Alan Ehret

Rashmi Agrawal, Lake Bu, Alan Ehret et al.

In this work, we propose an open-source, first-of-its-kind, arithmetic hardware library with a focus on accelerating the arithmetic operations involved in Ring Learning with Error (RLWE)-based somewhat homomorphic encryption (SHE). We design and implement a hardware accelerator consisting of submodules like Residue Number System (RNS), Chinese Remainder Theorem (CRT), NTT-based polynomial multiplication, modulo inverse, modulo reduction, and all the other polynomial and scalar operations involved in SHE. For all of these operations, wherever possible, we include a hardware-cost efficient serial and a fast parallel implementation in the library. A modular and parameterized design approach helps in easy customization and also provides flexibility to extend these operations for use in most homomorphic encryption applications that fit well into emerging FPGA-equipped cloud architectures. Using the submodules from the library, we prototype a hardware accelerator on FPGA. The evaluation of this hardware accelerator shows a speed up of approximately 4200x and 2950x to evaluate a homomorphic multiplication and addition respectively when compared to an existing software implementation.

Michel A. Kinsy, Mihailo Isakov, Alan Ehret et al.

In this work, we introduce a Self-Aware Polymorphic Architecture (SAPA) design approach to support emerging context-aware applications and mitigate the programming challenges caused by the ever-increasing complexity and heterogeneity of high performance computing systems. Through the SAPA design, we examined the salient software-hardware features of adaptive computing systems that allow for (1) the dynamic allocation of computing resources depending on program needs (e.g., the amount of parallelism in the program) and (2) automatic approximation to meet program and system goals (e.g., execution time budget, power constraints and computation resiliency) without the programming complexity of current multicore and many-core systems. The proposed adaptive computer architecture framework applies machine learning algorithms and control theory techniques to the application execution based on information collected about the system runtime performance trade-offs. It has heterogeneous reconfigurable cores with fast hardware-level migration capability, self-organizing memory structures and hierarchies, an adaptive application-aware network-on-chip, and a built-in hardware layer for dynamic, autonomous resource management. Our prototyped architecture performs extremely well on a large pool of applications.

Michel A. Kinsy, Donato Kava, Alan Ehret et al.

Sphinx, a hardware-software co-design architecture for binary code and runtime obfuscation. The Sphinx architecture uses binary code diversification and self-reconfigurable processing elements to maintain application functionality while obfuscating the binary code and architecture states to attackers. This approach dramatically reduces an attacker's ability to exploit information gained from one deployment to attack another deployment. Our results show that the Sphinx is able to decouple the program's execution time, power and memory and I/O activities from its functionality. It is also practical in the sense that the system (both software and hardware) overheads are minimal.