2020
Autores
Abdalla, M; Barbosa, M; Bradley, T; Jarecki, S; Katz, J; Xu, J;
Publicação
IACR Cryptol. ePrint Arch.
Abstract
2018
Autores
Barbosa, M; Farshim, P;
Publicação
IACR Cryptology ePrint Archive
Abstract
2017
Autores
Barbosa, Manuel; Catalano, Dario; Fiore, Dario;
Publicação
IACR Cryptology ePrint Archive
Abstract
2017
Autores
Bahmani, R; Barbosa, M; Brasser, F; Portela, B; Sadeghi, AR; Scerri, G; Warinschi, B;
Publicação
Financial Cryptography and Data Security - 21st International Conference, FC 2017, Sliema, Malta, April 3-7, 2017, Revised Selected Papers
Abstract
In this paper we show how Isolated Execution Environments (IEE) offered by novel commodity hardware such as Intel’s SGX provide a new path to constructing general secure multiparty computation (MPC) protocols. Our protocol is intuitive and elegant: it uses code within an IEE to play the role of a trusted third party (TTP), and the attestation guarantees of SGX to bootstrap secure communications between participants and the TTP. The load of communications and computations on participants only depends on the size of each party’s inputs and outputs and is thus small and independent from the intricacies of the functionality to be computed. The remaining computational load– essentially that of computing the functionality – is moved to an untrusted party running an IEE-enabled machine, an attractive feature for Cloud-based scenarios. Our rigorous modular security analysis relies on the novel notion of labeled attested computation which we put forth in this paper. This notion is a convenient abstraction of the kind of attestation guarantees one can obtain from trusted hardware in multi-user scenarios. Finally, we present an extensive experimental evaluation of our solution on SGX-enabled hardware. Our implementation is open-source and it is functionality agnostic: it can be used to securely outsource to the Cloud arbitrary off-the-shelf collaborative software, such as the one employed on financial data applications, enabling secure collaborative execution over private inputs provided by multiple parties. © 2017, International Financial Cryptography Association.
2023
Autores
Almeida, JB; Barbosa, M; Barthe, G; Grégoire, B; Laporte, V; Léchenet, JC; Oliveira, T; Pacheco, H; Quaresma, M; Schwabe, P; Séré, A; Strub, PY;
Publicação
IACR Cryptol. ePrint Arch.
Abstract
2021
Autores
Almeida, JB; Barbosa, M; Correia, ML; Eldefrawy, K; Lengrand, SG; Pacheco, H; Pereira, V;
Publicação
IACR Cryptol. ePrint Arch.
Abstract
The access to the final selection minute is only available to applicants.
Please check the confirmation e-mail of your application to obtain the access code.