Resettable Zero Knowledge in the Bare Public-Key Model under Standard Assumption

In this paper we resolve an open problem regarding resettable zero knowledge in the bare public-key (BPK for short) model: Does there exist constant round resettable zero knowledge argument with concurrent soundness for $\mathcal{NP}$ in BPK model without assuming \emph{sub-exponential hardness}? We give a positive answer to this question by presenting such a protocol for any language in $\mathcal{NP}$ in the bare public-key model assuming only collision-resistant hash functions against \emph{polynomial-time} adversaries.Comment: 19 pag

Concurrently Non-Malleable Zero Knowledge in the Authenticated Public-Key Model

We consider a type of zero-knowledge protocols that are of interest for their practical applications within networks like the Internet: efficient zero-knowledge arguments of knowledge that remain secure against concurrent man-in-the-middle attacks. In an effort to reduce the setup assumptions required for efficient zero-knowledge arguments of knowledge that remain secure against concurrent man-in-the-middle attacks, we consider a model, which we call the Authenticated Public-Key (APK) model. The APK model seems to significantly reduce the setup assumptions made by the CRS model (as no trusted party or honest execution of a centralized algorithm are required), and can be seen as a slightly stronger variation of the Bare Public-Key (BPK) model from \cite{CGGM,MR}, and a weaker variation of the registered public-key model used in \cite{BCNP}. We then define and study man-in-the-middle attacks in the APK model. Our main result is a constant-round concurrent non-malleable zero-knowledge argument of knowledge for any polynomial-time relation (associated to a language in $\mathcal{NP}$), under the (minimal) assumption of the existence of a one-way function family. Furthermore,We show time-efficient instantiations of our protocol based on known number-theoretic assumptions. We also note a negative result with respect to further reducing the setup assumptions of our protocol to those in the (unauthenticated) BPK model, by showing that concurrently non-malleable zero-knowledge arguments of knowledge in the BPK model are only possible for trivial languages

Concurrent Knowledge-Extraction in the Public-Key Model

Knowledge extraction is a fundamental notion, modelling machine possession of values (witnesses) in a computational complexity sense. The notion provides an essential tool for cryptographic protocol design and analysis, enabling one to argue about the internal state of protocol players without ever looking at this supposedly secret state. However, when transactions are concurrent (e.g., over the Internet) with players possessing public-keys (as is common in cryptography), assuring that entities ``know'' what they claim to know, where adversaries may be well coordinated across different transactions, turns out to be much more subtle and in need of re-examination. Here, we investigate how to formally treat knowledge possession by parties (with registered public-keys) interacting over the Internet. Stated more technically, we look into the relative power of the notion of ``concurrent knowledge-extraction'' (CKE) in the concurrent zero-knowledge (CZK) bare public-key (BPK) model.Comment: 38 pages, 4 figure

A constant-round resettably-sound resettable zero-knowledge argument in the BPK model

In resetting attacks against a proof system, a prover or a verifier is reset and enforced to use the same random tape on various inputs as many times as an adversary may want. Recent deployment of cloud computing gives these attacks a new importance. This paper shows that argument systems for any NP language that are both resettably-sound and resettable zero-knowledge are possible by a constant-round protocol in the BPK model. For that sake, we define and construct a resettably-extractable {\em conditional} commitment scheme

Resettable Cryptography in Constant Rounds -- the Case of Zero Knowledge

A fundamental question in cryptography deals with understanding the role that randomness plays in cryptographic protocols and to what extent it is necessary. One particular line of works was initiated by Canetti, Goldreich, Goldwasser, and Micali (STOC 2000) who introduced the notion of resettable zero-knowledge, where the protocol must be zero-knowledge even if a cheating verifier can reset the prover and have several interactions in which the prover uses the same random tape. Soon afterwards, Barak, Goldreich, Goldwasser, and Lindell (FOCS 2001) studied the setting where the \emph{verifier} uses a fixed random tape in multiple interactions. Subsequent to these works, a number of papers studied the notion of resettable protocols in the setting where \emph{only one} of the participating parties uses a fixed random tape multiple times. The notion of resettable security has been studied in two main models: the plain model and the bare public key model (also introduced in the above paper by Canetti et. al.). In a recent work, Deng, Goyal and Sahai (FOCS 2009) gave the first construction of a \emph{simultaneous} resettable zero-knowledge protocol where both participants of the protocol can reuse a fixed random tape in any (polynomial) number of executions. Their construction however required $O(n^\epsilon)$ rounds of interaction between the prover and the verifier. Both in the plain as well as the BPK model, this construction remain the only known simultaneous resettable zero-knowledge protocols. In this work, we study the question of round complexity of simultaneous resettable zero-knowledge in the BPK model. We present a \emph{constant round} protocol in such a setting based on standard cryptographic assumptions. Our techniques are significantly different from the ones used by Deng, Goyal and Sahai

Concurrent/Resettable Zero-Knowledge With Concurrent Soundness in the Bare Public-Key Model and Its Applications

In this work, we investigate concurrent knowledge-extraction (CKE) and concurrent non-malleability (CNM) for concurrent (and stronger, resettable) ZK protocols in the bare public-key model. We formulate, driven by concrete attacks, and achieve CKE for constant-round concurrent/resettable arguments in the BPK model under standard polynomial assumptions. We get both generic and practical implementations. Here, CKE is a new concurrent verifier security that is strictly stronger than concurrent soundness in public-key model. We investigate, driven by concrete attacks, and clarify the subtleties in formulating CNM in the public-key model. We then give a new (augmented) CNM formulation in the public-key model and a construction of CNMZK in the public-key model satisfying the new CNM formulation

Improved OR-Composition of Sigma-Protocols

In [CDS94] Cramer, Damg̊ard and Schoenmakers (CDS) devise an OR-composition technique for Σ-protocols that allows to construct highly-efficient proofs for compound statements. Since then, such technique has found countless applications as building block for designing efficient protocols. Unfortunately, the CDS OR-composition technique works only if both statements are fixed before the proof starts. This limitation restricts its usability in those protocols where the theorems to be proved are defined at different stages of the protocol, but, in order to save rounds of communication, the proof must start even if not all theorems are available. Many round-optimal protocols ([KO04, DPV04, YZ07, SV12]) crucially need such property to achieve round-optimality, and, due to the inapplicability of CDS’s technique, are currently implemented using proof systems that requires expensive NP reductions, but that allow the proof to start even if no statement is defined (a.k.a., LS proofs from Lapidot-Shamir [LS90]). In this paper we show an improved OR-composition technique for Σ-protocols, that requires only one statement to be fixed when the proof starts, while the other statement can be define

Constant-Round Concurrent Non-Malleable Zero Knowledge in the Bare Public-Key Model

One of the central questions in Cryptography is the design of round-efficient protocols that are secure under concurrent man-in-the- middle attacks. In this paper we present the first constant-round concurrent non-malleable zero-knowledge argument system for NP in the Bare Public-Key model [Canetti et al., STOC 2000], resolving one of the major open problems in this area. To achieve our result, we introduce and study the notion of non-malleable witness indistinguishability, which is of independent interest. Previous results either achieved relaxed forms of concurrency/security or needed stronger setup assumptions or required a non-constant round complexity

New Notions of Soundness and Simultaneous Resettability in the Public-Key Model

I n this paper, some new notions of soundness in public-key model are presented. We clarify the relationships among our new notions of soundness and the original 4 soundness notions presented by Micali and Reyzin. Our new soundness notions also characterize a new model for ZK protocols in public key model: weak soundness model. By ``weak” we mean for each common input x selected by a malicious prover on the fly, x is used by the malicious prover at most a-priori bounded polynomial times. The weak soundness model just lies in between BPK model and UPK model. Namely, it is weaker than BPK model but stronger than UPK model. In the weak soundness model (also in the UPK model, since weak soundness model implies UPK model), we get a 3-round black-box rZK arguments with weak resettable soundness for NP. Note that simultaneous resettability is an important open problem in the field of ZK protocols. And Reyzin has proven that there are no ZK protocols with resettable soundness in the BPK model. It means that to achieve simultaneous resettability one needs to augment the BPK model in a reasonable fashion. Although Barak et al. [BGGL01] have proven that any language which has a black-box ZK arguments with resettable soundness is in BPP. It is the weak soundness that makes us to get simultaneous resettability. More interestingly, our protocols work in a somewhat ``parallel repetition” manner to reduce the error probability and the verifier indeed has secret information with respect to historical transcripts. Note that in general the error probability of such protocols can not be reduced by parallel repetition. [BIN97] At last, we give a 3-round non-black-box rZK arguments system with resettable soundness for NP in the preprocessing model in which a trusted third party is assumed. Our construction for such protocol is quite simple. Note that although the preprocessing model is quite imposing but it is still quite reasonable as indicated in [CGGM00]. For example, in many e-commerce setting a trusted third party is often assumed. The critical tools used in this paper are: verifiable pseudorandom functions, zap and complexity leveraging. To our knowledge, our protocols are also the second application of verifiable pseudorandom functions. The first application is the 3-round rZK arguments with one-time soundness for NP in the public-key model as indicated by Micali and Reyzin [MR01a]