## CryptoDB

### Rafail Ostrovsky

#### Publications

**Year**

**Venue**

**Title**

2022

PKC

CNF-FSS and its Applications
Abstract

Function Secret Sharing (FSS), introduced by Boyle, Gilboa and Ishai~\cite{BGI15}, extends the classical notion of secret-sharing a \textit{value} to secret sharing a \textit{function}. Namely, for a secret function $f$ (from a class $\cal F$), FSS provides a sharing of $f$ whereby {\em succinct} shares (``keys'') are distributed to a set of parties, so that later the parties can non-interactively compute an additive sharing of $f(x)$, for any input $x$ in the domain of $f$.
Previous work on FSS concentrated mostly on the two-party case, where highly efficient schemes are obtained for some simple, yet extremely useful, classes $\cal F$ (in particular, FSS for the class of point functions, a task referred to as DPF~--~Distributed Point Functions~\cite{GI14,BGI15}).
In this paper, we concentrate on the multi-party case, with $p\ge 3$ parties and $t$-security ($1\le t<p$). First, we introduce the notion of \textsf{CNF-DPF} (or, more generally, \textsf{CNF-FSS}), where the scheme uses the CNF version of secret sharing (rather than additive sharing) to share each value $f(x)$. We then demonstrate the utility of CNF-DPF by providing several applications. Our main result shows how CNF-DPF can be used to achieve substantial asymptotic improvement in communication complexity when using it as a building block for constructing {\em standard} $(t,p)$-DPF protocols that tolerate $t>1$ (semi-honest) corruptions (of the $p$ parties). For example, we build a 2-out-of-5 secure (standard) DPF scheme of communication complexity $O(N^{1/4})$, where $N$ is the domain size of $f$ (compared with the current best-known of $O(N^{1/2})$ for $(2,5)$-DPF). More generally, with $p>dt$ parties, we give a $(t,p)$-DPF whose communication grows as $O(N^{1/2d})$ (rather than $O(\sqrt{N})$ that follows from the $(p-1,p)$-DPF scheme of \cite{BGI15}).
We also present a 1-out-of-3 secure CNF-DPF scheme, in which each party holds two of the three keys, with poly-logarithmic communication complexity. These results have immediate implications to scenarios where (multi-server) DPF was shown to be applicable. For example, we show how to use such a scheme to obtain asymptotic improvement ($O(\log^2N)$ versus $O(\sqrt{N})$) in communication complexity over the 3-party protocol of~\cite{BKKO20}.

2021

EUROCRYPT

Alibi: A Flaw in Cuckoo-Hashing based Hierarchical ORAM Schemes and a Solution
📺
Abstract

There once was a table of hashes
That held extra items in stashes
It all seemed like bliss
But things went amiss
When the stashes were stored in the caches
The first Oblivious RAM protocols introduced the ``hierarchical solution,''
(STOC '90) where the server stores a series of hash tables of geometrically increasing capacities.
Each ORAM query would read a small number of locations from each level of the hierarchy,
and each level of the hierarchy would be reshuffled and rebuilt at geometrically increasing intervals to ensure that
no single query was ever repeated twice at the same level. This yielded an ORAM protocol with polylogarithmic overhead.
Future works extended and improved the hierarchical solution, replacing traditional hashing with cuckoo
hashing (ICALP '11) and cuckoo hashing with a combined stash (Goodrich et al. SODA '12).
In this work, we identify a subtle flaw in the protocol of Goodrich et al. (SODA '12)
that uses cuckoo hashing with a stash in the hierarchical ORAM solution.
We give a concrete distinguishing attack against this type of hierarchical ORAM
that uses cuckoo hashing with a \emph{combined} stash.
This security flaw has propagated to at least 5 subsequent
hierarchical ORAM protocols,
including the recent optimal ORAM scheme, OptORAMa (Eurocrypt '20).
In addition to our attack, we identify a simple fix that
does not increase the asymptotic complexity.
We note, however, that our attack only affects more recent \emph{hierarchical ORAMs},
but does not affect the early protocols that predate the use of cuckoo hashing,
or other types of ORAM solutions (e.g. Path ORAM or Circuit ORAM).

2021

EUROCRYPT

Threshold Garbled Circuits and Ad Hoc Secure Computation
📺
Abstract

Garbled Circuits (GCs) represent fundamental and powerful tools in cryptography, and many variants of GCs have been considered since their introduction. An important property of the garbled circuits is that they can be evaluated securely if and only if exactly 1 key for each input wire is obtained: no less and no more. In this work we study the case when: 1) some of the wire-keys are missing, but we are still interested in computing the output of the garbled circuit and 2) the evaluator of the GC might have both keys for a constant number of wires. We start to study this question in terms of non-interactive multi-party computation (NIMPC) which is strongly connected with GCs. In this notion, there is a fixed number of parties (n) that can get correlated information from a trusted setup. Then these parties can send an encoding of their input to an evaluator, which can compute the output of the function. Similarly to the notion of ad hoc secure computation proposed by Beimel et al. [ITCS 2016], we consider the case when less than n parties participate in the online phase, and in addition we let these parties colluding with the evaluator. We refer to this notion as Threshold NIMPC.
In addition, we show that when the number of parties participating in the online phase is a fixed threshold l <= n then it is possible to securely evaluate any l-input function. We build our result on top of a new secret-sharing scheme (which can be of independent interest) and on the results proposed by Benhamouda, Krawczyk and Rabin [Crypto 2017]. Our protocol can be used to compute any function in NC1 in the information-theoretic setting and any function in P assuming one-way functions.
As a second (and main) contribution, we consider a slightly different notion of security in which the number of parties that can participate in the online phase is not specified, and can be any number c above the threshold l (in this case the evaluator cannot collude with the other parties). We solve an open question left open by Beimel, Ishai and Kushilevitz [Eurocrypt 2017] showing how to build a secure protocol for the case when c is constant, under the Learning with Errors assumption.

2021

CRYPTO

ATLAS: Efficient and Scalable MPC in the Honest Majority Setting
📺
Abstract

In this work, we address communication, computation, and round efficiency of unconditionally secure multi-party computation for arithmetic circuits in the honest majority setting. We achieve both algorithmic and practical improvements:
- The best known result in the semi-honest setting has been due to Damgard and Nielsen (CRYPTO 2007). Over the last decade, their construction has played an important role in the progress of efficient secure computation. However despite a number of follow-up works, any significant improvements to the basic semi-honest protocol have been hard to come by. We show 33% improvement in communication complexity of this protocol. We show how to generalize this result to the malicious setting, leading to the best known unconditional honest majority MPC with malicious security.
- We focus on the round complexity of the Damgard and Nielsen protocol and improve it by a factor of 2. Our improvement relies on a novel observation relating to an interplay between Damgard and Nielsen multiplication and Beaver triple multiplication. An implementation of our constructions shows an execution run time improvement compared to the state of the art ranging from 30% to 50%.

2021

ASIACRYPT

How to Build a Trapdoor Function from an Encryption Scheme
📺
Abstract

In this work we ask the following question: Can we transform any encryption scheme into a trapdoor function (TDF)? Alternatively stated, can we make any encryption scheme randomness recoverable? We propose a generic compiler that takes as input any encryption scheme with pseudorandom ciphertexts and adds a trapdoor to invert the encryption, recovering also the random coins. This universal TDFier only assumes in addition the existence of a hinting pseudorandom generator (PRG). Despite the simplicity, our transformation is quite general and we establish a series of new feasibility results:
- The first identity-based TDF [Bellare et al. EUROCRYPT 2012] from the CDH assumption in pairing-free groups (or from factoring), thus matching the state of the art for identity-based encryption schemes. Prior works required pairings or LWE.
- The first collusion-resistant attribute-based TDF (AB-TDF) for all ($NC^1$, resp.) circuits from LWE (bilinear maps, resp.). Moreover, the first single-key AB-TDF from CDH. To the best of our knowledge, no AB-TDF was known in the literature (not even for a single key) from any assumption. We obtain the same results for predicate encryption.
As an additional contribution, we define and construct a trapdoor garbling scheme: A simulation secure garbling scheme with a hidden ``trigger'' that allows the evaluator to fully recover the randomness used by the garbling algorithm. We show how to construct trapdoor garbling from the DDH or LWE assumption with an interplay of key-dependent message (KDM) and randomness-dependent message (RDM) techniques.
Trapdoor garbling allows us to obtain alternative constructions of (single-key) AB-TDFs with additional desirable properties, such as adaptive security (in the choice of the attribute) and projective keys. We expect trapdoor garbling to be useful in other contexts, e.g. in case where, upon successful execution, the evaluator needs to immediately verify that the garbled circuit was well-formed.

2021

TCC

Oblivious Transfer from Trapdoor Permutations in Minimal Rounds
📺
Abstract

Oblivious transfer (OT) is a foundational primitive within cryptography owing to its connection with secure computation. One of the oldest constructions of oblivious transfer was from certified trapdoor permutations (TDPs). However several decades later, we do not know if a similar construction can be obtained from TDPs in general.
In this work, we study the problem of constructing round optimal oblivious transfer from trapdoor permutations. In particular, we obtain the following new results (in the plain model) relying on TDPs in a black-box manner:
– Three-round oblivious transfer protocol that guarantees indistinguishability-security against malicious senders (and semi-honest receivers).
– Four-round oblivious transfer protocol secure against malicious adversaries with black-box simulation-based security.
By combining our second result with an already known compiler we obtain the first round-optimal 2-party computation protocol that relies in a black-box way on TDPs.
A key technical tool underlying our results is a new primitive we call dual witness encryption (DWE) that may be of independent interest.

2020

TCC

Round Optimal Secure Multiparty Computation from Minimal Assumptions
📺
Abstract

We construct a four round secure multiparty computation (MPC) protocol in the plain model that achieves security against any dishonest majority. The security of our protocol relies only on the existence of four round oblivious transfer. This culminates the long line of research on constructing round-efficient MPC from minimal assumptions (at least w.r.t. black-box simulation).

2020

EUROCRYPT

Resource-Restricted Cryptography: Revisiting MPC Bounds in the Proof-of-Work Era
📺
Abstract

Traditional bounds on synchronous Byzantine agreement (BA) and secure multi-party computation (MPC) establish that in absence of a private correlated-randomness setup, such as a PKI,
protocols can tolerate up to $t<n/3$ of the parties being malicious. The introduction of ``Nakamoto style'' consensus, based on Proof-of-Work (PoW) blockchains, put forth a somewhat different flavor of BA,
showing that even a majority of corrupted parties
can be tolerated as long as the majority of the computation resources remain at honest hands. This assumption on honest majority of some resource was also extended to other resources such as stake, space, etc., upon which blockchains achieving Nakamoto-style consensus were built that violated the $t<n/3$ bound in terms of number of party corruptions. The above state of affairs
begs the question of whether the seeming mismatch is due to different goals and models, or whether the resource-restricting paradigm can be generically used to circumvent the $n/3$ lower bound.
In this work we study this question and formally demonstrate
how the above paradigm changes the rules of the game in cryptographic definitions.
First, we abstract the core properties that the resource-restricting paradigm offers by means of a functionality {\em wrapper}, in the UC framework, which when applied to a standard point-to-point network restricts the ability (of the adversary) to send new messages. We show that such a wrapped network can be implemented using the resource-restricting paradigm---concretely, using PoWs and honest majority of computing power---and that the traditional $t<n/3$ impossibility results fail when the parties have access to such a network. Our construction is in the {\em fresh} Common Reference String (CRS) model---i.e., it assumes a CRS which becomes available to the parties at the same time as to the adversary.
We then present constructions for BA and MPC, which given access to such a network tolerate $t<n/2$ corruptions without assuming a private correlated randomness setup. We also show how to remove the freshness assumption from the CRS by leveraging the power of a random oracle. Our MPC protocol achieves the standard notion of MPC security, where parties might have dedicated roles, as is for example the case in Oblivious Transfer protocols. This is in contrast to existing solutions basing MPC on PoWs, which associate roles to pseudonyms but do not link these pseudonyms with the actual parties.

2020

CRYPTO

On Succinct Arguments and Witness Encryption from Groups
📺
Abstract

Succinct non-interactive arguments (SNARGs) enable proofs of NP statements with very low communication. Recently, there has been significant work in both theory and practice on constructing SNARGs with very short proofs. Currently, the state-of-the-art in succinctness is due to Groth (Eurocrypt 2016) who constructed a SNARG from bilinear maps where the proof consists of just 3 group elements.
In this work, we first construct a concretely-efficient designated-verifier (preprocessing) SNARG with inverse polynomial soundness, where the proof consists of just 2 group elements in a standard (generic) group. This leads to a 50% reduction in concrete proof size compared to Groth's construction. We follow the approach of Bitansky et al. (TCC 2013) who describe a compiler from linear PCPs to SNARGs in the preprocessing model. Our improvement is based on a new linear PCP packing technique that allows us to construct 1-query linear PCPs which can then be compiled into a SNARG (using ElGamal encryption over a generic group). An appealing feature of our new SNARG is that the verifier can precompute a statement-independent lookup table in an offline phase; verifying proofs then only requires 2 exponentiations and a single table lookup. This makes our new designated-verifier SNARG appealing in settings that demand fast verification and minimal communication.
We then turn to the question of constructing arguments where the proof consists of a single group element. Here, we first show that any (possibly interactive) argument for a language L where the verification algorithm is "generic" (i.e., only performs generic group operations) and the proof consists of a single group element, implies a witness encryption scheme for L. We then show that under a yet-unproven, but highly plausible, hypothesis on the hardness of approximating the minimal distance of linear codes, we can construct a 2-message laconic argument for NP where the proof consists of a single group element. Under the same hypothesis, we obtain a witness encryption scheme for NP in the generic group model. Along the way, we show that under a conceptually-similar but proven hardness of approximation result, there is a 2-message laconic argument for NP with negligible soundness error where the prover's message consists of just 2 group elements. In both settings, we obtain laconic arguments (and linear PCPs) with linear decision procedures. Our constructions circumvent a previous lower bound by Groth on such argument systems with linear decision procedures by relying on imperfect completeness. Namely, our constructions have vanishing but not negligible completeness error, while the lower bound of Groth implicitly assumes negligible completeness error of the underlying argument. Our techniques thus highlight new avenues for designing linear PCPs, succinct arguments, and witness encryption schemes.

2020

TCC

Efficient Range-Trapdoor Functions and Applications: Rate-1 OT and More
Abstract

Substantial work on trapdoor functions (TDFs) has led to many powerful notions
and applications. However, despite tremendous work and progress, all known
constructions have prohibitively large public keys.
In this work, we introduce new techniques for realizing so-called range-trapdoor hash functions with short public keys. This notion, introduced by Döttling et al. [Crypto 2019], allows for encoding a range of indices into a public key in a way that the public key leaks no information about the range, yet an associated trapdoor enables recovery of the corresponding input part.
We give constructions of range-trapdoor hash functions, where for a given range $I$ the public key consists of $O(n)$ group elements, improving upon $O(n |I|)$ achieved by Döttling et al. Moreover, by designing our evaluation algorithm in a special way involving Toeplitz matrix multiplication and by showing how to perform fast-Fourier transforms in the exponent, we arrive at $O(n \log n)$ group operations for evaluation, improving upon $O(n^2)$, required of previous constructions. Our constructions rely on power-DDH assumptions in pairing-free groups.
As applications of our results we obtain
--- The first construction of (rate-1) lossy TDFs with public keys consisting of a linear number of group elements (without pairings).
--- Rate-1 string OT with receiver communication complexity of $O(n)$ group elements, where $n$ is the sender's message size, improving upon $O(n^2)$ [Crypto 2019]. This leads to a similar result in the context of private-information retrieval (PIR).
--- Semi-compact homomorphic encryption for branching programs: A construction of homomorphic encryption for branching programs, with ciphertexts consisting of $O(\lambda n d)$ group elements, improving upon $O(\lambda^2 n d)$. Here $\lambda $ denotes the security parameter, $n$ the input size and $d$ the depth of the program.

2020

JOFC

Oblivious Sampling with Applications to Two-Party k-Means Clustering
Abstract

The k -means clustering problem is one of the most explored problems in data mining. With the advent of protocols that have proven to be successful in performing single database clustering, the focus has shifted in recent years to the question of how to extend the single database protocols to a multiple database setting. To date, there have been numerous attempts to create specific multiparty k -means clustering protocols that protect the privacy of each database, but according to the standard cryptographic definitions of “privacy-protection”, so far all such attempts have fallen short of providing adequate privacy. In this paper, we describe a Two-Party k -Means Clustering Protocol that guarantees privacy against an honest-but-curious adversary, and is more efficient than utilizing a general multiparty “compiler” to achieve the same task. In particular, a main contribution of our result is a way to compute efficiently multiple iterations of k -means clustering without revealing the intermediate values. To achieve this, we describe a technique for performing two-party division securely and also introduce a novel technique allowing two parties to securely sample uniformly at random from an unknown domain size. The resulting Division Protocol and Random Value Protocol are of use to any protocol that requires the secure computation of a quotient or random sampling. Our techniques can be realized based on the existence of any semantically secure homomorphic encryption scheme. For concreteness, we describe our protocol based on Paillier Homomorphic Encryption scheme (see Paillier in Advances in: cryptology EURO-CRYPT’99 proceedings, LNCS 1592, pp 223–238, 1999). We will also demonstrate that our protocol is efficient in terms of communication, remaining competitive with existing protocols (such as Jagannathan and Wright in: KDD’05, pp 593–599, 2005) that fail to protect privacy.

2019

CRYPTO

Cryptographic Sensing
📺
Abstract

Is it possible to measure a physical object in a way that makes the measurement signals unintelligible to an external observer? Alternatively, can one learn a natural concept by using a contrived training set that makes the labeled examples useless without the line of thought that has led to their choice? We initiate a study of “cryptographic sensing” problems of this type, presenting definitions, positive and negative results, and directions for further research.

2019

EUROCRYPT

Private Anonymous Data Access
📺
Abstract

We consider a scenario where a server holds a huge database that it wants to make accessible to a large group of clients. After an initial setup phase, clients should be able to read arbitrary locations in the database while maintaining privacy (the server does not learn which locations are being read) and anonymity (the server does not learn which client is performing each read). This should hold even if the server colludes with a subset of the clients. Moreover, the run-time of both the server and the client during each read operation should be low, ideally only poly-logarithmic in the size of the database and the number of clients. We call this notion Private Anonymous Data Access (PANDA). PANDA simultaneously combines aspects of Private Information Retrieval (PIR) and Oblivious RAM (ORAM). PIR has no initial setup, and allows anybody to privately and anonymously access a public database, but the server’s run-time is linear in the data size. On the other hand, ORAM achieves poly-logarithmic server run-time, but requires an initial setup after which only a single client with a secret key can access the database. The goal of PANDA is to get the best of both worlds: allow many clients to privately and anonymously access the database as in PIR, while having an efficient server as in ORAM.In this work, we construct bounded-collusion PANDA schemes, where the efficiency scales linearly with a bound on the number of corrupted clients that can collude with the server, but is otherwise poly-logarithmic in the data size and the total number of clients. Our solution relies on standard assumptions, namely the existence of fully homomorphic encryption, and combines techniques from both PIR and ORAM. We also extend PANDA to settings where clients can write to the database.

2019

CRYPTO

Trapdoor Hash Functions and Their Applications
📺
Abstract

We introduce a new primitive, called trapdoor hash functions (TDH), which are hash functions $$\mathsf {H}: \{0,1\}^n \rightarrow \{0,1\}^\lambda $$ with additional trapdoor function-like properties. Specifically, given an index $$i\in [n]$$, TDHs allow for sampling an encoding key $$\mathsf {ek}$$ (that hides i) along with a corresponding trapdoor. Furthermore, given $$\mathsf {H}(x)$$, a hint value $$\mathsf {E}(\mathsf {ek},x)$$, and the trapdoor corresponding to $$\mathsf {ek}$$, the $$i^{th}$$ bit of x can be efficiently recovered. In this setting, one of our main questions is: How small can the hint value $$\mathsf {E}(\mathsf {ek},x)$$ be? We obtain constructions where the hint is only one bit long based on DDH, QR, DCR, or LWE.This primitive opens a floodgate of applications for low-communication secure computation. We mainly focus on two-message protocols between a receiver and a sender, with private inputs x and y, resp., where the receiver should learn f(x, y). We wish to optimize the (download) rate of such protocols, namely the asymptotic ratio between the size of the output and the sender’s message. Using TDHs, we obtain:1.The first protocols for (two-message) rate-1 string OT based on DDH, QR, or LWE. This has several useful consequences, such as:(a)The first constructions of PIR with communication cost poly-logarithmic in the database size based on DDH or QR. These protocols are in fact rate-1 when considering block PIR.(b)The first constructions of a semi-compact homomorphic encryption scheme for branching programs, where the encrypted output grows only with the program length, based on DDH or QR.(c)The first constructions of lossy trapdoor functions with input to output ratio approaching 1 based on DDH, QR or LWE.(d)The first constant-rate LWE-based construction of a 2-message “statistically sender-private” OT protocol in the plain model.2.The first rate-1 protocols (under any assumption) for n parallel OTs and matrix-vector products from DDH, QR or LWE.
We further consider the setting where f evaluates a RAM program y with running time $$T\ll |x|$$ on x. We obtain the first protocols with communication sublinear in the size of x, namely $$T\cdot \sqrt{|x|}$$ or $$T\cdot \root 3 \of {|x|}$$, based on DDH or, resp., pairings (and correlated-input secure hash functions).

2019

CRYPTO

Universally Composable Secure Computation with Corrupted Tokens
📺
Abstract

We introduce the corrupted token model. This model generalizes the tamper-proof token model proposed by Katz (EUROCRYPT ’07) relaxing the trust assumption on the honest behavior of tokens. Our model is motivated by the real-world practice of outsourcing hardware production to possibly corrupted manufacturers. We capture the malicious behavior of token manufacturers by allowing the adversary to corrupt the tokens of honest players at the time of their creation.We show that under minimal complexity assumptions, i.e., the existence of one-way functions, it is possible to UC-securely realize (a variant of) the tamper-proof token functionality of Katz in the corrupted token model with n stateless tokens assuming that the adversary corrupts at most $$n-1$$ of them (for any $$n>0$$). We apply this result to existing multi-party protocols in Katz’s model to achieve UC-secure MPC in the corrupted token model assuming only the existence of one-way functions. Finally, we show how to obtain the above results using tokens of small size that take only short inputs. The technique in this result can also be used to improve the assumption of UC-secure hardware obfuscation recently proposed by Nayak et al. (NDSS ’17). While their construction requires the existence of collision-resistant hash functions, we can obtain the same result from only one-way functions. Moreover using our main result we can improve the trust assumption on the tokens as well.

2019

CRYPTO

Reusable Non-Interactive Secure Computation
📺
Abstract

We consider the problem of Non-Interactive Two-Party Secure Computation (NISC), where Rachel wishes to publish an encryption of her input x, in such a way that any other party, who holds an input y, can send her a single message which conveys to her the value f(x, y), and nothing more. We demand security against malicious parties. While such protocols are easy to construct using garbled circuits and general non-interactive zero-knowledge proofs, this approach inherently makes a non-black-box use of the underlying cryptographic primitives and is infeasible in practice.Ishai et al. (Eurocrypt 2011) showed how to construct NISC protocols that only use parallel calls to an ideal oblivious transfer (OT) oracle, and additionally make only a black-box use of any pseudorandom generator. Combined with the efficient 2-message OT protocol of Peikert et al. (Crypto 2008), this leads to a practical approach to NISC that has been implemented in subsequent works. However, a major limitation of all known OT-based NISC protocols is that they are subject to selective failure attacks that allows a malicious sender to entirely compromise the security of the protocol when the receiver’s first message is reused.Motivated by the failure of the OT-based approach, we consider the problem of basing reusable NISC on parallel invocations of a standard arithmetic generalization of OT known as oblivious linear-function evaluation (OLE). We obtain the following results:We construct an information-theoretically secure reusable NISC protocol for arithmetic branching programs and general zero-knowledge functionalities in the OLE-hybrid model. Our zero-knowledge protocol only makes an absolute constant number of OLE calls per gate in an arithmetic circuit whose satisfiability is being proved. We also get reusable NISC in the OLE-hybrid model for general Boolean circuits using any one-way function.We complement this by a negative result, showing that reusable NISC is impossible to achieve in the OT-hybrid model. This provides a formal justification for the need to replace OT by OLE.We build a universally composable 2-message reusable OLE protocol in the CRS model that can be based on the security of Paillier encryption and requires only a constant number of modular exponentiations. This provides the first arithmetic analogue of the 2-message OT protocols of Peikert et al. (Crypto 2008).By combining our NISC protocol in the OLE-hybrid model and the 2-message OLE protocol, we get protocols with new attractive asymptotic and concrete efficiency features. In particular, we get the first (designated-verifier) NIZK protocols for NP where following a statement-independent preprocessing, both proving and verifying are entirely “non-cryptographic” and involve only a constant computational overhead. Furthermore, we get the first statistical designated-verifier NIZK argument for NP under an assumption related to factoring.

2019

TCC

Lower and Upper Bounds on the Randomness Complexity of Private Computations of AND
Abstract

We consider multi-party information-theoretic private protocols, and specifically their randomness complexity. The randomness complexity of private protocols is of interest both because random bits are considered a scarce resource, and because of the relation between that complexity measure and other complexity measures of boolean functions such as the circuit size or the sensitivity of the function being computed [12, 17].More concretely, we consider the randomness complexity of the basic boolean function and, that serves as a building block in the design of many private protocols. We show that and cannot be privately computed using a single random bit, thus giving the first non-trivial lower bound on the 1-private randomness complexity of an explicit boolean function, $$f: \{0,1\}^n \rightarrow \{0,1\}$$. We further show that the function and, on any number of inputs n (one input bit per player), can be privately computed using 8 random bits (and 7 random bits in the special case of $$n=3$$ players), improving the upper bound of 73 random bits implicit in [17]. Together with our lower bound, we thus approach the exact determination of the randomness complexity of and. To the best of our knowledge, the exact randomness complexity of private computation is not known for any explicit function (except for xor, which is trivially 1-random, and for several degenerate functions).

2019

ASIACRYPT

UC-Secure Multiparty Computation from One-Way Functions Using Stateless Tokens
Abstract

We revisit the problem of universally composable (UC) secure multiparty computation in the stateless hardware token model.
We construct a three round multi-party computation protocol for general functions based on one-way functions where each party sends two tokens to every other party. Relaxing to the two-party case, we also construct a two round protocol based on one-way functions where each party sends a single token to the other party, and at the end of the protocol, both parties learn the output.One of the key components in the above constructions is a new two-round oblivious transfer protocol based on one-way functions using only one token, which can be reused an unbounded polynomial number of times.
All prior constructions required either stronger complexity assumptions, or larger number of rounds, or a larger number of tokens.

2018

CRYPTO

Adaptive Garbled RAM from Laconic Oblivious Transfer
Abstract

We give a construction of an adaptive garbled RAM scheme. In the adaptive setting, a client first garbles a “large” persistent database which is stored on a server. Next, the client can provide garbling of multiple adaptively and adversarially chosen RAM programs that execute and modify the stored database arbitrarily. The garbled database and the garbled program should reveal nothing more than the running time and the output of the computation. Furthermore, the sizes of the garbled database and the garbled program grow only linearly in the size of the database and the running time of the executed program respectively (up to poly logarithmic factors). The security of our construction is based on the assumption that laconic oblivious transfer (Cho et al., CRYPTO 2017) exists. Previously, such adaptive garbled RAM constructions were only known using indistinguishability obfuscation or in random oracle model. As an additional application, we note that this work yields the first constant round secure computation protocol for persistent RAM programs in the malicious setting from standard assumptions. Prior works did not support persistence in the malicious setting.

2018

CRYPTO

Continuously Non-Malleable Codes in the Split-State Model from Minimal Assumptions
📺
Abstract

At ICS 2010, Dziembowski, Pietrzak and Wichs introduced the notion of non-malleable codes, a weaker form of error-correcting codes guaranteeing that the decoding of a tampered codeword either corresponds to the original message or to an unrelated value. The last few years established non-malleable codes as one of the recently invented cryptographic primitives with the highest impact and potential, with very challenging open problems and applications.In this work, we focus on so-called continuously non-malleable codes in the split-state model, as proposed by Faust et al. (TCC 2014), where a codeword is made of two shares and an adaptive adversary makes a polynomial number of attempts in order to tamper the target codeword, where each attempt is allowed to modify the two shares independently (yet arbitrarily). Achieving continuous non-malleability in the split-state model has been so far very hard. Indeed, the only known constructions require strong setup assumptions (i.e., the existence of a common reference string) and strong complexity-theoretic assumptions (i.e., the existence of non-interactive zero-knowledge proofs and collision-resistant hash functions).As our main result, we construct a continuously non-malleable code in the split-state model without setup assumptions, requiring only one-to-one one-way functions (i.e., essentially optimal computational assumptions). Our result introduces several new ideas that make progress towards understanding continuous non-malleability, and shows interesting connections with protocol-design and proof-approach techniques used in other contexts (e.g., look-ahead simulation in zero-knowledge proofs, non-malleable commitments, and leakage resilience).

2018

PKC

On the Message Complexity of Secure Multiparty Computation
Abstract

We study the minimal number of point-to-point messages required for general secure multiparty computation (MPC) in the setting of computational security against semi-honest, static adversaries who may corrupt an arbitrary number of parties.We show that for functionalities that take inputs from n parties and deliver outputs to k parties, $$2n+k-3$$2n+k-3 messages are necessary and sufficient. The negative result holds even when given access to an arbitrary correlated randomness setup. The positive result can be based on any 2-round MPC protocol (which can in turn can be based on 2-message oblivious transfer), or on a one-way function given a correlated randomness setup.

2018

TCC

Round Optimal Black-Box “Commit-and-Prove”
Abstract

Motivated by theoretical and practical considerations, an important line of research is to design secure computation protocols that only make black-box use of cryptography. An important component in nearly all the black-box secure computation constructions is a black-box commit-and-prove protocol. A commit-and-prove protocol allows a prover to commit to a value and prove a statement about this value while guaranteeing that the committed value remains hidden. A black-box commit-and-prove protocol implements this functionality while only making black-box use of cryptography.In this paper, we build several tools that enable constructions of round-optimal, black-box commit and prove protocols. In particular, assuming injective one-way functions, we design the first round-optimal, black-box commit-and-prove arguments of knowledge satisfying strong privacy against malicious verifiers, namely:Zero-knowledge in four rounds and,Witness indistinguishability in three rounds.
Prior to our work, the best known black-box protocols achieving commit-and-prove required more rounds.We additionally ensure that our protocols can be used, if needed, in the delayed-input setting, where the statement to be proven is decided only towards the end of the interaction. We also observe simple applications of our protocols towards achieving black-box four-round constructions of extractable and equivocal commitments.We believe that our protocols will provide a useful tool enabling several new constructions and easy round-efficient conversions from non-black-box to black-box protocols in the future.

2018

TCC

Information-Theoretic Broadcast with Dishonest Majority for Long Messages
Abstract

Byzantine broadcast is a fundamental primitive for secure computation. In a setting with n parties in the presence of an adversary controlling at most t parties, while a lot of progress in optimizing communication complexity has been made for $$t < n/2$$t<n/2, little progress has been made for the general case $$t<n$$t<n, especially for information-theoretic security. In particular, all information-theoretic secure broadcast protocols for $$\ell $$ℓ-bit messages and $$t<n$$t<n and optimal round complexity $${\mathcal {O}}(n)$$O(n) have, so far, required a communication complexity of $${\mathcal {O}}(\ell n^2)$$O(ℓn2). A broadcast extension protocol allows a long message to be broadcast more efficiently using a small number of single-bit broadcasts. Through broadcast extension, so far, the best achievable round complexity for $$t<n$$t<n setting with the optimal communication complexity of $${\mathcal {O}}(\ell n)$$O(ℓn) is $${\mathcal {O}}(n^4)$$O(n4) rounds.In this work, we construct a new broadcast extension protocol for $$t<n$$t<n with information-theoretic security. Our protocol improves the round complexity to $${\mathcal {O}}(n^3)$$O(n3) while maintaining the optimal communication complexity for long messages. Our result shortens the gap between the information-theoretic setting and the computational setting, and between the optimal communication protocol and the optimal round protocol in the information-theoretic setting for $$t<n$$t<n.

2018

ASIACRYPT

Non-interactive Secure Computation from One-Way Functions
Abstract

The notion of non-interactive secure computation (NISC) first introduced in the work of Ishai et al. [EUROCRYPT 2011] studies the following problem: Suppose a receiver R wishes to publish an encryption of her secret input y so that any sender S with input x can then send a message m that reveals f(x, y) to R (for some function f). Here, m can be viewed as an encryption of f(x, y) that can be decrypted by R. NISC requires security against both malicious senders and receivers, and also requires the receiver’s message to be reusable across multiple computations (w.r.t. a fixed input of the receiver).All previous solutions to this problem necessarily rely upon OT (or specific number-theoretic assumptions) even in the common reference string model or the random oracle model or to achieve weaker notions of security such as super-polynomial-time simulation.In this work, we construct a NISC protocol based on the minimal assumption of one way functions, in the stateless hardware token model. Our construction achieves UC security and requires a single token sent by the receiver to the sender.

2013

EUROCRYPT

2011

ASIACRYPT

2000

EUROCRYPT

1992

CRYPTO

1992

CRYPTO

#### Program Committees

- Eurocrypt 2019
- Eurocrypt 2017
- PKC 2016
- Eurocrypt 2011
- TCC 2010
- Eurocrypt 2009
- PKC 2007
- PKC 2006
- Eurocrypt 2005
- TCC 2005
- Crypto 2004
- Crypto 2003
- Crypto 2002
- Crypto 1998

#### Coauthors

- William Aiello (1)
- Joël Alwen (1)
- Yair Amir (2)
- Prabhanjan Ananth (1)
- Saikrishna Badrinarayanan (3)
- Ohad Barta (1)
- Eli Ben-Sasson (1)
- Nir Bitansky (1)
- Dan Boneh (3)
- Xavier Boyen (1)
- Harry Buhrman (1)
- Paul Bunn (4)
- Ran Canetti (2)
- Alfonso Cevallos (1)
- Nishanth Chandran (6)
- Melissa Chase (2)
- Alessandro Chiesa (1)
- Chongwon Cho (3)
- Wutichai Chongchitmate (4)
- Arka Rai Choudhuri (2)
- Kai-Min Chung (1)
- Michele Ciampi (7)
- Giovanni Di Crescenzo (7)
- Ivan Damgård (1)
- Yevgeniy Dodis (2)
- Shlomi Dolev (1)
- Nico Döttling (1)
- Cynthia Dwork (1)
- Brett Hemenway Falk (1)
- Serge Fehr (3)
- Joan Feigenbaum (1)
- Matthias Fitzi (2)
- Matthew K. Franklin (1)
- Juan A. Garay (7)
- Sanjam Garg (8)
- Ran Gelles (2)
- Craig Gentry (1)
- Clint Givens (1)
- Shafi Goldwasser (1)
- S. Dov Gordon (1)
- Vipul Goyal (11)
- Jens Groth (4)
- Mohammad Hajiabadi (2)
- Shai Halevi (2)
- Mike Hamburg (1)
- Ariel Hamlin (1)
- Brett Hemenway (9)
- William E. Skeith III (4)
- Yuval Ishai (15)
- Zahra Jafargholi (1)
- Abhishek Jain (7)
- Ari Juels (1)
- Bhavana Kanukurthi (2)
- Jonathan Katz (6)
- Dakshita Khurana (2)
- Aggelos Kiayias (1)
- Joe Kilian (1)
- Daniel Kraschewski (1)
- Abishek Kumarasubramanian (2)
- Eyal Kushilevitz (10)
- Chen-Kuei Lee (1)
- Hanjun Li (1)
- Benoît Libert (1)
- Tianren Liu (1)
- Sachin Lodha (1)
- Steve Lu (6)
- Michael Luby (1)
- Giulio Malavolta (2)
- Tal Malkin (1)
- Ueli Maurer (2)
- Silvio Micali (1)
- Manika Mittal (1)
- Tal Moran (1)
- Ryan Moriarty (2)
- Tamer Mour (1)
- Steven Myers (1)
- Moni Naor (3)
- Jesper Buus Nielsen (1)
- Daniel Noble (1)
- Claudio Orlandi (1)
- Giorgos Panagiotakos (1)
- Omkant Pandey (2)
- Omer Paneth (1)
- Anat Paskin-Cherniavsky (1)
- Beni Paskin-Cherniavsky (1)
- Rafael Pass (1)
- Giuseppe Persiano (5)
- Antigoni Polychroniadou (1)
- Manoj Prabhakaran (2)
- Emmanuel Prouff (1)
- Yuval Rabani (1)
- Sivaramakrishnan Rajagopalan (1)
- Vanishree Rao (2)
- Mariana Raykova (1)
- Silas Richelson (4)
- Alon Rosen (2)
- Adi Rosén (3)
- Amit Sahai (11)
- Alfredo De Santis (1)
- Alessandra Scafuro (6)
- Christian Schaffner (1)
- Leonard J. Schulman (1)
- Hakan Seyalioglu (1)
- Hovav Shacham (1)
- Luisa Siniscalchi (4)
- Adam Smith (3)
- Yifan Song (1)
- Akshayaram Srinivasan (2)
- Adrian Thillard (1)
- Vinod Vaikuntanathan (1)
- Ramarathnam Venkatesan (3)
- Muthuramakrishnan Venkitasubramaniam (2)
- Daniele Venturi (1)
- Damien Vergnaud (2)
- Ivan Visconti (23)
- Akshay Wadia (3)
- Brent Waters (1)
- Mor Weiss (1)
- Daniel Wichs (3)
- David J. Wu (1)
- Jürg Wullschleger (1)
- Moti Yung (4)
- Hong-Sheng Zhou (1)
- Vassilis Zikas (4)