Paper Info
Title
More Efficient Oblivious Transfer and Extensions for Faster Secure Computation
Abstract
Protocols for secure computation enable parties to compute a joint function on their private inputs without revealing anything but the result. A foundation for secure computation is oblivious transfer (OT), which traditionally requires expensive public key cryptography. A more efficient way to perform many OTs is to extend a small number of base OTs using OT extensions based on symmetric cryptography.\ In this work we present optimizations and efficient implementations of OT and OT extensions in the semi-honest model. We propose a novel OT protocol with security in the standard model and improve OT extensions with respect to communication complexity, computation complexity, and scalability. We also provide specific optimizations of OT extensions that are tailored to the secure computation protocols of Yao and Goldreich-Micali-Wigderson and reduce the communication complexity even further. We experimentally verify the efficiency gains of our protocols and optimizations. By applying our implementation to current secure computation frameworks, we can securely compute a Levenshtein distance circuit with 1.29 billion AND gates at a rate of 1.2 million AND gates per second. Moreover, we demonstrate the importance of correctly implementing OT within secure computation protocols by presenting an attack on the FastGC framework.
Year
DOI
DocType
2013
10.1145/2508859.2516738
Conference
Citations 
PageRank 
References 
83
1.94
46
Authors
4
Name
Order
Citations
PageRank
Gilad Asharov141423.31
Yehuda Lindell24194215.46
Thomas Schneider3154069.17
Michael Zohner440913.44