization server associates the | |||
access token with the particular resource server and the resource | access token with the particular resource server, and the resource | |||
server is then supposed to verify the intended audience. If the | server is then supposed to verify the intended audience. If the | |||
access token fails the intended audience validation, the resource | access token fails the intended audience validation, the resource | |||
server refuses to serve the respective request. | server refuses to serve the respective request. | |||
In general, audience restriction limits the impact of token leakage. | In general, audience restriction limits the impact of token leakage. | |||
In the case of a counterfeit resource server, it may (as described | In the case of a counterfeit resource server, it may (as described | |||
below) also prevent abuse of the phished access token at the | below) also prevent abuse of the phished access token at the | |||
legitimate resource server. | legitimate resource server. | |||
The audience can be expressed using logical names or physical | The audience can be expressed using logical names or physical | |||
skipping to change at page 37, line 10 ¶ | skipping to change at line 1701 ¶ | |||
legitimate resource server's URL by using a valid TLS certificate | legitimate resource server's URL by using a valid TLS certificate | |||
obtained from a different CA. It might also be considered a privacy | obtained from a different CA. It might also be considered a privacy | |||
benefit to hide the resource server URL from the authorization | benefit to hide the resource server URL from the authorization | |||
server. | server. | |||
Audience restriction may seem easier to use since it does not require | Audience restriction may seem easier to use since it does not require | |||
any cryptography on the client side. Still, since every access token | any cryptography on the client side. Still, since every access token | |||
is bound to a specific resource server, the client also needs to | is bound to a specific resource server, the client also needs to | |||
obtain a single resource server-specific access token when accessing | obtain a single resource server-specific access token when accessing | |||
several resource servers. (Resource indicators, as specified in | several resource servers. (Resource indicators, as specified in | |||
[RFC8707], can help to achieve this.) [I-D.ietf-oauth-token-binding] | [RFC8707], can help to achieve this.) [TOKEN-BINDING] had the same | |||
had the same property since different token-binding IDs must be | property since different token-binding IDs must be associated with | |||
associated with the access token. Using [RFC8705], on the other | the access token. Using mutual TLS for OAuth 2.0 [RFC8705], on the | |||
hand, allows a client to use the access token at multiple resource | other hand, allows a client to use the access token at multiple | |||
servers. | resource servers. | |||
It should be noted that audience restrictions, or generally speaking | It should be noted that audience restrictions -- or, generally | |||
an indication by the client to the authorization server where it | speaking, an indication by the client to the authorization server | |||
wants to use the access token, have additional benefits beyond the | where it wants to use the access token -- have additional benefits | |||
scope of token leakage prevention. It allows the authorization | beyond the scope of token leakage prevention. They allow the | |||
server to create a different access token whose format and content | authorization server to create a different access token whose format | |||
are specifically minted for the respective server. This has huge | and content are specifically minted for the respective server. This | |||
functional and privacy advantages in deployments using structured | has huge functional and privacy advantages in deployments using | |||
access tokens. | structured access tokens. | |||
4.10.3. Discussion: Preventing Leakage via Metadata | 4.10.3. Discussion: Preventing Leakage via Metadata | |||
An authorization server could provide the client with additional | An authorization server could provide the client with additional | |||
information about the locations where it is safe to use its access | information about the locations where it is safe to use its access | |||
tokens. This approach, and why it is not recommended, is discussed | tokens. This approach, and why it is not recommended, is discussed | |||
in the following. | in the following. | |||
In the simplest form, this would require the authorization server to | In the simplest form, this would require the authorization server to | |||
publish a list of its known resource servers, illustrated in the | publish a list of its known resource servers, illustrated in the | |||
skipping to change at page 38, line 4 ¶ | skipping to change at line 1742 ¶ | |||
"issuer":"https://server.somesite.example", | "issuer":"https://server.somesite.example", | |||
"authorization_endpoint": | "authorization_endpoint": | |||
"https://server.somesite.example/authorize", | "https://server.somesite.example/authorize", | |||
"resource_servers":[ | "resource_servers":[ | |||
"email.somesite.example", | "email.somesite.example", | |||
"storage.somesite.example", | "storage.somesite.example", | |||
"video.somesite.example" | "video.somesite.example" | |||
] | ] | |||
... | ... | |||
} | } | |||
The authorization server could also return the URL(s) an access token | The authorization server could also return the URL(s) an access token | |||
is good for in the token response, illustrated by the example and | is good for in the token response, illustrated by the example and | |||
non-standard return parameter access_token_resource_server: | non-standard return parameter access_token_resource_server: | |||
HTTP/1.1 200 OK | HTTP/1.1 200 OK | |||
Content-Type: application/json;charset=UTF-8 | Content-Type: application/json;charset=UTF-8 | |||
Cache-Control: no-store | Cache-Control: no-store | |||
Pragma: no-cache | Pragma: no-cache | |||
{ | { | |||
"access_token":"2YotnFZFEjr1zCsicMWpAA", | "access_token":"2YotnFZFEjr1zCsicMWpAA", | |||
"access_token_resource_server": | "access_token_resource_server": | |||
"https://hostedresource.somesite.example/path1", | "https://hostedresource.somesite.example/path1", | |||
... | ... | |||
} | } | |||
This mitigation strategy would rely on the client to enforce the | This mitigation strategy would rely on the client to enforce the | |||
security policy and to only send access tokens to legitimate | security policy and to only send access tokens to legitimate | |||
destinations. Results of OAuth-related security research (see for | destinations. Results of OAuth-related security research (see, for | |||
example [research.ubc] and [research.cmu]) indicate a large portion | example, [research.ubc] and [research.cmu]) indicate a large portion | |||
of client implementations do not or fail to properly implement | of client implementations do not or fail to properly implement | |||
security controls, like state checks. So relying on clients to | security controls, like state checks. So, relying on clients to | |||
prevent access token phishing is likely to fail as well. Moreover, | prevent access token phishing is likely to fail as well. Moreover, | |||
given the ratio of clients to authorization and resource servers, it | given the ratio of clients to authorization and resource servers, it | |||
is considered the more viable approach to move as much as possible | is considered the more viable approach to move as much as possible | |||
security-related logic to those entities. Clearly, the client has to | security-related logic to those servers. Clearly, the client has to | |||
contribute to the overall security. However, there are alternative | contribute to the overall security. However, there are alternative | |||
countermeasures, as described before, that provide a better balance | countermeasures, as described in Sections 4.10.1 and 4.10.2, that | |||
between the involved parties. | provide a better balance between the involved parties. | |||
4.11. Open Redirection | 4.11. Open Redirection | |||
The following attacks can occur when an authorization server or | The following attacks can occur when an authorization server or | |||
client has an open redirector. Such endpoints are sometimes | client has an open redirector. Such endpoints are sometimes | |||
implemented, for example, to show a message before a user is then | implemented, for example, to show a message before a user is then | |||
redirected to an external website, or to redirect users back to a URL | redirected to an external website, or to redirect users back to a URL | |||
they were intending to visit before being interrupted, e.g., by a | they were intending to visit before being interrupted, e.g., by a | |||
login prompt. | login prompt. | |||
skipping to change at page 39, line 15 ¶ | skipping to change at line 1801 ¶ | |||
In order to prevent open redirection, clients should only redirect if | In order to prevent open redirection, clients should only redirect if | |||
the target URLs are allowed or if the origin and integrity of a | the target URLs are allowed or if the origin and integrity of a | |||
request can be authenticated. Countermeasures against open | request can be authenticated. Countermeasures against open | |||
redirection are described by OWASP [owasp.redir]. | redirection are described by OWASP [owasp.redir]. | |||
4.11.2. Authorization Server as Open Redirector | 4.11.2. Authorization Server as Open Redirector | |||
Just as with clients, attackers could try to utilize a user's trust | Just as with clients, attackers could try to utilize a user's trust | |||
in the authorization server (and its URL in particular) for | in the authorization server (and its URL in particular) for | |||
performing phishing attacks. OAuth authorization servers regularly | performing phishing attacks. OAuth authorization servers regularly | |||
redirect users to other websites (the clients), but must do so | redirect users to other websites (the clients), but they must do so | |||
safely. | safely. | |||
[RFC6749], Section 4.1.2.1, already prevents open redirects by | Section 4.1.2.1 of [RFC6749] already prevents open redirects by | |||
stating that the authorization server MUST NOT automatically redirect | stating that the authorization server MUST NOT automatically redirect | |||
the user agent in case of an invalid combination of client_id and | the user agent in case of an invalid combination of client_id and | |||
redirect_uri. | redirect_uri. | |||
However, an attacker could also utilize a correctly registered | However, an attacker could also utilize a correctly registered | |||
redirect URI to perform phishing attacks. The attacker could, for | redirection URI to perform phishing attacks. The attacker could, for | |||
example, register a client via dynamic client registration [RFC7591] | example, register a client via dynamic client registration [RFC7591] | |||
and execute one of the following attacks: | and execute one of the following attacks: | |||
1. Intentionally send an erroneous authorization request, e.g., by | 1. Intentionally send an erroneous authorization request, e.g., by | |||
using an invalid scope value, thus instructing the authorization | using an invalid scope value, thus instructing the authorization | |||
server to redirect the user-agent to its phishing site. | server to redirect the user agent to its phishing site. | |||
2. Intentionally send a valid authorization request with client_id | 2. Intentionally send a valid authorization request with client_id | |||
and redirect_uri controlled by the attacker. After the user | and redirect_uri controlled by the attacker. After the user | |||
authenticates, the authorization server prompts the user to | authenticates, the authorization server prompts the user to | |||
provide consent to the request. If the user notices an issue | provide consent to the request. If the user notices an issue | |||
with the request and declines the request, the authorization | with the request and declines the request, the authorization | |||
server still redirects the user agent to the phishing site. In | server still redirects the user agent to the phishing site. In | |||
this case, the user agent will be redirected to the phishing site | this case, the user agent will be redirected to the phishing site | |||
regardless of the action taken by the user. | regardless of the action taken by the user. | |||
3. Intentionally send a valid silent authentication request | 3. Intentionally send a valid silent authentication request | |||
(prompt=none) with client_id and redirect_uri controlled by the | (prompt=none) with client_id and redirect_uri controlled by the | |||
attacker. In this case, the authorization server will | attacker. In this case, the authorization server will | |||
automatically redirect the user agent to the phishing site. | automatically redirect the user agent to the phishing site. | |||
The authorization server MUST take precautions to prevent these | The authorization server MUST take precautions to prevent these | |||
threats. The authorization server MUST always authenticate the user | threats. The authorization server MUST always authenticate the user | |||
first and, with the exception of the silent authentication use case, | first and, with the exception of the silent authentication use case, | |||
prompt the user for credentials when needed, before redirecting the | prompt the user for credentials when needed, before redirecting the | |||
user. Based on its risk assessment, the authorization server needs | user. Based on its risk assessment, the authorization server needs | |||
to decide whether it can trust the redirect URI or not. It could | to decide whether or not it can trust the redirection URI. It could | |||
take into account URI analytics done internally or through some | take into account URI analytics done internally or through some | |||
external service to evaluate the credibility and trustworthiness of | external service to evaluate the credibility and trustworthiness of | |||
content behind the URI, and the source of the redirect URI and other | content behind the URI, and the source of the redirection URI and | |||
client data. | other client data. | |||
The authorization server SHOULD only automatically redirect the user | The authorization server SHOULD only automatically redirect the user | |||
agent if it trusts the redirect URI. If the URI is not trusted, the | agent if it trusts the redirection URI. If the URI is not trusted, | |||
authorization server MAY inform the user and rely on the user to make | the authorization server MAY inform the user and rely on the user to | |||
the correct decision. | make the correct decision. | |||
4.12. 307 Redirect | 4.12. 307 Redirect | |||
At the authorization endpoint, a typical protocol flow is that the | At the authorization endpoint, a typical protocol flow is that the | |||
authorization server prompts the user to enter their credentials in a | authorization server prompts the user to enter their credentials in a | |||
form that is then submitted (using the HTTP POST method) back to the | form that is then submitted (using the HTTP POST method) back to the | |||
authorization server. The authorization server checks the | authorization server. The authorization server checks the | |||
credentials and, if successful, redirects the user agent to the | credentials and, if successful, redirects the user agent to the | |||
client's redirection endpoint. | client's redirection endpoint. | |||
In [RFC6749], the HTTP status code 302 is used for this purpose, but | In [RFC6749], the HTTP status code 302 (Found) is used for this | |||
"any other method available via the user-agent to accomplish this | purpose, but "any other method available via the user-agent to | |||
redirection is allowed". When the status code 307 is used for | accomplish this redirection is allowed". When the status code 307 is | |||
redirection instead, the user agent will send the user's credentials | used for redirection instead, the user agent will send the user's | |||
via HTTP POST to the client. | credentials via HTTP POST to the client. | |||
This discloses the sensitive credentials to the client. If the | This discloses the sensitive credentials to the client. If the | |||
client is malicious, it can use the credentials to impersonate the | client is malicious, it can use the credentials to impersonate the | |||
user at the authorization server. | user at the authorization server. | |||
The behavior might be unexpected for developers but is defined in | The behavior might be unexpected for developers but is defined in | |||
[RFC9110], Section 15.4.8. This status code does not require the | Section 15.4.8 of [RFC9110]. This status code (307) does not require | |||
user agent to rewrite the POST request to a GET request and thereby | the user agent to rewrite the POST request to a GET request and | |||
drop the form data in the POST request body. | thereby drop the form data in the POST request body. | |||
In the HTTP standard [RFC9110], only the status code 303 | In the HTTP standard [RFC9110], only the status code 303 | |||
unambiguously enforces rewriting the HTTP POST request to an HTTP GET | unambiguously enforces rewriting the HTTP POST request to an HTTP GET | |||
request. For all other status codes, including the popular 302, user | request. For all other status codes, including the popular 302, user | |||
agents can opt not to rewrite POST to GET requests and therefore to | agents can opt not to rewrite POST to GET requests, thereby causing | |||
reveal the user's credentials to the client. (In practice, however, | the user's credentials to be revealed to the client. (In practice, | |||
most user agents will only show this behaviour for 307 redirects.) | however, most user agents will only show this behavior for 307 | |||
redirects.) | ||||
Authorization servers that redirect a request that potentially | Authorization servers that redirect a request that potentially | |||
contains the user's credentials therefore MUST NOT use the HTTP 307 | contains the user's credentials therefore MUST NOT use the HTTP 307 | |||
status code for redirection. If an HTTP redirection (and not, for | status code for redirection. If an HTTP redirection (and not, for | |||
example, JavaScript) is used for such a request, the authorization | example, JavaScript) is used for such a request, the authorization | |||
server SHOULD use HTTP status code 303 (See Other). | server SHOULD use HTTP status code 303 (See Other). | |||
4.13. TLS Terminating Reverse Proxies | 4.13. TLS Terminating Reverse Proxies | |||
A common deployment architecture for HTTP applications is to hide the | A common deployment architecture for HTTP applications is to hide the | |||
application server behind a reverse proxy that terminates the TLS | application server behind a reverse proxy that terminates the TLS | |||
skipping to change at page 41, line 46 ¶ | skipping to change at line 1920 ¶ | |||
logic performed in the application server, the attacker could simply | logic performed in the application server, the attacker could simply | |||
add an allowed IP address to the header and render the protection | add an allowed IP address to the header and render the protection | |||
useless. | useless. | |||
A reverse proxy MUST therefore sanitize any inbound requests to | A reverse proxy MUST therefore sanitize any inbound requests to | |||
ensure the authenticity and integrity of all header values relevant | ensure the authenticity and integrity of all header values relevant | |||
for the security of the application servers. | for the security of the application servers. | |||
If an attacker were able to get access to the internal network | If an attacker were able to get access to the internal network | |||
between the proxy and application server, the attacker could also try | between the proxy and application server, the attacker could also try | |||
to circumvent security controls in place. It is, therefore, | to circumvent security controls in place. Therefore, it is essential | |||
essential to ensure the authenticity of the communicating entities. | to ensure the authenticity of the communicating entities. | |||
Furthermore, the communication link between the reverse proxy and | Furthermore, the communication link between the reverse proxy and | |||
application server MUST be protected against eavesdropping, | application server MUST be protected against eavesdropping, | |||
injection, and replay of messages. | injection, and replay of messages. | |||
4.14. Refresh Token Protection | 4.14. Refresh Token Protection | |||
Refresh tokens are a convenient and user-friendly way to obtain new | Refresh tokens are a convenient and user-friendly way to obtain new | |||
access tokens. They also add to the security of OAuth, since they | access tokens. They also add to the security of OAuth, since they | |||
allow the authorization server to issue access tokens with a short | allow the authorization server to issue access tokens with a short | |||
lifetime and reduced scope, thus reducing the potential impact of | lifetime and reduced scope, thus reducing the potential impact of | |||
access token leakage. | access token leakage. | |||
4.14.1. Discussion | 4.14.1. Discussion | |||
Refresh tokens are an attractive target for attackers since they | Refresh tokens are an attractive target for attackers because they | |||
represent the full scope of grant a resource owner delegated to a | represent the full scope of access granted to a certain client, and | |||
certain client and they are not further constrained to a specific | they are not further constrained to a specific resource. If an | |||
resource. If an attacker is able to exfiltrate and successfully | attacker is able to exfiltrate and successfully replay a refresh | |||
replay a refresh token, the attacker will be able to mint access | token, the attacker will be able to mint access tokens and use them | |||
tokens and use them to access resource servers on behalf of the | to access resource servers on behalf of the resource owner. | |||
resource owner. | ||||
[RFC6749] already provides robust baseline protection by requiring | [RFC6749] already provides robust baseline protection by requiring | |||
* confidentiality of the refresh tokens in transit and storage, | * confidentiality of the refresh tokens in transit and storage, | |||
* the transmission of refresh tokens over TLS-protected connections | * the transmission of refresh tokens over TLS-protected connections | |||
between authorization server and client, | between authorization server and client, | |||
* the authorization server to maintain and check the binding of a | * the authorization server to maintain and check the binding of a | |||
refresh token to a certain client and authentication of this | refresh token to a certain client and authentication of this | |||
client during token refresh, if possible, and | client during token refresh, if possible, and | |||
* that refresh tokens cannot be generated, modified, or guessed. | * that refresh tokens cannot be generated, modified, or guessed. | |||
skipping to change at page 43, line 22 ¶ | skipping to change at line 1988 ¶ | |||
Authorization servers MUST utilize one of these methods to detect | Authorization servers MUST utilize one of these methods to detect | |||
refresh token replay by malicious actors for public clients: | refresh token replay by malicious actors for public clients: | |||
* *Sender-constrained refresh tokens:* the authorization server | * *Sender-constrained refresh tokens:* the authorization server | |||
cryptographically binds the refresh token to a certain client | cryptographically binds the refresh token to a certain client | |||
instance, e.g., by utilizing [RFC8705] or [RFC9449]. | instance, e.g., by utilizing [RFC8705] or [RFC9449]. | |||
* *Refresh token rotation:* the authorization server issues a new | * *Refresh token rotation:* the authorization server issues a new | |||
refresh token with every access token refresh response. The | refresh token with every access token refresh response. The | |||
previous refresh token is invalidated but information about the | previous refresh token is invalidated, but information about the | |||
relationship is retained by the authorization server. If a | relationship is retained by the authorization server. If a | |||
refresh token is compromised and subsequently used by both the | refresh token is compromised and subsequently used by both the | |||
attacker and the legitimate client, one of them will present an | attacker and the legitimate client, one of them will present an | |||
invalidated refresh token, which will inform the authorization | invalidated refresh token, which will inform the authorization | |||
server of the breach. The authorization server cannot determine | server of the breach. The authorization server cannot determine | |||
which party submitted the invalid refresh token, but it will | which party submitted the invalid refresh token, but it will | |||
revoke the active refresh token. This stops the attack at the | revoke the active refresh token. This stops the attack at the | |||
cost of forcing the legitimate client to obtain a fresh | cost of forcing the legitimate client to obtain a fresh | |||
authorization grant. | authorization grant. | |||
skipping to change at page 43, line 44 ¶ | skipping to change at line 2010 ¶ | |||
may be encoded into the refresh token itself. This can enable an | may be encoded into the refresh token itself. This can enable an | |||
authorization server to efficiently determine the grant to which a | authorization server to efficiently determine the grant to which a | |||
refresh token belongs, and by extension, all refresh tokens that | refresh token belongs, and by extension, all refresh tokens that | |||
need to be revoked. Authorization servers MUST ensure the | need to be revoked. Authorization servers MUST ensure the | |||
integrity of the refresh token value in this case, for example, | integrity of the refresh token value in this case, for example, | |||
using signatures. | using signatures. | |||
Authorization servers MAY revoke refresh tokens automatically in case | Authorization servers MAY revoke refresh tokens automatically in case | |||
of a security event, such as: | of a security event, such as: | |||
* password change | * password change or | |||
* logout at the authorization server | * logout at the authorization server. | |||
Refresh tokens SHOULD expire if the client has been inactive for some | Refresh tokens SHOULD expire if the client has been inactive for some | |||
time, i.e., the refresh token has not been used to obtain fresh | time, i.e., the refresh token has not been used to obtain fresh | |||
access tokens for some time. The expiration time is at the | access tokens for some time. The expiration time is at the | |||
discretion of the authorization server. It might be a global value | discretion of the authorization server. It might be a global value | |||
or determined based on the client policy or the grant associated with | or determined based on the client policy or the grant associated with | |||
the refresh token (and its sensitivity). | the refresh token (and its sensitivity). | |||
4.15. Client Impersonating Resource Owner | 4.15. Client Impersonating Resource Owner | |||
Resource servers may make access control decisions based on the | Resource servers may make access control decisions based on the | |||
identity of a resource owner for which an access token was issued, or | identity of a resource owner for which an access token was issued, or | |||
based on the identity of a client in the client credentials grant. | based on the identity of a client in the client credentials grant. | |||
For example, [RFC9068] (JSON Web Token (JWT) Profile for OAuth 2.0 | For example, [RFC9068] (JSON Web Token (JWT) Profile for OAuth 2.0 | |||
Access Tokens) describes a data structure for access tokens | Access Tokens) describes a data structure for access tokens | |||
containing a sub claim defined as follows: | containing a sub claim defined as follows: | |||
| In cases of access tokens obtained through grants where a resource | | In cases of access tokens obtained through grants where a resource | |||
| owner is involved, such as the authorization code grant, the value | | owner is involved, such as the authorization code grant, the value | |||
| of sub SHOULD correspond to the subject identifier of the resource | | of "sub" SHOULD correspond to the subject identifier of the | |||
| owner. In cases of access tokens obtained through grants where no | | resource owner. In cases of access tokens obtained through grants | |||
| resource owner is involved, such as the client credentials grant, | | where no resource owner is involved, such as the client | |||
| the value of sub SHOULD correspond to an identifier the | | credentials grant, the value of "sub" SHOULD correspond to an | |||
| authorization server uses to indicate the client application. | | identifier the authorization server uses to indicate the client | |||
| application. | ||||
If both options are possible, a resource server may mistake a | If both options are possible, a resource server may mistake a | |||
client's identity for the identity of a resource owner. For example, | client's identity for the identity of a resource owner. For example, | |||
if a client is able to choose its own client_id during registration | if a client is able to choose its own client_id during registration | |||
with the authorization server, a malicious client may set it to a | with the authorization server, a malicious client may set it to a | |||
value identifying a resource owner (e.g., a sub value if OpenID | value identifying a resource owner (e.g., a sub value if OpenID | |||
Connect is used). If the resource server cannot properly distinguish | Connect is used). If the resource server cannot properly distinguish | |||
between access tokens obtained with involvement of the resource owner | between access tokens obtained with involvement of the resource owner | |||
and those without, the client may accidentally be able to access | and those without, the client may accidentally be able to access | |||
resources belonging to the resource owner. | resources belonging to the resource owner. | |||
This attack potentially affects not only implementations using | This attack potentially affects not only implementations using | |||
[RFC9068], but also similar, bespoke solutions. | [RFC9068], but also similar, bespoke solutions. | |||
4.15.1. Countermeasures | 4.15.1. Countermeasures | |||
Authorization servers SHOULD NOT allow clients to influence their | Authorization servers SHOULD NOT allow clients to influence their | |||
client_id or any claim that could cause confusion with a genuine | client_id or any other claim that could cause confusion with a | |||
resource owner if a common namespace for client IDs and user | genuine resource owner if a common namespace for client IDs and user | |||
identifiers exists, such as in the sub claim shown above. Where this | identifiers exists, such as in the sub claim example from [RFC9068] | |||
cannot be avoided, authorization servers MUST provide other means for | shown in Section 4.15 above. Where this cannot be avoided, | |||
the resource server to distinguish between the two types of access | authorization servers MUST provide other means for the resource | |||
tokens. | server to distinguish between the two types of access tokens. | |||
4.16. Clickjacking | 4.16. Clickjacking | |||
As described in Section 4.4.1.9 of [RFC6819], the authorization | As described in Section 4.4.1.9 of [RFC6819], the authorization | |||
request is susceptible to clickjacking attacks, also called user | request is susceptible to clickjacking attacks, also called user | |||
interface redressing. In such an attack, an attacker embeds the | interface redressing. In such an attack, an attacker embeds the | |||
authorization endpoint user interface in an innocuous context. A | authorization endpoint user interface in an innocuous context. A | |||
user believing to interact with that context, for example, by | user believing to interact with that context, for example, by | |||
clicking on buttons, inadvertently interacts with the authorization | clicking on buttons, inadvertently interacts with the authorization | |||
endpoint user interface instead. The opposite can be achieved as | endpoint user interface instead. The opposite can be achieved as | |||
well: A user believing to interact with the authorization endpoint | well: A user believing to interact with the authorization endpoint | |||
might inadvertently type a password into an attacker-provided input | might inadvertently type a password into an attacker-provided input | |||
field overlaid over the original user interface. Clickjacking | field overlaid over the original user interface. Clickjacking | |||
attacks can be designed such that users can hardly notice the attack, | attacks can be designed such that users can hardly notice the attack, | |||
for example using almost invisible iframes overlaid on top of other | for example, using almost invisible iframes overlaid on top of other | |||
elements. | elements. | |||
An attacker can use this vector to obtain the user's authentication | An attacker can use this vector to obtain the user's authentication | |||
credentials, change the scope of access granted to the client, and | credentials, change the scope of access granted to the client, and | |||
potentially access the user's resources. | potentially access the user's resources. | |||
Authorization servers MUST prevent clickjacking attacks. Multiple | Authorization servers MUST prevent clickjacking attacks. Multiple | |||
countermeasures are described in [RFC6819], including the use of the | countermeasures are described in [RFC6819], including the use of the | |||
X-Frame-Options HTTP response header field and frame-busting | X-Frame-Options HTTP response header field and frame-busting | |||
JavaScript. In addition to those, authorization servers SHOULD also | JavaScript. In addition to those, authorization servers SHOULD also | |||
skipping to change at page 45, line 34 ¶ | skipping to change at line 2099 ¶ | |||
authorize the client (e.g., the device authorization endpoint, login | authorize the client (e.g., the device authorization endpoint, login | |||
pages, error pages, etc.). This prevents framing by unauthorized | pages, error pages, etc.). This prevents framing by unauthorized | |||
origins in user agents that support CSP. The client MAY permit being | origins in user agents that support CSP. The client MAY permit being | |||
framed by some other origin than the one used in its redirection | framed by some other origin than the one used in its redirection | |||
endpoint. For this reason, authorization servers SHOULD allow | endpoint. For this reason, authorization servers SHOULD allow | |||
administrators to configure allowed origins for particular clients | administrators to configure allowed origins for particular clients | |||
and/or for clients to register these dynamically. | and/or for clients to register these dynamically. | |||
Using CSP allows authorization servers to specify multiple origins in | Using CSP allows authorization servers to specify multiple origins in | |||
a single response header field and to constrain these using flexible | a single response header field and to constrain these using flexible | |||
patterns (see [W3C.CSP-2] for details). Level 2 of this standard | patterns (see [W3C.CSP-2] for details). Level 2 of CSP provides a | |||
provides a robust mechanism for protecting against clickjacking by | robust mechanism for protecting against clickjacking by using | |||
using policies that restrict the origin of frames (using frame- | policies that restrict the origin of frames (by using frame- | |||
ancestors) together with those that restrict the sources of scripts | ancestors) together with those that restrict the sources of scripts | |||
allowed to execute on an HTML page (by using script-src). A non- | allowed to execute on an HTML page (by using script-src). A non- | |||
normative example of such a policy is shown in the following listing: | normative example of such a policy is shown in the following listing: | |||
HTTP/1.1 200 OK | HTTP/1.1 200 OK | |||
Content-Security-Policy: frame-ancestors https://ext.example.org:8000 | Content-Security-Policy: frame-ancestors https://ext.example.org:8000 | |||
Content-Security-Policy: script-src 'self' | Content-Security-Policy: script-src 'self' | |||
X-Frame-Options: ALLOW-FROM https://ext.example.org:8000 | X-Frame-Options: ALLOW-FROM https://ext.example.org:8000 | |||
... | ... | |||
skipping to change at page 46, line 15 ¶ | skipping to change at line 2128 ¶ | |||
4.17. Attacks on In-Browser Communication Flows | 4.17. Attacks on In-Browser Communication Flows | |||
If the authorization response is sent with in-browser communication | If the authorization response is sent with in-browser communication | |||
techniques like postMessage [WHATWG.postmessage_api] instead of HTTP | techniques like postMessage [WHATWG.postmessage_api] instead of HTTP | |||
redirects, messages may inadvertently be sent to malicious origins or | redirects, messages may inadvertently be sent to malicious origins or | |||
injected from malicious origins. | injected from malicious origins. | |||
4.17.1. Examples | 4.17.1. Examples | |||
The following non-normative pseudocode examples of attacks using in- | The following non-normative pseudocode examples of attacks using in- | |||
browser communication are described in [research.rub]: | browser communication are described in [research.rub]. | |||
4.17.1.1. Insufficient Limitation of Receiver Origins | 4.17.1.1. Insufficient Limitation of Receiver Origins | |||
When sending the authorization response or token response via | When sending the authorization response or token response via | |||
postMessage, the authorization server sends the response to the | postMessage, the authorization server sends the response to the | |||
wildcard origin "*" instead of the client's origin. When the window | wildcard origin "*" instead of the client's origin. When the window | |||
to which the response is sent is controlled by an attacker, the | to which the response is sent is controlled by an attacker, the | |||
attacker can read the response. | attacker can read the response. | |||
window.opener.postMessage( | window.opener.postMessage( | |||
skipping to change at page 46, line 37 ¶ | skipping to change at line 2150 ¶ | |||
code: "ABC", | code: "ABC", | |||
state: "123" | state: "123" | |||
}, | }, | |||
"*" // any website in the opener window can receive the message | "*" // any website in the opener window can receive the message | |||
) | ) | |||
4.17.1.2. Insufficient URI Validation | 4.17.1.2. Insufficient URI Validation | |||
When sending the authorization response or token response via | When sending the authorization response or token response via | |||
postMessage, the authorization server may not check the receiver | postMessage, the authorization server may not check the receiver | |||
origin against the redirect URI and instead, for example, send the | origin against the redirection URI and instead, for example, may send | |||
response to an origin provided by an attacker. This is analogous to | the response to an origin provided by an attacker. This is analogous | |||
the attack described in Section 4.1. | to the attack described in Section 4.1. | |||
window.opener.postMessage( | window.opener.postMessage( | |||
{ | { | |||
code: "ABC", | code: "ABC", | |||
state: "123" | state: "123" | |||
}, | }, | |||
"https://attacker.example" // attacker-provided value | "https://attacker.example" // attacker-provided value | |||
) | ) | |||
4.17.1.3. Injection after Insufficient Validation of Sender Origin | 4.17.1.3. Injection after Insufficient Validation of Sender Origin | |||
skipping to change at page 47, line 20 ¶ | skipping to change at line 2177 ¶ | |||
token response into the client. | token response into the client. | |||
In the case of a maliciously injected authorization response, the | In the case of a maliciously injected authorization response, the | |||
attack is a variant of the CSRF attacks described in Section 4.7. | attack is a variant of the CSRF attacks described in Section 4.7. | |||
The countermeasures described in Section 4.7 apply to this attack as | The countermeasures described in Section 4.7 apply to this attack as | |||
well. | well. | |||
In the case of a maliciously injected token response, sender- | In the case of a maliciously injected token response, sender- | |||
constrained access tokens as described in Section 4.10.1 may prevent | constrained access tokens as described in Section 4.10.1 may prevent | |||
the attack under some circumstances, but additional countermeasures | the attack under some circumstances, but additional countermeasures | |||
as described next are generally required. | as described in Section 4.17.2 are generally required. | |||
4.17.2. Recommendations | 4.17.2. Recommendations | |||
When comparing client receiver origins against pre-registered | When comparing client receiver origins against pre-registered | |||
origins, authorization servers MUST utilize exact string matching as | origins, authorization servers MUST utilize exact string matching as | |||
described in Section 4.1.3. Authorization servers MUST send | described in Section 4.1.3. Authorization servers MUST send | |||
postMessages to trusted client receiver origins, as shown in the | postMessages to trusted client receiver origins, as shown in the | |||
following, non-normative example: | following, non-normative example: | |||
window.opener.postMessage( | window.opener.postMessage( | |||
{ | { | |||
code: "ABC", | code: "ABC", | |||
state: "123" | state: "123" | |||
}, | }, | |||
"https://client.example" // use explicit client origin | "https://client.example" // use explicit client origin | |||
) | ) | |||
Wildcard origins like "*" in postMessage MUST NOT be used as | Wildcard origins like "*" in postMessage MUST NOT be used, as | |||
attackers can use them to leak a victim's in-browser message to | attackers can use them to leak a victim's in-browser message to | |||
malicious origins. Both measures contribute to the prevention of | malicious origins. Both measures contribute to the prevention of | |||
leakage of authorization codes and access tokens (see Section 4.1). | leakage of authorization codes and access tokens (see Section 4.1). | |||
Clients MUST prevent injection of in-browser messages on the client | Clients MUST prevent injection of in-browser messages on the client | |||
receiver endpoint. Clients MUST utilize exact string matching to | receiver endpoint. Clients MUST utilize exact string matching to | |||
compare the initiator origin of an in-browser message with the | compare the initiator origin of an in-browser message with the | |||
authorization server origin, as shown in the following, non-normative | authorization server origin, as shown in the following, non-normative | |||
example: | example: | |||
skipping to change at page 48, line 17 ¶ | skipping to change at line 2218 ¶ | |||
if (e.origin === "https://honest.as.example") { | if (e.origin === "https://honest.as.example") { | |||
// process e.data.code and e.data.state | // process e.data.code and e.data.state | |||
} | } | |||
}) | }) | |||
Since in-browser communication flows only apply a different | Since in-browser communication flows only apply a different | |||
communication technique (i.e., postMessage instead of HTTP redirect), | communication technique (i.e., postMessage instead of HTTP redirect), | |||
all measures protecting the authorization response listed in | all measures protecting the authorization response listed in | |||
Section 2.1 MUST be applied equally. | Section 2.1 MUST be applied equally. | |||
5. Acknowledgements | 5. IANA Considerations | |||
We would like to thank Brock Allen, Annabelle Richard Backman, | This document has no IANA actions. | |||
Dominick Baier, Vittorio Bertocci, Brian Campbell, Bruno Crispo, | ||||
William Dennis, George Fletcher, Matteo Golinelli, Dick Hardt, Joseph | ||||
Heenan, Pedram Hosseyni, Phil Hunt, Tommaso Innocenti, Louis Jannett, | ||||
Jared Jennings, Michael B. Jones, Engin Kirda, Konstantin Lapine, | ||||
Neil Madden, Christian Mainka, Jim Manico, Nov Matake, Doug McDorman, | ||||
Ali Mirheidari, Vladislav Mladenov, Karsten Meyer zu Selhausen, Kaan | ||||
Onarioglu, Aaron Parecki, Michael Peck, Johan Peeters, Nat Sakimura, | ||||
Guido Schmitz, Jörg Schwenk, Rifaat Shekh-Yusef, Travis Spencer, | ||||
Petteri Stenius, Tomek Stojecki, Tim Wuertele, David Waite and Hans | ||||
Zandbelt for their valuable feedback. | ||||
6. IANA Considerations | 6. Security Considerations | |||
This draft makes no requests to IANA. | Security considerations are described in Sections 2, 3, and 4. | |||
7. Security Considerations | 7. References | |||
Security considerations are described in Section 2, Section 3, and | 7.1. Normative References | |||
Section 4. | ||||
8. References | [BCP195] Best Current Practice 195, | |||
<https://www.rfc-editor.org/info/bcp195>. | ||||
At the time of writing, this BCP comprises the following: | ||||
8.1. Normative References | Moriarty, K. and S. Farrell, "Deprecating TLS 1.0 and TLS | |||
1.1", BCP 195, RFC 8996, DOI 10.17487/RFC8996, March 2021, | ||||
<https://www.rfc-editor.org/info/rfc8996>. | ||||
[BCP195] IETF, "BCP195", <https://www.rfc-editor.org/info/bcp195>. | Sheffer, Y., Saint-Andre, P., and T. Fossati, | |||
"Recommendations for Secure Use of Transport Layer | ||||
Security (TLS) and Datagram Transport Layer Security | ||||
(DTLS)", BCP 195, RFC 9325, DOI 10.17487/RFC9325, November | ||||
2022, <https://www.rfc-editor.org/info/rfc9325>. | ||||
[RFC3986] Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform | [RFC3986] Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform | |||
Resource Identifier (URI): Generic Syntax", STD 66, | Resource Identifier (URI): Generic Syntax", STD 66, | |||
RFC 3986, DOI 10.17487/RFC3986, January 2005, | RFC 3986, DOI 10.17487/RFC3986, January 2005, | |||
<https://www.rfc-editor.org/info/rfc3986>. | <https://www.rfc-editor.org/info/rfc3986>. | |||
[RFC6749] Hardt, D., Ed., "The OAuth 2.0 Authorization Framework", | [RFC6749] Hardt, D., Ed., "The OAuth 2.0 Authorization Framework", | |||
RFC 6749, DOI 10.17487/RFC6749, October 2012, | RFC 6749, DOI 10.17487/RFC6749, October 2012, | |||
<https://www.rfc-editor.org/info/rfc6749>. | <https://www.rfc-editor.org/info/rfc6749>. | |||
skipping to change at page 49, line 48 ¶ | skipping to change at line 2292 ¶ | |||
[RFC8705] Campbell, B., Bradley, J., Sakimura, N., and T. | [RFC8705] Campbell, B., Bradley, J., Sakimura, N., and T. | |||
Lodderstedt, "OAuth 2.0 Mutual-TLS Client Authentication | Lodderstedt, "OAuth 2.0 Mutual-TLS Client Authentication | |||
and Certificate-Bound Access Tokens", RFC 8705, | and Certificate-Bound Access Tokens", RFC 8705, | |||
DOI 10.17487/RFC8705, February 2020, | DOI 10.17487/RFC8705, February 2020, | |||
<https://www.rfc-editor.org/info/rfc8705>. | <https://www.rfc-editor.org/info/rfc8705>. | |||
[RFC9068] Bertocci, V., "JSON Web Token (JWT) Profile for OAuth 2.0 | [RFC9068] Bertocci, V., "JSON Web Token (JWT) Profile for OAuth 2.0 | |||
Access Tokens", RFC 9068, DOI 10.17487/RFC9068, October | Access Tokens", RFC 9068, DOI 10.17487/RFC9068, October | |||
2021, <https://www.rfc-editor.org/info/rfc9068>. | 2021, <https://www.rfc-editor.org/info/rfc9068>. | |||
8.2. Informative References | 7.2. Informative References | |||
[I-D.bradley-oauth-jwt-encoded-state] | [arXiv.1508.04324v2] | |||
Mladenov, V., Mainka, C., and J. Schwenk, "On the security | ||||
of modern Single Sign-On Protocols: Second-Order | ||||
Vulnerabilities in OpenID Connect", arXiv:1508.04324v2, | ||||
DOI 10.48550/arXiv.1508.04324, 7 January 2016, | ||||
<https://arxiv.org/abs/1508.04324v2/>. | ||||
[arXiv.1601.01229] | ||||
Fett, D., Küsters, R., and G. Schmitz, "A Comprehensive | ||||
Formal Security Analysis of OAuth 2.0", arXiv:1601.01229, | ||||
DOI 10.48550/arXiv.1601.01229, 6 January 2016, | ||||
<https://arxiv.org/abs/1601.01229/>. | ||||
[arXiv.1704.08539] | ||||
Fett, D., Küsters, R., and G. Schmitz, "The Web SSO | ||||
Standard OpenID Connect: In-Depth Formal Security Analysis | ||||
and Security Guidelines", arXiv:1704.08539, | ||||
DOI 10.48550/arXiv.1704.08539, 27 April 2017, | ||||
<https://arxiv.org/abs/1704.08539/>. | ||||
[arXiv.1901.11520] | ||||
Fett, D., Hosseyni, P., and R. Küsters, "An Extensive | ||||
Formal Security Analysis of the OpenID Financial-grade | ||||
API", arXiv:1901.11520, DOI 10.48550/arXiv.1901.11520, 31 | ||||
January 2019, <https://arxiv.org/abs/1901.11520/>. | ||||
[bug.chromium] | ||||
"Referer header includes URL fragment when opening link | ||||
using New Tab", Chromium Issue Tracker, Issue ID: | ||||
40076763, <https://issues.chromium.org/issues/40076763>. | ||||
[JWT-ENCODED-STATE] | ||||
Bradley, J., Lodderstedt, T., and H. Zandbelt, "Encoding | Bradley, J., Lodderstedt, T., and H. Zandbelt, "Encoding | |||
claims in the OAuth 2 state parameter using a JWT", Work | claims in the OAuth 2 state parameter using a JWT", Work | |||
in Progress, Internet-Draft, draft-bradley-oauth-jwt- | in Progress, Internet-Draft, draft-bradley-oauth-jwt- | |||
encoded-state-09, 4 November 2018, | encoded-state-09, 4 November 2018, | |||
<https://datatracker.ietf.org/doc/html/draft-bradley- | <https://datatracker.ietf.org/doc/html/draft-bradley- | |||
oauth-jwt-encoded-state-09>. | oauth-jwt-encoded-state-09>. | |||
[I-D.ietf-oauth-token-binding] | [OAUTH-V2.1] | |||
Jones, M., Campbell, B., Bradley, J., and W. Denniss, | ||||
"OAuth 2.0 Token Binding", Work in Progress, Internet- | ||||
Draft, draft-ietf-oauth-token-binding-08, 19 October 2018, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-oauth- | ||||
token-binding-08>. | ||||
[I-D.ietf-oauth-v2-1] | ||||
Hardt, D., Parecki, A., and T. Lodderstedt, "The OAuth 2.1 | Hardt, D., Parecki, A., and T. Lodderstedt, "The OAuth 2.1 | |||
Authorization Framework", Work in Progress, Internet- | Authorization Framework", Work in Progress, Internet- | |||
Draft, draft-ietf-oauth-v2-1-11, 14 May 2024, | Draft, draft-ietf-oauth-v2-1-12, 15 November 2024, | |||
<https://datatracker.ietf.org/doc/html/draft-ietf-oauth- | <https://datatracker.ietf.org/doc/html/draft-ietf-oauth- | |||
v2-1-11>. | v2-1-12>. | |||
[OAuth.Post] | [OAuth.Post] | |||
Jones, M. and B. Campbell, "OAuth 2.0 Form Post Response | Jones, M. and B. Campbell, "OAuth 2.0 Form Post Response | |||
Mode", 27 April 2015, <https://openid.net/specs/oauth-v2- | Mode", The OpenID Foundation, 27 April 2015, | |||
form-post-response-mode-1_0.html>. | <https://openid.net/specs/oauth-v2-form-post-response- | |||
mode-1_0.html>. | ||||
[OAuth.Responses] | [OAuth.Responses] | |||
de Medeiros, B., Scurtescu, M., Tarjan, P., and M. Jones, | de Medeiros, B., Ed., Scurtescu, M., Tarjan, P., and M. | |||
"OAuth 2.0 Multiple Response Type Encoding Practices", 25 | Jones, "OAuth 2.0 Multiple Response Type Encoding | |||
February 2014, <https://openid.net/specs/oauth-v2- | Practices", The OpenID Foundation, 25 February 2014, | |||
multiple-response-types-1_0.html>. | <https://openid.net/specs/oauth-v2-multiple-response- | |||
types-1_0.html>. | ||||
[OpenID.Core] | [OpenID.Core] | |||
Sakimura, N., Bradley, J., Jones, M., de Medeiros, B., and | Sakimura, N., Bradley, J., Jones, M., de Medeiros, B., and | |||
C. Mortimore, "OpenID Connect Core 1.0 incorporating | C. Mortimore, "OpenID Connect Core 1.0 incorporating | |||
errata set 2", 15 December 2023, | errata set 2", The OpenID Foundation, 15 December 2023, | |||
<https://openid.net/specs/openid-connect-core-1_0.html>. | <https://openid.net/specs/openid-connect-core-1_0.html>. | |||
[OpenID.Discovery] | [OpenID.Discovery] | |||
Sakimura, N., Bradley, J., Jones, M., and E. Jay, "OpenID | Sakimura, N., Bradley, J., Jones, M., and E. Jay, "OpenID | |||
Connect Discovery 1.0 incorporating errata set 2", 15 | Connect Discovery 1.0 incorporating errata set 2", The | |||
December 2023, <https://openid.net/specs/openid-connect- | OpenID Foundation, 15 December 2023, | |||
discovery-1_0.html>. | <https://openid.net/specs/openid-connect-discovery- | |||
1_0.html>. | ||||
[OpenID.JARM] | [OpenID.JARM] | |||
Lodderstedt, T. and B. Campbell, "Financial-grade API: JWT | Lodderstedt, T. and B. Campbell, "Financial-grade API: JWT | |||
Secured Authorization Response Mode for OAuth 2.0 (JARM)", | Secured Authorization Response Mode for OAuth 2.0 (JARM)", | |||
17 October 2018, | The OpenID Foundation, 17 October 2018, | |||
<https://openid.net/specs/openid-financial-api-jarm.html>. | <https://openid.net/specs/openid-financial-api-jarm.html>. | |||
[owasp.redir] | ||||
OWASP Foundation, "Unvalidated Redirects and Forwards | ||||
Cheat Sheet", OWASP Cheat Sheet Series, | ||||
<https://cheatsheetseries.owasp.org/cheatsheets/ | ||||
Unvalidated_Redirects_and_Forwards_Cheat_Sheet.html>. | ||||
[research.cmu] | ||||
Chen, E., Pei, Y., Chen, S., Tian, Y., Kotcher, R., and P. | ||||
Tague, "OAuth Demystified for Mobile Application | ||||
Developers", CCS '14: Proceedings of the 2014 ACM SIGSAC | ||||
Conference on Computer and Communications Security, pp. | ||||
892-903, DOI 10.1145/2660267.2660323, November 2014, | ||||
<https://www.microsoft.com/en-us/research/wp- | ||||
content/uploads/2016/02/OAuthDemystified.pdf>. | ||||
[research.jcs_14] | ||||
Bansal, C., Bhargavan, K., Delignat-Lavaud, A., and S. | ||||
Maffeis, "Discovering concrete attacks on website | ||||
authorization by formal analysis", Journal of Computer | ||||
Security, vol. 22, no. 4, pp. 601-657, DOI 10.3233/JCS- | ||||
140503, 23 April 2014, | ||||
<https://www.doc.ic.ac.uk/~maffeis/papers/jcs14.pdf>. | ||||
[research.rub] | ||||
Jannett, L., Mladenov, V., Mainka, C., and J. Schwenk, | ||||
"DISTINCT: Identity Theft using In-Browser Communications | ||||
in Dual-Window Single Sign-On", CCS '22: Proceedings of | ||||
the 2022 ACM SIGSAC Conference on Computer and | ||||
Communications Security, DOI 10.1145/3548606.3560692, 7 | ||||
November 2022, | ||||
<https://dl.acm.org/doi/pdf/10.1145/3548606.3560692>. | ||||
[research.rub2] | ||||
Fries, C., "Security Analysis of Real-Life OpenID Connect | ||||
Implementations", Master's thesis, Ruhr-Universität Bochum | ||||
(RUB), 20 December 2020, | ||||
<https://www.nds.rub.de/media/ei/arbeiten/2021/05/03/ | ||||
masterthesis.pdf>. | ||||
[research.ubc] | ||||
Sun, S.-T. and K. Beznosov, "The Devil is in the | ||||
(Implementation) Details: An Empirical Analysis of OAuth | ||||
SSO Systems", Proceedings of the 2012 ACM conference on | ||||
Computer and communications security (CCS '12), pp. | ||||
378-390, DOI 10.1145/2382196.2382238, October 2012, | ||||
<https://css.csail.mit.edu/6.858/2012/readings/oauth- | ||||
sso.pdf>. | ||||
[research.udel] | ||||
Liu, D., Hao, S., and H. Wang, "All Your DNS Records Point | ||||
to Us: Understanding the Security Threats of Dangling DNS | ||||
Records", CCS '16: Proceedings of the 2016 ACM SIGSAC | ||||
Conference on Computer and Communications Security, pp. | ||||
1414-1425, DOI 10.1145/2976749.2978387, 24 October 2016, | ||||
<https://dl.acm.org/doi/pdf/10.1145/2976749.2978387>. | ||||
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate | [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate | |||
Requirement Levels", BCP 14, RFC 2119, | Requirement Levels", BCP 14, RFC 2119, | |||
DOI 10.17487/RFC2119, March 1997, | DOI 10.17487/RFC2119, March 1997, | |||
<https://www.rfc-editor.org/info/rfc2119>. | <https://www.rfc-editor.org/info/rfc2119>. | |||
[RFC7591] Richer, J., Ed., Jones, M., Bradley, J., Machulak, M., and | [RFC7591] Richer, J., Ed., Jones, M., Bradley, J., Machulak, M., and | |||
P. Hunt, "OAuth 2.0 Dynamic Client Registration Protocol", | P. Hunt, "OAuth 2.0 Dynamic Client Registration Protocol", | |||
RFC 7591, DOI 10.17487/RFC7591, July 2015, | RFC 7591, DOI 10.17487/RFC7591, July 2015, | |||
<https://www.rfc-editor.org/info/rfc7591>. | <https://www.rfc-editor.org/info/rfc7591>. | |||
skipping to change at page 52, line 14 ¶ | skipping to change at line 2485 ¶ | |||
[RFC9440] Campbell, B. and M. Bishop, "Client-Cert HTTP Header | [RFC9440] Campbell, B. and M. Bishop, "Client-Cert HTTP Header | |||
Field", RFC 9440, DOI 10.17487/RFC9440, July 2023, | Field", RFC 9440, DOI 10.17487/RFC9440, July 2023, | |||
<https://www.rfc-editor.org/info/rfc9440>. | <https://www.rfc-editor.org/info/rfc9440>. | |||
[RFC9449] Fett, D., Campbell, B., Bradley, J., Lodderstedt, T., | [RFC9449] Fett, D., Campbell, B., Bradley, J., Lodderstedt, T., | |||
Jones, M., and D. Waite, "OAuth 2.0 Demonstrating Proof of | Jones, M., and D. Waite, "OAuth 2.0 Demonstrating Proof of | |||
Possession (DPoP)", RFC 9449, DOI 10.17487/RFC9449, | Possession (DPoP)", RFC 9449, DOI 10.17487/RFC9449, | |||
September 2023, <https://www.rfc-editor.org/info/rfc9449>. | September 2023, <https://www.rfc-editor.org/info/rfc9449>. | |||
[TOKEN-BINDING] | ||||
Jones, M., Campbell, B., Bradley, J., and W. Denniss, | ||||
"OAuth 2.0 Token Binding", Work in Progress, Internet- | ||||
Draft, draft-ietf-oauth-token-binding-08, 19 October 2018, | ||||
<https://datatracker.ietf.org/doc/html/draft-ietf-oauth- | ||||
token-binding-08>. | ||||
[W3C.CSP-2] | [W3C.CSP-2] | |||
West, M., Barth, A., and D. Veditz, "Content Security | West, M., Barth, A., and D. Veditz, "Content Security | |||
Policy Level 2", July 2015, <https://www.w3.org/TR/CSP2>. | Policy Level 2", W3C Recommendation, December 2016, | |||
<https://www.w3.org/TR/2016/REC-CSP2-20161215/>. Latest | ||||
version available at <https://www.w3.org/TR/CSP2/>. | ||||
[W3C.webappsec-referrer-policy] | ||||
Eisinger, J. and E. Stark, "Referrer Policy", 26 January | ||||
2017, | ||||
<https://www.w3.org/TR/2017/CR-referrer-policy-20170126/>. | ||||
Latest version available at | ||||
<https://www.w3.org/TR/referrer-policy/>. | ||||
[W3C.WebAuthn] | [W3C.WebAuthn] | |||
Hodges, J., Jones, J.C., Jones, M.B., Kumar, A., and E. | Hodges, J., Jones, J.C., Jones, M.B., Kumar, A., and E. | |||
Lundberg, "Web Authentication: An API for accessing Public | Lundberg, "Web Authentication: An API for accessing Public | |||
Key Credentials Level 2", 8 April 2021, | Key Credentials Level 2", W3C Recommendation, 8 April | |||
2021, | ||||
<https://www.w3.org/TR/2021/REC-webauthn-2-20210408/>. | <https://www.w3.org/TR/2021/REC-webauthn-2-20210408/>. | |||
Latest version available at | ||||
<https://www.w3.org/TR/webauthn-2/>. | ||||
[W3C.WebCrypto] | [W3C.WebCrypto] | |||
Watson, M., "Web Cryptography API", 26 January 2017, | Watson, M., Ed., "Web Cryptography API", W3C | |||
Recommendation, 26 January 2017, | ||||
<https://www.w3.org/TR/2017/REC-WebCryptoAPI-20170126/>. | <https://www.w3.org/TR/2017/REC-WebCryptoAPI-20170126/>. | |||
Latest version available at | ||||
[W3C.webappsec-referrer-policy] | <https://www.w3.org/TR/WebCryptoAPI/>. | |||
Eisinger, J. and E. Stark, "Referrer Policy", 20 April | ||||
2017, <https://w3c.github.io/webappsec-referrer-policy>. | ||||
[WHATWG.CORS] | [WHATWG.CORS] | |||
"Fetch Standard: CORS protocol", | WHATWG, "CORS protocol", Fetch: Living Standard, | |||
Section 3.2, 17 June 2024, | ||||
<https://fetch.spec.whatwg.org/#http-cors-protocol>. | <https://fetch.spec.whatwg.org/#http-cors-protocol>. | |||
[WHATWG.postmessage_api] | [WHATWG.postmessage_api] | |||
"HTML Living Standard: Cross-document messaging", | WHATWG, "Cross-document messaging", HTML: Living Standard, | |||
Section 9.3, 19 August 2024, | ||||
<https://html.spec.whatwg.org/multipage/web- | <https://html.spec.whatwg.org/multipage/web- | |||
messaging.html#web-messaging>. | messaging.html#web-messaging>. | |||
[arXiv.1508.04324v2] | Acknowledgements | |||
Mladenov, V., Mainka, C., and J. Schwenk, "On the security | ||||
of modern Single Sign-On Protocols: Second-Order | ||||
Vulnerabilities in OpenID Connect", arXiv 1508.04324v2, 7 | ||||
January 2016, <https://arxiv.org/abs/1508.04324v2/>. | ||||
[arXiv.1601.01229] | ||||
Fett, D., Küsters, R., and G. Schmitz, "A Comprehensive | ||||
Formal Security Analysis of OAuth 2.0", arXiv 1601.01229, | ||||
6 January 2016, <https://arxiv.org/abs/1601.01229/>. | ||||
[arXiv.1704.08539] | ||||
Fett, D., Küsters, R., and G. Schmitz, "The Web SSO | ||||
Standard OpenID Connect: In-Depth Formal Security Analysis | ||||
and Security Guidelines", arXiv 1704.08539, 27 April 2017, | ||||
<https://arxiv.org/abs/1704.08539/>. | ||||
[arXiv.1901.11520] | ||||
Fett, D., Hosseyni, P., and R. Küsters, "An Extensive | ||||
Formal Security Analysis of the OpenID Financial-grade | ||||
API", arXiv 1901.11520, 31 January 2019, | ||||
<https://arxiv.org/abs/1901.11520/>. | ||||
[bug.chromium] | ||||
"Referer header includes URL fragment when opening link | ||||
using New Tab", | ||||
<https://issues.chromium.org/issues/40076763>. | ||||
[owasp.redir] | ||||
"OWASP Cheat Sheet Series - Unvalidated Redirects and | ||||
Forwards", | ||||
<https://cheatsheetseries.owasp.org/cheatsheets/ | ||||
Unvalidated_Redirects_and_Forwards_Cheat_Sheet.html>. | ||||
[research.cmu] | ||||
Chen, E., Pei, Y., Chen, S., Tian, Y., Kotcher, R., and P. | ||||
Tague, "OAuth Demystified for Mobile Application | ||||
Developers", November 2014, | ||||
<https://css.csail.mit.edu/6.858/2012/readings/oauth- | ||||
sso.pdf>. | ||||
[research.jcs_14] | ||||
Bansal, C., Bhargavan, K., Delignat-Lavaud, A., and S. | ||||
Maffeis, "Discovering concrete attacks on website | ||||
authorization by formal analysis", 23 April 2014, | ||||
<https://www.doc.ic.ac.uk/~maffeis/papers/jcs14.pdf>. | ||||
[research.rub] | ||||
Jannett, L., Mladenov, V., Mainka, C., and J. Schwenk, | ||||
"DISTINCT: Identity Theft using In-Browser Communications | ||||
in Dual-Window Single Sign-On", | ||||
DOI 10.1145/3548606.3560692, 7 November 2022, | ||||
<https://distinct-sso.com/paper.pdf>. | ||||
[research.rub2] | ||||
Fries, C., "Security Analysis of Real-Life OpenID Connect | ||||
Implementations", 20 December 2020, | ||||
<https://www.nds.rub.de/media/ei/arbeiten/2021/05/03/ | ||||
masterthesis.pdf>. | ||||
[research.ubc] | ||||
Sun, S.-T. and K. Beznosov, "The Devil is in the | ||||
(Implementation) Details: An Empirical Analysis of OAuth | ||||
SSO Systems", October 2012, | ||||
<https://passwordresearch.com/papers/paper267.html>. | ||||
[research.udel] | ||||
Liu, D., Hao, S., and H. Wang, "All Your DNS Records Point | ||||
to Us: Understanding the Security Threats of Dangling DNS | ||||
Records", 24 October 2016, | ||||
<https://www.eecis.udel.edu/~hnw/paper/ccs16a.pdf>. | ||||
Appendix A. Document History | ||||
[[ To be removed from the final specification ]] | ||||
-29 | ||||
* Fix broken reference | ||||
-28 | ||||
* Various editorial fixes | ||||
* Address feedback from IESG ballot | ||||
-27 | ||||
* Mostly editorial feedback from Microsoft incorporated | ||||
* Feedback from SECDIR review incorporated | ||||
-26 | ||||
* Feedback from ARTART review incorporated | ||||
* Gen-ART review (typo fixes) | ||||
-25 | ||||
* Shepherd's writeup feedback: Removed discussion on outdated POP | ||||
approaches | ||||
* Shepherd's writeup feedback: Clarify relationship to other | ||||
document. | ||||
* Shepherd's writeup feedback: Expand abbreviations | ||||
* Shepherd's writeup feedback: Better explain attacker model | ||||
* Shepherd's writeup feedback: Various editorial changes | ||||
* AD review: Mention updated documents in abstract | ||||
* AD review: Fix HTTP reference | ||||
* AD review: Clarification in the attacker model | ||||
* AD review: Various editorial and minor changes | ||||
-24 | ||||
* Some feedback from shepherd's writeup incorporated | ||||
* Cleaned up references | ||||
* Clarification on mix-up attack | ||||
* Add researcher names to acknowledgements | ||||
* Removed sentence stating that only MTLS is standardized; DPoP is | ||||
now as well | ||||
-23 | ||||
* Added CORS considerations | ||||
* Reworded Section 4.15.1 to be more in line with OAuth 2.1 | ||||
* Editorial changes | ||||
* Clarifications and updated references | ||||
-22 | ||||
* Added section on securing in-browser communication | ||||
* Merged section on phishing via AS into existing section on open | ||||
redirectors | ||||
* Restructure and move section on sender-constrained tokens | ||||
* Mention RFCs for Private Key JWK method | ||||
-21 | ||||
* Improved wording on phishing via AS | ||||
-20 | ||||
* Improved description of authorization code injection attacks and | ||||
PKCE protection | ||||
* Removed recommendation for MTLS in discussion (not reflected in | ||||
actual Recommendations section) | ||||
* Reworded "placeholder" text in security considerations. | ||||
* Alphabetized list of names and fixed unicode problem | ||||
* Explained Clickjacking | ||||
* Explained Open Redirectors | ||||
* Clarified references to attacker model by including a link to | ||||
Section 3 | ||||
* Clarified description of "CSRF tokens" and reference to RFC6819 | ||||
* Described that OIDC can prevent access token injection | ||||
* Updated references | ||||
-19 | ||||
* Changed affiliation of Andrey Labunets | ||||
* Editorial change to clarify the new recommendations for refresh | ||||
tokens | ||||
-18 | ||||
* Fix editorial and spelling issues. | ||||
* Change wording for disallowing HTTP redirect URIs. | ||||
-17 | ||||
* Make the use of metadata RECOMMENDED for both servers and clients | ||||
* Make announcing PKCE support in metadata the RECOMMENDED way | ||||
(before: either metadata or deployment-specific way) | ||||
* AS also MUST NOT expose open redirectors. | ||||
* Mention that attackers can collaborate. | ||||
* Update recommendations regarding mix-up defense, building upon | ||||
[RFC9207]. | ||||
* Improve description of mix-up attack. | ||||
* Make HTTPS mandatory for most redirect URIs. | ||||
-16 | ||||
* Make MTLS a suggestion instead of RECOMMENDED. | ||||
* Add important requirements when using nonce for code injection | ||||
protection. | ||||
* Highlight requirements for refresh token sender-constraining. | ||||
* Make PKCE a MUST for public clients. | ||||
* Describe PKCE Downgrade Attacks and countermeasures. | ||||
* Allow variable port numbers in localhost redirect URIs as in | ||||
RFC8252, Section 7.3. | ||||
-15 | ||||
* Update reference to DPoP | ||||
* Fix reference to RFC8414 | ||||
* Move to xml2rfcv3 | ||||
-14 | ||||
* Added info about using CSP to prevent clickjacking | ||||
* Changes from WGLC feedback | ||||
* Editorial changes | ||||
* AS MUST announce PKCE support either in metadata or using | ||||
deployment-specific ways (before: SHOULD) | ||||
-13 | ||||
* Discourage use of Resource Owner Password Credentials Grant | ||||
* Added text on client impersonating resource owner | ||||
* Recommend asymmetric methods for client authentication | ||||
* Encourage use of PKCE mode "S256" | ||||
* PKCE may replace state for CSRF protection | ||||
* AS SHOULD publish PKCE support | ||||
* Cleaned up discussion on auth code injection | ||||
* AS MUST support PKCE | ||||
-12 | ||||
* Added updated attacker model | ||||
-11 | ||||
* Adapted section 2.1.2 to outcome of consensus call | ||||
* more text on refresh token inactivity and implementation note on | ||||
refresh token replay detection via refresh token rotation | ||||
-10 | ||||
* incorporated feedback by Joseph Heenan | ||||
* changed occurrences of SHALL to MUST | ||||
* added text on lack of token/cert binding support tokens issued in | ||||
the authorization response as justification to not recommend | ||||
issuing tokens there at all | ||||
* added requirement to authenticate clients during code exchange | ||||
(PKCE or client credential) to 2.1.1. | ||||
* added section on refresh tokens | ||||
* editorial enhancements to 2.1.2 based on feedback | ||||
-09 | ||||
* changed text to recommend not to use implicit but code | ||||
* added section on access token injection | ||||
* reworked sections 3.1 through 3.3 to be more specific on implicit | ||||
grant issues | ||||
-08 | ||||
* added recommendations re implicit and token injection | ||||
* uppercased key words in Section 2 according to RFC 2119 | ||||
-07 | ||||
* incorporated findings of Doug McDorman | ||||
* added section on HTTP status codes for redirects | ||||
* added new section on access token privilege restriction based on | ||||
comments from Johan Peeters | ||||
-06 | ||||
* reworked section 3.8.1 | ||||
* incorporated Phil Hunt's feedback | ||||
* reworked section on mix-up | ||||
* extended section on code leakage via referrer header to also cover | ||||
state leakage | ||||
* added Daniel Fett as author | ||||
* replaced text intended to inform WG discussion by recommendations | ||||
to implementors | ||||
* modified example URLs to conform to RFC 2606 | ||||
-05 | ||||
* Completed sections on code leakage via referrer header, attacks in | ||||
browser, mix-up, and CSRF | ||||
* Reworked Code Injection Section | ||||
* Added reference to OpenID Connect spec | ||||
* removed refresh token leakage as respective considerations have | ||||
been given in section 10.4 of RFC 6749 | ||||
* first version on open redirection | ||||
* incorporated Christian Mainka's review feedback | ||||
-04 | ||||
* Restructured document for better readability | ||||
* Added best practices on Token Leakage prevention | ||||
-03 | ||||
* Added section on Access Token Leakage at Resource Server | ||||
* incorporated Brian Campbell's findings | ||||
-02 | ||||
* Folded Mix up and Access Token leakage through a bad AS into new | ||||
section for dynamic OAuth threats | ||||
* reworked dynamic OAuth section | ||||
-01 | ||||
* Added references to mitigation methods for token leakage | ||||
* Added reference to Token Binding for Authorization Code | ||||
* incorporated feedback of Phil Hunt | ||||
* fixed numbering issue in attack descriptions in section 2 | ||||
-00 (WG document) | We would like to thank Brock Allen, Annabelle Richard Backman, | |||
* turned the ID into a WG document and a BCP | Dominick Baier, Vittorio Bertocci, Brian Campbell, Bruno Crispo, | |||
* Added federated app login as topic in Other Topics | William Dennis, George Fletcher, Matteo Golinelli, Dick Hardt, Joseph | |||
Heenan, Pedram Hosseyni, Phil Hunt, Tommaso Innocenti, Louis Jannett, | ||||
Jared Jennings, Michael B. Jones, Engin Kirda, Konstantin Lapine, | ||||
Neil Madden, Christian Mainka, Jim Manico, Nov Matake, Doug McDorman, | ||||
Karsten Meyer zu Selhausen, Ali Mirheidari, Vladislav Mladenov, Kaan | ||||
Onarioglu, Aaron Parecki, Michael Peck, Johan Peeters, Nat Sakimura, | ||||
Guido Schmitz, Jörg Schwenk, Rifaat Shekh-Yusef, Travis Spencer, | ||||
Petteri Stenius, Tomek Stojecki, David Waite, Tim Würtele, and Hans | ||||
Zandbelt for their valuable feedback. | ||||
Authors' Addresses | Authors' Addresses | |||
Torsten Lodderstedt | Torsten Lodderstedt | |||
SPRIND | SPRIND | |||
Email: torsten@lodderstedt.net | Email: torsten@lodderstedt.net | |||
John Bradley | John Bradley | |||
Yubico | Yubico | |||
Email: ve7jtb@ve7jtb.com | Email: ve7jtb@ve7jtb.com | |||
End of changes. 212 change blocks. | ||||
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