Utilizing Chrome’s accessibility APIs to search out safety bugs

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Posted by Adrian Taylor, Safety Engineer, Chrome

Chrome’s person interface (UI) code is complicated, and typically has bugs.

Are these bugs safety bugs? Particularly, if a person’s clicks and actions end in reminiscence corruption, is that one thing that an attacker can exploit to hurt that person?

Our safety severity pointers say “sure, typically.” For instance, an attacker may very possible persuade a person to click on an autofill immediate, however it will likely be a lot more durable to persuade the person to step by way of a complete movement of various dialogs.

Even when these bugs aren’t probably the most simply exploitable, it takes a substantial amount of time for our safety shepherds to make these determinations. Person interface bugs are sometimes flakey (that’s, not reliably reproducible). Additionally, even when these bugs aren’t essentially deemed to be exploitable, they might nonetheless be annoying crashes which trouble the person.

It might be nice if we may discover these bugs robotically.

If solely the entire tree of Chrome UI controls had been uncovered, one way or the other, such that we may enumerate and work together with every UI management robotically.

Aha! Chrome exposes all of the UI controls to assistive expertise. Chrome goes to nice lengths to make sure its whole UI is uncovered to display readers, braille gadgets and different such assistive tech. This tree of controls contains all of the toolbars, menus, and the construction of the web page itself. This structural definition of the browser person interface is already typically utilized in different contexts, for instance by some password managers, demonstrating that investing in accessibility has advantages for all customers. We’re now taking that funding and leveraging it to search out safety bugs, too.

Particularly, we’re now “fuzzing” that accessibility tree – that’s, interacting with the completely different UI controls semi-randomly to see if we are able to make issues crash. This system has an extended pedigree.

Display reader expertise is a bit completely different on every platform, however on Linux the tree may be explored utilizing Accerciser.

Screenshot of Accerciser displaying the tree of UI controls in Chrome

All we have now to do is discover the identical tree of controls with a fuzzer. How exhausting can it’s?

“We do that not as a result of it’s straightforward, however as a result of we thought it could be straightforward” – Anon.

Truly we by no means thought this is able to be straightforward, and some completely different bits of tech have needed to fall into place to make this doable. Particularly,

There are many mixtures of the way to work together with Chrome. Really randomly clicking on UI controls in all probability gained’t discover bugs – we wish to leverage coverage-guided fuzzing to assist the fuzzer choose mixtures of controls that appear to achieve into new code inside Chrome.

We want any such bugs to be real. We subsequently must fuzz the precise Chrome UI, or one thing very related, slightly than exercising elements of the code in an unrealistic unit-test-like context. That’s the place our InProcessFuzzer framework comes into play – it runs fuzz instances inside a Chrome browser_test; primarily an actual model of Chrome.

However such browser_tests have a excessive startup price. We have to amortize that price over 1000’s of check instances by operating a batch of them inside every browser invocation. Centipede is designed to do this.

However every check case gained’t be idempotent. Inside a given invocation of the browser, the UI state could also be successively modified by every check case. We intend so as to add concatenation to centipede to resolve this.

Chrome is a loud setting with a number of timers, which can properly confuse coverage-guided fuzzers. Gathering protection for such a big binary is gradual in itself. So, we don’t know if coverage-guided fuzzing will efficiently discover the UI paths right here.

All of those considerations are frequent to the opposite fuzzers which run within the browser_test context, most notably our new IPC fuzzer (weblog posts to observe). However the UI fuzzer introduced some particular challenges.

Discovering UI bugs is just helpful in the event that they’re actionable. Ideally, meaning:

Our fuzzing infrastructure provides a radical set of diagnostics.

It may bisect to search out when the bug was launched and when it was fastened.

It may reduce complicated check instances into the smallest doable reproducer.

The check case is descriptive and says which UI controls had been used, so a human might be able to reproduce it.

These necessities collectively imply that the check instances ought to be steady throughout every Chrome model – if a given check case reproduces a bug with Chrome 125, hopefully it is going to accomplish that in Chrome 124 and Chrome 126 (assuming the bug is current in each). But that is tough, since Chrome UI controls are deeply nested and sometimes nameless.

Initially, the fuzzer picked controls merely based mostly on their ordinal at every stage of the tree (as an example “management 3 nested in management 5 nested in management 0”) however such check instances are unlikely to be steady because the Chrome UI evolves. As a substitute, we settled on an strategy the place the controls are named, when doable, and in any other case recognized by a mixture of position and ordinal. This yields check instances like this:

motion {
path_to_control {
named {
identify: “Take a look at – Chromium”
}
}
path_to_control {
nameless {
position: “panel”
}
}
path_to_control {
nameless {
position: “panel”
}
}
path_to_control {
nameless {
position: “panel”
}
}
path_to_control {
named {
identify: “Bookmarks”
}
}
take_action {
action_id: 12
}
}

Fuzzers are unlikely to stumble throughout these management names by probability, even with the instrumentation utilized to string comparisons. Actually, this by-name strategy turned out to be solely 20% as efficient as selecting controls by ordinal. To resolve this we added a customized mutator which is wise sufficient to place in place management names and roles that are recognized to exist. We randomly use this mutator or the usual libprotobuf-mutator with a view to get the very best of each worlds. This strategy has confirmed to be about 80% as fast as the unique ordinal-based mutator, whereas offering steady check instances.

Chart of code protection achieved by minutes fuzzing with completely different methods

So, does any of this work?

We don’t know but! – and you’ll observe alongside as we discover out. The fuzzer discovered a few potential bugs (at present entry restricted) within the accessibility code itself however hasn’t but explored far sufficient to find bugs in Chrome’s basic UI. However, on the time of writing, this has solely been operating on our ClusterFuzz infrastructure for just a few hours, and isn’t but engaged on our protection dashboard. If you happen to’d wish to observe alongside, control our protection dashboard because it expands to cowl UI code.

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