TY - JOUR
T1 - Efficiency and Accuracy Improvements of Secure Floating-Point Addition over Secret Sharing
AU - Sasaki, Kota
AU - Nuida, Koji
N1 - Publisher Copyright:
© 2022 Institute of Electronics, Information and Communication, Engineers, IEICE. All rights reserved.
PY - 2022
Y1 - 2022
N2 - In secure multiparty computation (MPC), floating-point numbers should be handled in many potential applications, but these are basically expensive. In particular, for MPC based on secret sharing (SS), the floating-point addition takes many communication rounds though the addition is the most fundamental operation. In this paper, we propose an SS-based two-party protocol for floating-point addition with 13 rounds (for single/double precision numbers), which is much fewer than the milestone work of Aliasgari et al. in NDSS 2013 (34 and 36 rounds, respectively) and also fewer than the state of the art in the literature. Moreover, in contrast to the existing SS-based protocols which are all based on "roundTowardZero" rounding mode in the IEEE 754 standard, we propose another protocol with 15 rounds which is the first result realizing more accurate "roundTiesTo- Even" rounding mode. We also discuss possible applications of the latter protocol to secure Validated Numerics (a.k.a. Rigorous Computation) by implementing a simple example.
AB - In secure multiparty computation (MPC), floating-point numbers should be handled in many potential applications, but these are basically expensive. In particular, for MPC based on secret sharing (SS), the floating-point addition takes many communication rounds though the addition is the most fundamental operation. In this paper, we propose an SS-based two-party protocol for floating-point addition with 13 rounds (for single/double precision numbers), which is much fewer than the milestone work of Aliasgari et al. in NDSS 2013 (34 and 36 rounds, respectively) and also fewer than the state of the art in the literature. Moreover, in contrast to the existing SS-based protocols which are all based on "roundTowardZero" rounding mode in the IEEE 754 standard, we propose another protocol with 15 rounds which is the first result realizing more accurate "roundTiesTo- Even" rounding mode. We also discuss possible applications of the latter protocol to secure Validated Numerics (a.k.a. Rigorous Computation) by implementing a simple example.
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U2 - 10.1587/transfun.2021CIP0013
DO - 10.1587/transfun.2021CIP0013
M3 - Article
AN - SCOPUS:85126635079
SN - 0916-8508
VL - 105
SP - 231
EP - 241
JO - IEICE Transactions on Fundamentals of Electronics, Communications and Computer Sciences
JF - IEICE Transactions on Fundamentals of Electronics, Communications and Computer Sciences
IS - 3
ER -