Efficient Cache Attacks on AES, and Countermeasures

We describe several software side-channel attacks based on inter-process leakage through the state of the CPU's memory cache. This leakage reveals memory access patterns, which can be used for cryptanalysis of cryptographic primitives that employ data-dependent table lookups. The attacks allow an unprivileged process to attack other processes running in parallel on the same processor, despite partitioning methods such as memory protection, sandboxing, and virtualization. Some of our methods require only the ability to trigger services that perform encryption or MAC using the unknown key, such as encrypted disk partitions or secure network links. Moreover, we demonstrate an extremely strong type of attack, which requires knowledge of neither the specific plaintexts nor ciphertexts and works by merely monitoring the effect of the cryptographic process on the cache. We discuss in detail several attacks on AES and experimentally demonstrate their applicability to real systems, such as OpenSSL and Linux's dm-crypt encrypted partitions (in the latter case, the full key was recovered after just 800 writes to the partition, taking 65 milliseconds). Finally, we discuss a variety of countermeasures which can be used to mitigate such attacks.

Faster Software Cryptography

Dag Arne Osvik

This thesis presents work on the efficiency and security of cryptographic software. First it describes several efforts to construct very efficient implementations of cryptographic primitives. These include the Advanced Encryption Standard (AES) as well as several popular hash functions, spanning from the old MD5 to several candidates for the upcoming SHA-3 standard. Computer architectures considered range from low-end 8-bit microcontrollers to modern high-end graphics cards, and several key techniques for optimizing such implementations are presented. Results include compact implementations of SHA-1 and SHA-256 with reduced memory footprint and more than triple and double speed, respectively, compared with other fast implementations on the same architecture. Next it presents novel cryptanalytic attacks that can be performed on processor architectures with cache memories, like those used in modern personal computers. These belong to the category of side-channel attacks, exploiting unintended information leakage from an implementation to retrieve secret keys without having to find weaknesses in the cipher itself. The attacks even allow an unprivileged process to attack other processes running in parallel on the same processor, despite partitioning methods such as memory protection, sandboxing and virtualization. Practical results include full AES key recovery in 65ms using only write access to an encrypted partition. Finally the thesis investigates a technique for reducing the number of boolean operations required to express the AES round function, resulting in a significant improvement over previous efforts. This can be useful both for very compact AES implementations in hardware and for bitslice implementations of AES, in which software simulates many copies of the same compact hardware. Such software eliminates the table lookups exploited in cache attacks, and hence this kind of implementaton can be completely immune to them.

EPFL2012

Broadcast Encryption and Traitor Tracing for Conditional Access Systems

Alexandre Karlov

In the context of the thesis we are studying the notions of broadcast encryption and traitor tracing in an industrial framework of conditional access systems related to Pay-TV. Broadcast encryption represents a cryptographic primitive which allows confidential transmission of content on a broadcast channel in such a way that only an authorized subset of users defined by the broadcaster are able to access it. Traitor tracing is a mechanism for identifying rogue sources who shared their decryption keys. Combined together, these two methods can be used to identify compromised terminals and instantaneously revoke them. Intuitively these two techniques are of high interest for Pay-TV systems with respect to the threats of today. Today, the majority of industrial security system are based on the tamper-resistance against attacks, such as those exploiting, for instance, different side channel information such as time, power consumption, electromagnetic emanations to name a few. However during recent years these attacks became more and more sophisticated. Therefore the aim of this thesis is to propose new schemes and mechanisms to improve the state-of-the-art for the conditional access systems and more specifically Pay-TV systems so that they rely even more on a solid cryptographic basis. As a matter of fact, even though many cryptographic schemes closely related to the subject of this thesis existed since many years in academia, none of them could have been deployed directly and efficiently in the context of large scale Pay-TV system which puts a number of heavy constraints on the bandwidth as well as on the computational complexity of the receivers. Consequently we will also describe the system and its constraints in order to simplify the task of development and integration of future schemes in these two academic domains in the context of practical environment.

EPFL2011

Computer Aided Cryptanalysis from Ciphers to Side Channels

Martin Vuagnoux

In this dissertation, we study the security of cryptographic protocols and cryptosystems from the mathematical definition of the primitives, up to their physical implementations in the real world. We propose a representation of the chronological design using six layers (cryptographic primitives, cryptographic protocols, implementation, computer insecurity, side channel cryptanalysis and computer human interactions). We do the assumption that these layers should not be studied independently. Indeed, many negligible security weaknesses coming from different layers can be correlated to provide devastating practical attacks on cryptosystems. However, the complexity of a complete security analysis becomes huge and interdisciplinary knowledge is needed. These limitations are probably the reasons of the lack of complete security analysis in practice. We define a novel approach, to combine and study the six layers simultaneously. We propose to follow the data flow of a system and to perform security analysis across the six layers. This technique is applied in practice to the security analysis of computer keyboards, RC4, IEEE 802.11, and e-passports. Thanks to this method, we found 34 additional exploitable correlations in RC4 and we defined the best key recovery attacks on WEP and WPA. We also identified weaknesses in the design and the implementation of e-passports. Therefore, we show that the security risk of every layer seems to be related to its level of complexity. Thus, the implementation layer, the computer insecurity layer, the side channel layer and the computer human interfaces layer are subject to cost-effective attacks in practice. Interestingly, these layers are not intensively studied in cryptography, where research stays usually focused on the two first layers (and some side channel attacks). In this dissertation, we also propose frameworks for computer aided cryptanalysis. Indeed, when the complexity of a system is too important to perform manual analysis, some tools may automatically find weaknesses. Increasing complexity in systems adds new vulnerabilities. Straightforward but automated analysis becomes relevant. Two frameworks have been developed. The first one automatically highlights linear correlation in RC4. The second framework, called Autodafé automatically detects buffer overflows in modern software, using a technique called Fuzzing by Weighting Attacks with Markers.