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Round-Efficient Black-Box Construction of Composable Multi-Party Computation
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Abstract: | We present a round-efficient black-box construction of a general multi-party computation (MPC) protocol that satisfies composability in the plain model. The security of our protocol is proven in the angel-based UC framework [Prabhakaran and Sahai, STOC’04] under the minimal assumption of the existence of semi-honest oblivious transfer protocols. The round complexity of our protocol is $$\max (\widetilde{O}(\log ^2n), O(R_{{{{\mathsf {O}}}{{\mathsf {T}}}}}))$$ max ( O ~ ( log 2 n ) , O ( R O T ) ) when the round complexity of the underlying oblivious transfer protocol is $$R_{{{{\mathsf {O}}}{{\mathsf {T}}}}}$$ R O T . Since constant-round semi-honest oblivious transfer protocols can be constructed under standard assumptions (such as the existence of enhanced trapdoor permutations), our result gives a $$\widetilde{O}(\log ^2n)$$ O ~ ( log 2 n ) -round protocol under these assumptions. Previously, only an $$O(\max (n^{\epsilon }, R_{{{{\mathsf {O}}}{{\mathsf {T}}}}}))$$ O ( max ( n ϵ , R O T ) ) -round protocol was shown, where $$\epsilon >0$$ ϵ > 0 is an arbitrary constant. We obtain our MPC protocol by constructing a $$\widetilde{O}(\log ^2n)$$ O ~ ( log 2 n ) -round CCA-secure commitment scheme in a black-box way under the assumption of the existence of one-way functions. |
BibTeX
@article{jofc-2019-30146, title={Round-Efficient Black-Box Construction of Composable Multi-Party Computation}, journal={Journal of Cryptology}, publisher={Springer}, volume={32}, pages={178-238}, doi={10.1007/s00145-018-9276-1}, author={Susumu Kiyoshima}, year=2019 }