18,481 research outputs found
Instantaneous Decentralized Poker
We present efficient protocols for amortized secure multiparty computation
with penalties and secure cash distribution, of which poker is a prime example.
Our protocols have an initial phase where the parties interact with a
cryptocurrency network, that then enables them to interact only among
themselves over the course of playing many poker games in which money changes
hands.
The high efficiency of our protocols is achieved by harnessing the power of
stateful contracts. Compared to the limited expressive power of Bitcoin
scripts, stateful contracts enable richer forms of interaction between standard
secure computation and a cryptocurrency.
We formalize the stateful contract model and the security notions that our
protocols accomplish, and provide proofs using the simulation paradigm.
Moreover, we provide a reference implementation in Ethereum/Solidity for the
stateful contracts that our protocols are based on.
We also adopt our off-chain cash distribution protocols to the special case
of stateful duplex micropayment channels, which are of independent interest. In
comparison to Bitcoin based payment channels, our duplex channel implementation
is more efficient and has additional features
Betrayal, Distrust, and Rationality: Smart Counter-Collusion Contracts for Verifiable Cloud Computing
Cloud computing has become an irreversible trend. Together comes the pressing
need for verifiability, to assure the client the correctness of computation
outsourced to the cloud. Existing verifiable computation techniques all have a
high overhead, thus if being deployed in the clouds, would render cloud
computing more expensive than the on-premises counterpart. To achieve
verifiability at a reasonable cost, we leverage game theory and propose a smart
contract based solution. In a nutshell, a client lets two clouds compute the
same task, and uses smart contracts to stimulate tension, betrayal and distrust
between the clouds, so that rational clouds will not collude and cheat. In the
absence of collusion, verification of correctness can be done easily by
crosschecking the results from the two clouds. We provide a formal analysis of
the games induced by the contracts, and prove that the contracts will be
effective under certain reasonable assumptions. By resorting to game theory and
smart contracts, we are able to avoid heavy cryptographic protocols. The client
only needs to pay two clouds to compute in the clear, and a small transaction
fee to use the smart contracts. We also conducted a feasibility study that
involves implementing the contracts in Solidity and running them on the
official Ethereum network.Comment: Published in ACM CCS 2017, this is the full version with all
appendice
On the Design of Cryptographic Primitives
The main objective of this work is twofold. On the one hand, it gives a brief
overview of the area of two-party cryptographic protocols. On the other hand,
it proposes new schemes and guidelines for improving the practice of robust
protocol design. In order to achieve such a double goal, a tour through the
descriptions of the two main cryptographic primitives is carried out. Within
this survey, some of the most representative algorithms based on the Theory of
Finite Fields are provided and new general schemes and specific algorithms
based on Graph Theory are proposed
TumbleBit: an untrusted Bitcoin-compatible anonymous payment hub
This paper presents TumbleBit, a new unidirectional unlinkable payment hub that is fully compatible with today s Bitcoin protocol. TumbleBit allows parties to make fast, anonymous, off-blockchain payments through an untrusted intermediary called the Tumbler. TumbleBits anonymity properties are similar to classic Chaumian eCash: no one, not even the Tumbler, can link a payment from its payer to its payee. Every payment made via TumbleBit is backed by bitcoins, and comes with a guarantee that Tumbler can neither violate anonymity, nor steal bitcoins, nor print money by issuing payments to itself. We prove the security of TumbleBit using the real/ideal world paradigm and the random oracle model. Security follows from the standard RSA assumption and ECDSA unforgeability. We implement TumbleBit, mix payments from 800 users and show that TumbleBits offblockchain payments can complete in seconds.https://eprint.iacr.org/2016/575.pdfPublished versio
Secure Multiparty Computation with Partial Fairness
A protocol for computing a functionality is secure if an adversary in this
protocol cannot cause more harm than in an ideal computation where parties give
their inputs to a trusted party which returns the output of the functionality
to all parties. In particular, in the ideal model such computation is fair --
all parties get the output. Cleve (STOC 1986) proved that, in general, fairness
is not possible without an honest majority. To overcome this impossibility,
Gordon and Katz (Eurocrypt 2010) suggested a relaxed definition -- 1/p-secure
computation -- which guarantees partial fairness. For two parties, they
construct 1/p-secure protocols for functionalities for which the size of either
their domain or their range is polynomial (in the security parameter). Gordon
and Katz ask whether their results can be extended to multiparty protocols.
We study 1/p-secure protocols in the multiparty setting for general
functionalities. Our main result is constructions of 1/p-secure protocols when
the number of parties is constant provided that less than 2/3 of the parties
are corrupt. Our protocols require that either (1) the functionality is
deterministic and the size of the domain is polynomial (in the security
parameter), or (2) the functionality can be randomized and the size of the
range is polynomial. If the size of the domain is constant and the
functionality is deterministic, then our protocol is efficient even when the
number of parties is O(log log n) (where n is the security parameter). On the
negative side, we show that when the number of parties is super-constant,
1/p-secure protocols are not possible when the size of the domain is
polynomial
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