Facebook OAuth 2.0 Service Covert Redirect Web Security Bugs Based on Ask.com (Information Leakage & Open Redirect)
“Facebook had over 1.44 billion monthly active users as of March 2015. Because of the large volume of data users submit to the service, Facebook has come under scrutiny for their privacy policies. Facebook, Inc. held its initial public offering in February 2012 and began selling stock to the public three months later, reaching an original peak market capitalization of $104 billion. As of February 2015 Facebook reached a market capitalization of $212 Billion.” (Wikipedia)
(2) Vulnerability Description:
Facebook web application has a computer security problem. Hacker can exploit it by Covert Redirect cyber attacks.
The vulnerabilities can be attacked without user login. Tests were performed on Microsoft IE (10.0.9200.16750) of Windows 8, Mozilla Firefox (34.0) & Google Chromium 39.0.2171.65-0 ubuntu0.14.04.1.1064 (64-bit) of Ubuntu (14.04)，Apple Safari 6.1.6 of Mac OS X Lion 10.7.
(2.1) Vulnerability Description:
It increases the likelihood of successful Open Redirect Attacks to third-party websites, too.
The vulnerabilities occurs at page “/dialog/oauth?” with parameter “&redirect_uri”, e.g.
Before acceptance of third-party application:
When a logged-in Facebook user clicks the URL () above, he/she will be asked for consent as in whether to allow a third-party website to receive his/her information. If the user clicks OK, he/she will be then redirected to the URL assigned to the parameter “&redirect_uri”.
If a user has not logged onto Facebook and clicks the URL () above, the same situation will happen upon login.
After acceptance of third-party application:
A logged-in Facebook user would no longer be asked for consent and could be redirected to a webpage controlled by the attacker when he/she clicks the URL ().
For a user who has not logged in, the attack could still be completed after a pop-up page that prompts him/her to log in.
(2.1.1) Facebook would normally allow all the URLs that belong to the domain of an authorized third-party website. However, these URLs could be prone to manipulation. For example, the “&redirect_uri” parameter in the URLs is supposed to be set by the third-party websites, but an attacker could change its value to make Attacks.
Hence, a user could be redirected from Facebook to a vulnerable URL in that domain first and later be redirected from this vulnerable site to a malicious site unwillingly. This is as if the user is redirected from Facebook directly. The number of Facebook’s SSO client websites is so huge that such Attacks could be commonplace.
Before acceptance of the third-party application, Facebook’s SSO system makes the redirects appear more trustworthy and could potentially increase the likelihood of successful Open Redirect Attacks of third-party website.
Once the user accepts the application, the attackers could completely bypass Facebook’s authentication system and attack more easily.
It might be of Facebook’s interest to patch up against such attacks.
(2.2) Used one of webpages for the following tests. The webpage is “http://www.diebiyi.com/articles“. We can suppose it is malicious and contains code that collect sensitive information of both third-party app and users.
Below is an example of a vulnerable third-party domain:
Vulnerable URL in this domain:
Vulnerable URL from Facebook that is related to ask.com:
(2.3) The following URLs have the same vulnerabilities.
(3) What is Covert Redirect?
Covert Redirect is a class of security bugs disclosed in May 2014. It is an application that takes a parameter and redirects a user to the parameter value without sufficient validation. This often makes use of Open Redirect and XSS (Cross-site Scripting) vulnerabilities in third-party applications.
Covert Redirect is also related to single sign-on. It is known by its influence on OAuth and OpenID. Hacker may use it to steal users’ sensitive information. Almost all OAuth 2.0 and OpenID providers worldwide are affected. Covert Redirect can work together with CSRF (Cross-site Request Forgery) as well.
Discover and Reporter:
Wang Jing, Division of Mathematical Sciences (MAS), School of Physical and Mathematical Sciences (SPMS), Nanyang Technological University (NTU), Singapore. (@justqdjing)