Recently, I stumbled upon a question related to the behavior of a given program. That program was Mozilla Firefox and the behavior in question was how profile directory names were generated. Through this post, I will cover how to approach this question and how to solve it with available resources (source code).
The Question
How are Firefox profile directory names generated?
The Answer (and the road to get there)
To answer this question, we first have to understand which artifacts we are examining. In this case, we are dealing with Firefox profiles. Those are located in a user's AppData folder. By navigating AppData, we eventually find C:\Users\someUser\AppData\Roaming\Mozilla\Firefox\Profiles.
The Firefox 'Profiles' folder showing the directory for the profile named "default."
We see a folder for the only Firefox profile used on the system. Reasonably, this account is named "default" by default. But what about that seemingly random prefix?
Let's see if we can glean anything from trying to create a profile in Firefox. First, let's open up the Profile Manager by typing "firefox.exe -p" in the 'Run...' dialog (Windows key + R).
We can confirm that there is only one profile and it is named "default."
When we try to create a profile, we see the following window:
Great. We can actually see where it is going to be saved. And no matter what we enter in the text input field, the prefix stays the same. This tells us that the folder for this new profile isn't generated based on the profile name we enter. But there are other possibilities, such as the folder name being based on the current time.
There are many other tests we could run, but we actually don't need to -- the source code for Firefox is freely available online. Once we download and extract the source code, we can try to find the function that handles the generation of the profile's folder name.
Uncompressed, the Firefox source code is about 585MB. That's a lot of code to review. A better way to sift through all of this data is to either index it all and search it or to just recursively grep the root folder. I decided on the latter.
To find out where to look first, we can try to find a constant, unique phrase around the text in question. In the above image, the string "Your user settings, preferences and other user-related data will be stored in:" is right before the path name with which we are concerned. So let's grep for that and see if we can find anything.
There are many ways to grep data, but this was a quick and dirty job where I wasn't doing any parsing or modifying, so I used AstroGrep. I went ahead and searched for the a watered down version of the aforementioned unique phrase: "will be stored in." The results showed that the file named CreateProfileWizard.dtd contained this unique phrase (there were many files that were responsive, but based on the phrase's context and the filename for the file in which the phrase was found, we can determine relevancy).
A snippet of the responsive "CreateProfileWizard.dtd" file containing our unique phrase.
Now, it's just a matter of tracing this phrase back to its source. So we grab another unique phrase that is relevant to our discovery, such as "profileDirectoryExplanation," and see if we can find any more relevant files. Grepping for it comes back with more results -- one of which is createProfileWizard.xul. I didn't see much in this file at first glance (though there is quite bit of good info such as "<wizardpage id="createProfile" onpageshow="initSecondWizardPage();">" -- which will be seen soon), so I decided to see what else was in same directory as this file. There, I found createProfileWizard.js.
A snippet of the "createProfileWizard.js" file showing the functions used to generate the profile directory names.
Skimming the code, we can see that a salt table and Math.random() are used to determine the 8 character prefix. At line 68, we see the concatination of kSaltString ('0n38y60t' in the animated gif), a period ('.'), and aName (our text input field variable -- in our example, "abcdefg" or "4n6k").
In the end, the point is that having source code available makes research more streamlined. By looking at the Firefox source, we were able to determine that the profile directory names aren't based on a telling artifact.
Using what is available to you is invaluable. By having a program's source code [and approaching an issue with an analytic mindset], verifying program behavior is made so much easier.
I'll end with this: open source development is GOOD -- especially for forensics. Whether it's a tool meant to output forensic artifacts or just another Firefox, we are able to more confidently prove why we are seeing what we're seeing.
-4n6k
* Special thanks to Tom Yarrish (@CdtDelta) for spawning this post.
1 comments:
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