When blocking 3rd Party cookies using Google Chrome (latest), build 27 Win7/PC, I've seen that almost all OAuth logins from other sites don't work, with the exception of signing in with G+. I've already signed in with Google though, so that cookie exists.

  • Is this behavior that is actually a dependency of OAuth2.0, requiring 3rd-party cookies to be enabled?
  • Is it a consequence of the prevailing implementation of OAuth?
  • Is this something client-dependent?
  • Is this resulting from how Chrome defines what "third-party cookies" are?

Thank you all for your help and time! I can't seem to find any sources that clarify the issue for me.

  • Chrome on Mac gets the same problem with G+. I also cannot find any articles or sources that clarify what's going on. – philo vivero Mar 13 '17 at 18:42
  • I cannot find any direct corroboration of this hypothesis, but I suspect sites solve this by doing OAuth on the back-end server-side, then send a 302/Redirect to the client and set the cookies directly from their own domain. I suspect trying to do OAuth client-side will always fail when 3rd party cookies are blocked in Chrome. – philo vivero Mar 16 '17 at 20:31

For web applications, some sort of storage local storage is required ("MUST...") by the OAuth 2.0 spec as part of the defense against Cross-site request forgery (CSRF). The spec suggests cookies or HTML5 local storage specifically, with cookies being a prevalent implementation as your observations show.

Referencing RFC 6749 - The OAuth 2.0 Authorization Framework we find (emphasis added):

  1. Security Considerations

    As a flexible and extensible framework, OAuth's security considerations depend on many factors. The following sections provide implementers with security guidelines focused on the three client profiles described in Section 2.1: web application, user-agent-based application, and native application.


10.12. Cross-Site Request Forgery

Cross-site request forgery (CSRF) is an exploit in which an attacker causes the user-agent of a victim end-user to follow a malicious URI (e.g., provided to the user-agent as a misleading link, image, or redirection) to a trusting server (usually established via the presence of a valid session cookie).

A CSRF attack against the client's redirection URI allows an attacker to inject its own authorization code or access token, which can result in the client using an access token associated with the attacker's protected resources rather than the victim's (e.g., save the victim's bank account information to a protected resource controlled by the attacker).

The client MUST implement CSRF protection for its redirection URI. This is typically accomplished by requiring any request sent to the redirection URI endpoint to include a value that binds the request to the user-agent's authenticated state (e.g., a hash of the session cookie used to authenticate the user-agent). The client SHOULD utilize the "state" request parameter to deliver this value to the authorization server when making an authorization request.

Once authorization has been obtained from the end-user, the authorization server redirects the end-user's user-agent back to the client with the required binding value contained in the "state" parameter. The binding value enables the client to verify the validity of the request by matching the binding value to the user-agent's authenticated state. The binding value used for CSRF protection MUST contain a non-guessable value (as described in Section 10.10), and the user-agent's authenticated state (e.g., session cookie, HTML5 local storage) MUST be kept in a location accessible only to the client and the user-agent (i.e., protected by same-origin policy).

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