Thwarting the cleverest attackers

Savvy hackers can steal a computer’s secrets by timing its data storage transactions or measuring its power use. New research shows how to stop them.


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Caroline McCall
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In the last 10 years, cryptography researchers have demonstrated that even the most secure-seeming computer is shockingly vulnerable to attack. The time it takes a computer to store data in memory, fluctuations in its power consumption and even the noises it emits can betray information to a savvy assailant.

Attacks that use such indirect sources of information are called side-channel attacks, and the increasing popularity of cloud computing makes them an even greater threat. An attacker would have to be pretty motivated to install a device in your wall to measure your computer’s power consumption. But it’s comparatively easy to load a bit of code on a server in the cloud and eavesdrop on other applications it’s running.

Fortunately, even as they’ve been researching side-channel attacks, cryptographers have also been investigating ways of stopping them. Shafi Goldwasser, the RSA Professor of Electrical Engineering and Computer Science at MIT, and her former student Guy Rothblum, who’s now a researcher at Microsoft Research, recently posted a long report on the website of the Electronic Colloquium on Computational Complexity, describing a general approach to mitigating side-channel attacks. At the Association for Computing Machinery’s Symposium on Theory of Computing (STOC) in May, Goldwasser and colleagues will present a paper demonstrating how the technique she developed with Rothblum can be adapted to protect information processed on web servers.

In addition to preventing attacks on private information, Goldwasser says, the technique could also protect devices that use proprietary algorithms so that they can’t be reverse-engineered by pirates or market competitors — an application that she, Rothblum and others described at last year’s AsiaCrypt conference.

Today, when a personal computer is in use, it’s usually running multiple programs — say, a word processor, a browser, a PDF viewer, maybe an email program or a spreadsheet program. All the programs are storing data in memory, but the laptop’s operating system won’t let any program look at the data stored by any other. The operating systems running on servers in the cloud are no different, but a malicious program could launch a side-channel attack simply by sending its own data to memory over and over again. From the time the data storage and retrieval takes, it can infer what the other programs are doing with remarkable accuracy.

Goldwasser and Rothblum’s technique obscures the computational details of a program, whether it’s running on a laptop or a server. Their system converts a given computation into a sequence of smaller computational modules. Data fed into the first module is encrypted, and at no point during the module’s execution is it decrypted. The still-encrypted output of the first module is fed into the second module, which encrypts it in yet a different way, and so on.

The encryption schemes and the modules are devised so that the output of the final module is exactly the output of the original computation. But the operations performed by the individual modules are entirely different. A side-channel attacker could extract information about how the data in any given module is encrypted, but that won’t let him deduce what the sequence of modules does as a whole. “The adversary can take measurements of each module,” Goldwasser says, “but they can’t learn anything more than they could from a black box.”

The report by Goldwasser and Rothblum describes a type of compiler, a program that takes code written in a form intelligible to humans and converts it into the low-level instructions intelligible to a computer. There, the computational modules are an abstraction: The instruction that inaugurates a new module looks no different from the instruction that concluded the last one. But in the STOC paper, the modules are executed on different servers on a network.

According to Nigel Smart, a professor of cryptology in the computer science department at the University of Bristol in England, the danger of side-channel attacks “has been known since the late ’90s.”

“There’s a lot of engineering that was done to try to prevent this from being a problem,” Smart says, “a huge amount of engineering work. This is a megabucks industry.” Much of that work, however, has relied on trial and error, Smart says. Goldwasser and Rothblum’s study, on the other hand, “is a much more foundational study, looking at really foundational, deep questions about what is possible.”

Moreover, Smart says, previous work on side-channel attacks tended to focus on the threat posed to handheld devices, such as cellphones and smart cards. “It would seem to me that the stuff that is more likely to take off in the long run is the stuff that’s talking about servers,” Smart says. “I don’t know anyone else outside MIT who’s looking at that.”

Smart cautions, however, that the work of Goldwasser and her colleagues is unlikely to yield practical applications in the near future. “In security, and especially cryptography, it takes a long time to go from an academic idea to something that’s actually used in the real world,” Smart says. “They’re looking at what could be possible in 10, 20 years’ time.”


Topics: Computer Science and Artificial Intelligence Laboratory (CSAIL), Computer science and technology, Cryptography, Electrical engineering and electronics, Research, Multiparty protocols, Program obfuscation, Side-channel attacks

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Professor Goldwasser also teaches a 5-day course on campus that offers a unique approach to cryptography that you won't find in standard textbooks. It is based on the theory of provable security, and will ultimately enable you to assess cryptographic technologies with confidence, design cryptography that is error-proof, and understand many new technologies and their potential applications. Cryptography and Computer Security - August 6-10, 2012 Learn more at: http://shortprograms.mit.edu/6.87
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