The OAuth 2.0 Protocol: Bearer TokensMicrosoftmbj@microsoft.comhttp://self-issued.info/independentdick.hardt@gmail.comhttp://dickhardt.org/Facebookdavidrecordon@facebook.comhttp://www.davidrecordon.com/
This specification describes how to use bearer tokens when accessing OAuth 2.0
protected resources.
OAuth enables clients to access protected resources by
obtaining an access token, which is defined in as "a string representing an access
authorization issued to the client", rather than using the
resource owner's credentials.
Tokens are issued to clients by an authorization server with the approval of
the resource owner. The client uses the access token to access the protected resources
hosted by the resource server. This specification describes how to make protected resource
requests by treating an OAuth access token as a bearer token.
This specification defines the use of bearer tokens with OAuth
over HTTP using TLS. Other specifications may extend
it for use with other transport protocols.
The key words 'MUST', 'MUST NOT', 'REQUIRED', 'SHALL', 'SHALL NOT', 'SHOULD', 'SHOULD
NOT', 'RECOMMENDED', 'MAY', and 'OPTIONAL' in this document are to be interpreted as
described in .
This document uses the Augmented Backus-Naur Form (ABNF)
notation of . Additionally, the following rules are included from
: auth-param; and from : RWS.
Unless otherwise noted, all the protocol parameter names and values are case sensitive.
All terms are as defined in The OAuth 2.0 Protocol.
OAuth provides a method for clients to access a protected resource on behalf of a
resource owner. Before a client can access a protected resource, it must first obtain
authorization (access grant) from the resource owner, then exchange the access grant for
an access token (representing the grant's scope, duration, and other attributes). The
client accesses the protected resource by presenting the access token to the resource
server.
The access token provides an abstraction layer, replacing different authorization
constructs (e.g. username and password, assertion) for a single token understood by the
resource server. This abstraction enables issuing access tokens valid for a short time
period, as well as removing the resource server's need to understand a wide range of
authentication schemes.
The abstract flow illustrated in describes the overall
OAuth 2.0 protocol architecture. The following steps are specified within this
document:
E) The client makes a protected resource request to the resource server by presenting
the access token.
F) The resource server validates the access token, and if valid, serves the request.
Clients make authenticated token requests using the
Authorization request header field. Resource servers MUST
accept authenticated requests using the OAuth2 HTTP
authentication scheme as described in , and MAY support
additional methods.
Alternatively, clients MAY attempt to include the access token
in the HTTP body when using the application/x-www-form-urlencoded content
type as described in or using the
HTTP request URI in the query component as described in . Resource servers MAY support these
alternative methods.
Clients SHOULD only use the request body or URI when the
Authorization request header field
is not available, and MUST NOT use more than one method to
transport the token in each request. Because of the Security Considerations associated
with the URI method, it SHOULD only be used if no other method
is feasible.
The Authorization request header field is used by clients
to make authenticated token requests. The client uses the
OAuth2 authentication scheme to include the access token in
the request.
The Authorization header field uses the framework defined by
as follows:
When including the access token in the HTTP request entity-body, the client adds the
access token to the request body using the oauth_token
parameter. The client can use this method only if the following REQUIRED conditions are
met:
The HTTP request entity-body is single-part.
The entity-body follows the encoding requirements of the
application/x-www-form-urlencoded content-type as
defined by .
The HTTP request entity-header includes the Content-Type
header field set to application/x-www-form-urlencoded.
The HTTP request method is one for which a body is
permitted to be present in the request. In particular,
this means that the GET
method MAY NOT be used.
The entity-body can include other request-specific parameters, in which case, the
oauth_token parameters SHOULD be appended following the
request-specific parameters, properly separated by an &
character (ASCII code 38).
The application/x-www-form-urlencoded method
should typically only be used in application contexts where
participating browsers do not have access to the Authorization request header field.
When including the access token in the HTTP request URI, the client adds the access
token to the request URI query component as defined by using
the oauth_token parameter.
The HTTP request URI query can include other request-specific parameters, in which
case, the oauth_token parameters SHOULD be appended
following the request-specific parameters, properly separated by an
& character (ASCII code 38).
Because of the Security
Considerations associated with the URI method, it
SHOULD only be used if no other method is feasible.
This section describes the relevant security threats regarding
token handling when using bearer tokens and describes how to
mitigate these threats.
The following list presents several common threats against
protocols utilizing some form of tokens. This list of
threats is based on NIST Special Publication 800-63 . Since this document builds on the
OAuth 2.0 specification, we exclude a discussion of threats
that are described there or in related documents.
An attacker may generate a bogus token or modify the
token contents (such as the authentication or attribute
statements) of an existing token, causing the resource
server to grant inappropriate access to the client.
For example, an attacker may modify the token to extend
the validity period; a malicious client may modify the
assertion to gain access to information that they
should not be able to view.
Tokens may contain authentication and attribute
statements that include sensitive information.
An attacker uses the token generated for consumption by
resource server to obtain access to another resource
server.
An attacker attempts to use a token that has already
been used once with that resource server in the past.
A large range of threats can be mitigated by protecting the
contents of the token by using a digital signature or a
keyed message digest. Alternatively, the contents of the
token could be passed by reference rather than by value
(requiring a separate message exchange to resolve the
reference to the token contents).
This document does not specify the encoding or the contents
of the token; hence detailed recommendations for token
integrity protection are outside the scope of this document.
We assume that the token integrity protection is sufficient
to prevent the token from being modified.
To deal with token redirect, it is important for the
authorization server to include the identity of the intended
recipients, namely a single resource server (or a list of
resource servers). Restricting the use of the token to a
specific scope is also recommended.
To provide protection against token disclosure,
confidentiality protection is applied via TLS with a
ciphersuite that offers confidentiality protection. This
requires that the communication interaction between the
client and the authorization server, as well as the
interaction between the client and the resource server,
utilize confidentiality protection. Encrypting the token
contents is another alternative. Since TLS is mandatory to
implement and to use with this specification, it is the
preferred approach for preventing token disclosure via the
communication channel. For those rare cases where the client
is prevented from observing the contents of the token, token
encryption has to be applied in addition to the usage of TLS
protection.
To deal with token reuse, the following recommendations are
made: First, the lifetime of the token has to be limited by
putting a validity time field inside the protected part of
the token. Note that using short-lived (one hour or less)
tokens significantly reduces the impact of one of them being
leaked. Second, confidentiality protection of the exchanges
between the client and the authorization server and between
the client and the resource server MUST be applied. As a
consequence, no eavesdropper along the communication path is
able to observe the token exchange. Consequently, such an
on-path adversary cannot replay the token. Furthermore, the
resource server MUST ensure that it only hands out tokens to
clients it has authenticated first and authorized. For this
purpose, the client MUST be authenticated and authorized by
the resource server. The authorization server MUST also
receive a confirmation (the consent of the resource owner)
prior to providing a token to the client. Furthermore, when
presenting the token to a resource server, the client MUST
verify the identity of that resource server. Note that the
client MUST validate the TLS certificate chain when making
these requests to protected resources. Presenting the token
to an unauthenticated and unauthorized resource server or
failing to validate the certificate chain will allow
adversaries to steal the token and gain unauthorized access
to protected resources.
Client implementations MUST ensure that bearer tokens
are not leaked to unintended parties, as they will be
able to use them to gain access to protected resources.
This is the primary security consideration when using
bearer tokens with OAuth and underlies all the more
specific recommendations that follow.
The client must validate the TLS certificate chain when
making requests to protected resources. Failing to do
so may enable DNS hijacking attacks to steal the token
and gain unintended access.
Clients MUST always use TLS (https) when making requests
with bearer tokens. Failing to do so exposes the token
to numerous attacks that could give attackers unintended
access.
As cookies are generally sent in the clear,
implementations MUST NOT store bearer tokens within
them.
Using short-lived (one hour or less) bearer tokens can
reduce the impact of one of them being leaked. The
User-Agent flow should only issue short lived access
tokens.
Browsers may not adequately secure URLs in the browser
history. If bearer tokens are passed in page URLs
(typically as query string parameters), attackers might
be able to steal them from the history data. Instead,
pass browser tokens in message bodies for which
confidentiality measures are taken.
This document neither establishes new IANA registries nor adds
new values to existing registries.
The OAuth 2.0 ProtocolYahoo!eran@hueniverse.comhttp://hueniverse.comFacebookdavidrecordon@facebook.comhttp://www.davidrecordon.com/independentdick.hardt@gmail.comhttp://dickhardt.org/NIST Special Publication 800-63-1, INFORMATION SECURITYNISTNISTNISTNISTNISTNIST
The following people contributed to preliminary versions of this document:
Blaine Cook (BT), Brian Eaton (Google), Yaron Goland (Microsoft), Brent Goldman (Facebook),
Raffi Krikorian (Twitter), Luke Shepard (Facebook), and Allen Tom (Yahoo!). The content and
concepts within are a product of the OAuth community, WRAP community, and the OAuth Working
Group.
The OAuth Working Group has dozens of very active contributors who proposed ideas and
wording for this document, including: [[ If your name is missing or you think someone
should be added here, please send Mike Jones a note - don't be shy! ]]
Michael Adams, Andrew Arnott, Dirk Balfanz, Brian Campbell, Leah Culver, Bill de hÓra,
Brian Ellin, Igor Faynberg, George Fletcher, Tim Freeman, Evan Gilbert, Justin Hart,
John Kemp, Eran Hammer-Lahav, Chasen Le Hara, Michael B. Jones, Torsten Lodderstedt,
Eve Maler, James Manger, Laurence Miao,
Chuck Mortimore, Justin Richer, Peter Saint-Andre, Nat Sakimura, Rob Sayre,
Marius Scurtescu, Naitik Shah, Justin Smith, Jeremy Suriel, Christian Stübner, Paul Tarjan,
and Franklin Tse.
[[ to be removed by RFC editor before publication as an RFC ]]
-01
First public draft, which incorporates feedback received
on -00 including enhanced Security Considerations content.
This version is intended to accompany OAuth 2.0 draft 11.
-00
Initial draft based on preliminary version of OAuth 2.0 draft 11.