DOM based XSS Prevention Cheat Sheet

= Introduction =

When looking at XSS (Cross-Site Scripting), there are three generally recognized forms of XSS. Reflected, Stored, and DOM Based XSS. The XSS Prevention Cheatsheet does an excellent job of addressing Reflected and Stored XSS. This cheatsheet addresses DOM (Document Object Model) based XSS and is an extension (and assumes comprehension of) the XSS Prevention Cheatsheet.

In order to understand DOM based XSS, one needs to see the fundamental difference between Reflected and Stored XSS when compared to DOM based XSS. Reflected and Stored XSS are server side execution issues while DOM based XSS is a client (browser) side execution issue. All of this code originates on the server, which means it is the application owner's responsibility to make it safe from XSS, regardless of the type of XSS flaw it is.

When a browser is rendering HTML and any other associated content like CSS, javascript, etc. it identifies various rendering contexts for the different kinds of input and follows different rules for each context. A rendering context is associated with the parsing of HTML tags and their attributes. The HTML parser of the rendering context dictates how data is presented and laid out on the page and can be further broken down into the standard contexts of HTML, HTML attribute, URL, and CSS. The JavaScript or VBScript parser of an execution context is associated with the parsing and execution of script code. Each parser has distinct and separate semantics in the way they can possibly execute script code which make creating consistent rules for mitigating vulnerabilities in various contexts difficult. The complication is compounded by the differing meanings and treatment of encoded values within each subcontext (HTML, HTML attribute, URL, and CSS) within the execution context.

For the purposes of this article, we refer to the HTML, HTML attribute, URL, and CSS Cheatsheet contexts as subcontexts because each of these contexts can be reached and set within a JavaScript execution context. In JavaScript code, the main context is JavaScript but with the right tags and context closing characters, an attacker can try to attack the other 4 contexts using equivalent JavaScript DOM methods.

The following is an example vulnerability which occurs in the JavaScript context and HTML subcontext:

Let’s look at the individual subcontexts of the execution context in turn.

RULE #1 - HTML Escape then JavaScript Escape Before Inserting Untrusted Data into HTML Subcontext within the Execution Context
There are several methods and attributes which can be used to directly render HTML content within JavaScript. These methods constitute the HTML Subcontext within the Execution Context. If these methods are provided with untrusted input, then an XSS vulnerability could result. For example:

Guideline
To make dynamic updates to HTML in the DOM safe, we recommend a) HTML encoding, and then b) JavaScript encoding all untrusted input, as shown in these examples:

Note: The Encoder.encodeForHTML and Encoder.encodeForJS are just notional encoders. Various options for actual encoders are listed later in this document.

RULE #2 - JavaScript Escape Before Inserting Untrusted Data into HTML Attribute Subcontext within the Execution Context
The HTML attribute *subcontext* within the *execution* context is divergent from the standard encoding rules. This is because the rule to HTML attribute encode in an HTML attribute rendering context is necessary in order to mitigate attacks which try to exit out of an HTML attributes or try to add additional attributes which could lead to XSS. When you are in a DOM execution context you only need to JavaScript encode HTML attributes which do not execute code (attributes other than event handler, CSS, and URL attributes).

For example, the general rule is to HTML Attribute encode untrusted data (data from the database, HTTP request, user, back-end system, etc.) placed in an HTML Attribute. This is the appropriate step to take when outputting data in a rendering context, however using HTML Attribute encoding in an execution context will break the application display of data.

SAFE but BROKEN example
The problem is that if companyName had the value “Johnson & Johnson”. What would be displayed in the input text field would be “Johnson &amp;amp; Johnson”. The appropriate encoding to use in the above case would be only JavaScript encoding to disallow an attacker from closing out the single quotes and in-lining code, or escaping to HTML and opening a new script tag.

SAFE and FUNCTIONALLY CORRECT example
It is important to note that when setting an HTML attribute which does not execute code, the value is set directly within the object attribute of the HTML element so there is no concerns with injecting up.

RULE #3 - Be Careful when Inserting Untrusted Data into the Event Handler and JavaScript code Subcontexts within an Execution Context
Putting dynamic data within JavaScript code is especially dangerous because JavaScript encoding has different semantics for JavaScript encoded data when compared to other encodings. In many cases, JavaScript encoding does not stop attacks within an execution context. For example, a JavaScript encoded string will execute even though it is JavaScript encoded.

Therefore, the primary recommendation is to avoid including untrusted data in this context. If you must, the following examples describe some approaches that do and do not work.

The setAttribute(name_string,value_string) method is dangerous because it implicitly coerces the string_value into the DOM attribute datatype of name_string. In the case above, the attribute name is an JavaScript event handler, so the attribute value is implicitly converted to JavaScript code and evaluated. In the case above, JavaScript encoding does not mitigate against DOM based XSS. Other JavaScript methods which take code as a string types will have a similar problem as outline above (setTimeout, setInterval, new Function, etc.). This is in stark contrast to JavaScript encoding in the event handler attribute of a HTML tag (HTML parser) where JavaScript encoding mitigates against XSS.

An alternative to using Element.setAttribute(...) to set DOM attributes is to set the attribute directly. Directly setting event handler attributes will allow JavaScript encoding to mitigate against DOM based XSS.

There are other places in JavaScript where JavaScript encoding is accepted as valid executable code.

or

Because JavaScript is based on an international standard (ECMAScript), JavaScript encoding enables the support of international characters in programming constructs and variables in addition to alternate string representations (string escapes).

However the opposite is the case with HTML encoding. HTML tag elements are well defined and do not support alternate representations of the same tag. So HTML encoding cannot be used to allow the developer to have alternate representations of the  tag for example.

HTML Encoding’s Disarming Nature
In general, HTML encoding serves to castrate HTML tags which are placed in HTML and HTML attribute contexts. Working example (no HTML encoding):

Normally encoded example (Does Not Work – DNW):

HTML encoded example to highlight a fundamental difference with JavaScript encoded values (DNW):

If HTML encoding followed the same semantics as JavaScript encoding. The line above could have possibily worked to render a link. This difference makes JavaScript encoding a less viable weapon in our fight against XSS.

RULE #4 - JavaScript Escape Before Inserting Untrusted Data into the CSS Attribute Subcontext within the Execution Context
Normally executing JavaScript from a CSS context required either passing  to the CSS url method or invoking the CSS expression method passing JavaScript code to be directly executed. From my experience, calling the expression function from an execution context (JavaScript) has been disabled. In order to mitigate against the CSS url method, ensure that you are URL encoding the data passed to the CSS url method.

TODO: We have not been able to get the expression function working from DOM JavaScript code. Need some help.

RULE #5 - URL Escape then JavaScript Escape Before Inserting Untrusted Data into URL Attribute Subcontext within the Execution Context
The logic which parses URLs in both execution and rendering contexts looks to be the same. Therefore there is little change in the encoding rules for URL attributes in an execution (DOM) context.

var x = document.createElement(“a”); x.setAttribute(“href”, ‘<%=Encoder.encodeForJS(Encoder.encodeForURL(userRelativePath))%>’); var y = document.createTextElement(“Click Me To Test”); x.appendChild(y); document.body.appendChild(x);

If you utilize fully qualified URLs then this will break the links as the colon in the protocol identifier (“http:” or “javascript:”) will be URL encoded preventing the “http” and “javascript” protocols from being invoked.

=Guidelines for Developing Secure Applications Utilizing JavaScript=

DOM based XSS is extremely difficult to mitigate against because of its large attack surface and lack of standardization across browsers. The guidelines below are an attempt to provide guidelines for developers when developing Web based JavaScript applications (Web 2.0) such that they can avoid XSS.

1. Untrusted data should only be treated as displayable text. Never treat untrusted data as code or markup within JavaScript code. 2. Always JavaScript encode and delimit untrusted data as quoted strings when entering the application (Jim Manico and Robert Hansen) 3. Use, etc. to build dynamic interfaces. Avoid use of HTML rendering methods: 4. Understand the dataflow of untrusted data through your JavaScript code. If you do have to use the methods above remember to HTML and then JavaScript encode the untrusted data (Stefano Di Paola). 5. There are numerous methods which implicitly eval data passed to it. Make sure that any untrusted data passed to these methods is delimited with string delimiters and enclosed within a closure or JavaScript encoded to N-levels based on usage, and wrapped in a custom function. Ensure to follow step 4 above to make sure that the untrusted data is not sent to dangerous methods within the custom function or handle it by adding an extra layer of encoding.

Utilizing an Enclosure (as suggested by Gaz)

The example that follows illustrates using closures to avoid double JavaScript encoding.

The other alternative is using N-levels of encoding.

N-Levels of Encoding

If your code looked like the following, you would need to only double JavaScript encode input data.

The  has its first layer of JavaScript encoding reversed (upon execution) in the single quotes. Then the implicit  of   reverses another layer of JavaScript encoding to pass the correct value to. The reason why you only need to double JavaScript encode is that the  function did not itself pass the input to another method which implicitly or explicitly called. If "firstName" was passed to another JavaScript method which implicitly or explicitly called eval then  above would need to be changed to.

An important implementation note is that if the JavaScript code tries to utilize the double or triple encoded data in string comparisons, the value may be interpreted as different values based on the number of evals the data has passed through before being passed to the if comparison and the number of times the value was JavaScript encoded.

If "A" is double JavaScript encoded then the following if check will return false.

This brings up an interesting design point. Ideally, the correct way to apply encoding and avoid the problem stated above is to server-side encode for the output context where data is introduced into the application. Then client-side encode (using a JavaScript encoding library such as ESAPI4JS) for the individual subcontext (DOM methods) which untrusted data is passed to. ESAPI4JS (located at http://bit.ly/9hRTLH) and jQuery Encoder (located at https://github.com/chrisisbeef/jquery-encoder/blob/master/src/main/javascript/org/owasp/esapi/jquery/encoder.js) are two client side encoding libraries developed by Chris Schmidt. Here are some examples of how they are used:

It has been well noted by the group that any kind of reliance on a JavaScript library for encoding would be problematic as the JavaScript library could be subverted by attackers. One option is to wait till ECMAScript 5 so the JavaScript library could support immutable properties. Another option provided by Gaz (Gareth) was to use a specific code construct to limit mutability with anonymous clousures.

An example follows:

Chris Schmidt has put together another implementation of a JavaScript encoder at http://yet-another-dev.blogspot.com/2011/02/client-side-contextual-encoding-for.html.

6. Limit the usage of dynamic untrusted data to right side operations. And be aware of data which may be passed to the application which look like code (eg.,  ). (Achim)

If you want to change different object attributes based on user input use a level of indirection.

Instead of:

Do the following instead:

7. When URL encoding in DOM be aware of character set issues as the character set in JavaScript DOM is not clearly defined (Mike Samuel).

8. Limit access to properties objects when using object[x] accessors. (Mike Samuel). In other words use a level of indirection between untrusted input and specified object properties. Here is an example of the problem when using map types:

Although the developer writing the code above was trying to add additional keyed elements to the  object. This could be used by an attacker to subvert internal and external attributes of the  object.

9. Run your JavaScript in a ECMAScript 5 canopy or sand box to make it harder for your JavaScript API to be compromised (Gareth Heyes and John Stevens).

10. Don’t  JSON to convert it to native JavaScript objects. Instead use  and   (Chris Schmidt).

= Common Problems Associated with Mitigating DOM Based XSS =

Complex Contexts
In many cases the context isn’t always straightforward to discern.

In the above example, untrusted data started in the rendering URL context ( attribute of an   tag) then changed to a JavaScript execution context (  protocol handler) which passed the untrusted data to an execution URL subcontext (  of myFunction). Because the data was introduced in JavaScript code and passed to a URL subcontext the appropriate server-side encoding would be the following:

Or if you were using ECMAScript 5 with an immutable JavaScript client-side encoding libraries you could do the following:

Inconsistencies of Encoding Libraries
There are a number of open source encoding libraries out there:


 * 1) ESAPI
 * 2) Apache Commons String Utils
 * 3) Jtidy
 * 4) Your company’s custom implementation.

Some work on a black list while others ignore important characters like “<” and “>”. ESAPI is one of the few which works on a whitelist and encodes all non-alphanumeric characters. It is important to use an encoding library that understands which characters can be used to exploit vulnerabilies in their respective contexts. Misconceptions abound related to the proper encoding that is required.

Encoding Misconceptions
Many security training curriculums and papers advocate the blind usage of HTML encoding to resolve XSS. This logically seems to be prudent advice as the JavaScript parser does not understand HTML encoding. However, if the pages returned from your web application utilize a content type of “text/xhtml” or the file type extension of “*.xhtml” then HTML encoding may not work to mitigate against XSS.

For example:

The HTML encoded value above is still executable. If that isn’t enough to keep in mind, you have to remember that encodings are lost when you retrieve them using the value attribute of a DOM element.

Let’s look at the sample page and script:

Finally there is the problem that certain methods in JavaScript which are usually safe can be unsafe in certain contexts.

Usually Safe Methods
One example of an attribute which is usually safe is innerText. Some papers or guides advocate its use as an alternative to innerHTML to mitigate against XSS in innerHTML. However, depending on the tag which innerText is applied, code can be executed.

= Authors and Contributing Editors =

Jim Manico - jim[at]owasp.org

Abraham Kang - abraham.kang[at]owasp.org

Gareth (Gaz) Heyes

Stefano Di Paola

Achim Hoffmann - achim[at]owasp.org

Robert (RSnake) Hansen

Mario Heiderich

John Steven

Chris (Chris BEEF) Schmidt

Mike Samuel

Jeremy Long

Edwardo (SirDarkCat) Alberto Vela Nava

Jeff Williams - jeff.williams[at]owasp.org

Erlend Oftedal