Difference between revisions of "Testing for DOM-based Cross site scripting (OWASP-DV-003)"

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== References ==
 
== References ==
 +
'''OWASP Resources'''
 +
* [[DOM based XSS Prevention Cheat Sheet]]
 
'''Whitepapers'''<br>
 
'''Whitepapers'''<br>
 
* Document Object Model (DOM) - http://en.wikipedia.org/wiki/Document_Object_Model
 
* Document Object Model (DOM) - http://en.wikipedia.org/wiki/Document_Object_Model

Revision as of 13:45, 15 February 2012

OWASP Testing Guide v3 Table of Contents

This article is part of the OWASP Testing Guide v3. The entire OWASP Testing Guide v3 can be downloaded here.

OWASP at the moment is working at the OWASP Testing Guide v4: you can browse the Guide here

Contents


Brief Summary

DOM-based Cross-Site Scripting is the de-facto name for XSS bugs which are the result of active browser-side content on a page, typically JavaScript, obtaining user input and then doing something unsafe with it which leads to execution of injected code. This document only discusses JavaScript bugs which lead to XSS.

The DOM, or Document Object Model, is the structural format used to represent documents in a browser. The DOM enables dynamic scripts such as JavaScript to reference components of the document such as a form field or a session cookie. The DOM is also used by the browser for security - for example to limit scripts on different domains from obtaining session cookies for other domains. A DOM-based XSS vulnerability may occur when active content, such as a JavaScript function, is modified by a specially crafted request such that a DOM element that can be controlled by an attacker.

There have been very few papers published on this topic and, as such, very little standardization of its meaning and formalized testing exists.

Description of the Issue

Not all XSS bugs require the attacker to control the content returned from the server, but can instead abuse poor JavaScript coding practices to achieve the same results. The consequences are the same as a typical XSS flaw, only the means of delivery is different.

In comparison to other cross site scripting vulnerabilities (reflected and stored XSS), where an unsanitized parameter is passed by the server, returned to the user and executed in the context of the user's browser, a DOM-based XSS vulnerability controls the flow of the code by using elements of the Document Object Model (DOM) along with code crafted by the attacker to change the flow.

Due to their nature, DOM-based XSS vulnerabilities can be executed in many instances without the server being able to determine what is actually being executed. This may make many of the general XSS filtering and detection techniques impotent to such attacks.

The first hypothetical example uses the following client side code:

<script>
document.write("Site is at: " + document.location.href + ".");
</script>

An attacker may append #<script>alert('xss')</script> to the affected page URL which would, when executed, display the alert box. In this instance, the appended code would not be sent to the server as everything after the # character is not treated as part of the query by the browser but as a fragment. In this example, the code is immediately executed and an alert of "xss" is displayed by the page. Unlike the more common types of cross site scripting (Stored and Reflected) in which the code is sent to the server and then back to the browser, this is executed directly in the user's browser without server contact.

The consequences of DOM-based XSS flaws are as wide ranging as those seen in more well known forms of XSS, including cookie retrieval, further malicious script injection, etc. and should therefore be treated with the same severity.

Black Box testing and example

Blackbox testing for DOM-Based XSS is not usually performed since access to the source code is always available as it needs to be sent to the client to be executed.

Gray Box testing and example

Testing for DOM-Based XSS vulnerabilities:
JavaScript applications differ significantly from other types of applications because they are often dynamically generated by the server, and to understand what code is being executed, the website being tested needs to be crawled to determine all the instances of JavaScript being executed and where user input is accepted. Many websites rely on large libraries of functions, which often stretch into the hundreds of thousands of lines of code and have not been developed in-house. In these cases, top-down testing often becomes the only really viable option, since many bottom level functions are never used, and analyzing them to determine which are sinks will use up more time than is often available. The same can also be said for top-down testing if the inputs or lack thereof is not identified to begin with.

User input comes in two main forms:

  • Input written to the page by the server in a way that does not allow direct XSS
  • Input obtained from client-side JavaScript objects

Here are two examples of how the server may insert data into JavaScript:

var data = "<escaped data from the server>";
var result = someFunction("<escaped data from the server>");

And here are two examples of input from client-side JavaScript objects:

var data = window.location;
var result = someFunction(window.referer);

While there is little difference to the JavaScript code in how they are retrieved, it is important to note that when input is received via the server, the server can apply any permutations to the data that it desires, whereas the permutations performed by JavaScript objects are fairly well understood and documented, and so if someFunction in the above example were a sink, then the exploitability of the former would depend on the filtering done by the server, whereas the latter would depend on the encoding done by the browser on the window.referer object. Stefano Di Paulo has written an excellent article on what browsers return when asked for the various elements of a URL using the document. and location. attributes.

Additionally, JavaScript is often executed outside of <script> blocks, as evidenced by the many vectors which have led to XSS filter bypasses in the past, and so, when crawling the application, it is important to note the use of scripts in places such as event handlers and CSS blocks with expression attributes. Also, note that any off-site CSS or script objects will need to be assessed to determine what code is being executed.

Automated testing has only very limited success at identifying and validating DOM-based XSS as it usually identifies XSS by sending a specific payload and attempts to observe it in the server response. This may work fine for the simple example provided below, where the message parameter is reflected back to the user:

<script>
var pos=document.URL.indexOf("message=")+5;
document.write(document.URL.substring(pos,document.URL.length));
</script>

but may not be detected in the following contrived case:

 
<script>
var navAgt = navigator.userAgent;
 
if (navAgt.indexOf("MSIE")!=-1) {
     document.write("You are using IE as a browser and visiting site: " + document.location.href + ".");
}
else
{
    document.write("You are using an unknown browser.");
}
</script>

For this reason, automated testing will not detect areas that may be susceptible to DOM-based XSS unless the testing tool can perform addition analysis of the client side code.

Manual testing should therefore be undertaken and can be done by examining areas in the code where parameters are referred to that may be useful to an attacker. Examples of such areas include places where code is dynamically written to the page and elsewhere where the DOM is modified or even where scripts are directly executed. Further examples are described in the excellent DOM XSS article by Amit Klein, referenced at the end of this section.

References

OWASP Resources

Whitepapers