*12:17* [Pub][ePrint]
A Hybrid Approach for Proving Noninterference of Java Programs, by Ralf Kuesters and Tomasz Truderung and Bernhard Beckert and Daniel Bruns and Michael Kirsten and Martin Mohr
Several tools and approaches for proving noninterference properties for Java and other languages exist. Some of them have a high degree of automation or are even fully automatic, but overapproximate the actual information flow, and hence, may produce false positives. Other tools, such as those based on theorem proving, are precise, but may need interaction, and hence, analysis is time-consuming.In this paper, we propose a \\emph{hybrid approach} that aims at obtaining the best of both approaches: We want to use fully automatic analysis as much as possible and only at places in a program where, due to overapproximation, the automatic approaches fail, we resort to more precise, but interactive analysis, where the latter involves the verification only of specific functional properties in certain parts of the program, rather than checking more intricate noninterference properties for the whole program.

To illustrate the hybrid approach, in a case study we use this approach---along with the fully automatic tool Joana for checking noninterference properties for Java programs and the theorem prover KeY for the verification of Java programs--- as well as the CVJ framework proposed by K{\\\"u}sters, Truderung, and Graf to establish cryptographic privacy properties for a non-trivial Java program, namely an e-voting system. The CVJ framework allows one to establish cryptographic indistinguishability properties for Java programs by checking (standard) noninterference properties for such programs.

*12:17* [Pub][ePrint]
On Concurrently Secure Computation in the Multiple Ideal Query Model, by Vipul Goyal and Abhishek Jain
The multiple ideal query (MIQ) model was introduced by Goyal, Jain and Ostrovsky [Crypto\'10] as a relaxed notion of security which allows one to construct concurrently secure protocols in the plain model. The main question relevant to the MIQ model is how many queries must we allow to the ideal world adversary? The importance of the above question stems from the fact that if the answer is positive, then it would enable meaningful security guarantees in many application scenarios, as well as, lead to resolution of long standing open questions such as fully concurrent password based key exchange in the plain model.In this work, we continue the study of the MIQ model and prove severe lower bounds on the number of ideal queries per session. Following are our main results:

1) There exists a two-party functionality that cannot be securely realized in the MIQ model with only a constant number of ideal queries per session.

2) There exists a two-party functionality that cannot be securely realized in the MIQ model by any constant round protocol, with any polynomial number of ideal queries per session.

Both of these results are unconditional and even rule out protocols proven secure using a non-black-box simulator. We in fact prove a more general theorem which allows for trade-off between round complexity and the number of ideal queries per session. We obtain our negative results in the following two steps:

1) We first prove our results with respect to black-box simulation, i.e., we only rule out simulators that make black-box use of the adversary.

2) Next, we give a technique to compile our negative results w.r.t. black-box simulation into full impossibility results (ruling out non-black-box simulation as well) in the MIQ model. Interestingly, our compiler uses ideas from the work on obfuscation using tamper-proof hardware, even though our setting does not involve any hardware tokens.

*12:17* [Pub][ePrint]
Message-Locked Encryption for Lock-Dependent Messages, by MartÃn Abadi and Dan Boneh and Ilya Mironov and Ananth Raghunathan and Gil Segev
Motivated by the problem of avoiding duplication in storage systems, Bellare, Keelveedhi, and Ristenpart have recently put forward the notion of Message-Locked Encryption (MLE) schemes which subsumes convergent encryption and its variants. Such schemes do not rely on permanent secret keys, but rather encrypt messages using keys derived from the messages themselves.We strengthen the notions of security proposed by Bellare et al. by considering plaintext distributions that may depend on the public parameters of the schemes. We refer to such inputs as lock-dependent messages. We construct two schemes that satisfy our new notions of security for message-locked encryption with lock-dependent messages.

Our main construction deviates from the approach of Bellare et al. by avoiding the use of ciphertext components derived deterministically from the messages. We design a fully randomized scheme that supports an equality-testing algorithm defined on the ciphertexts.

Our second construction has a deterministic ciphertext component that enables more efficient equality testing. Security for lock-dependent messages still holds under computational assumptions on the message distributions produced by the attacker.

In both of our schemes the overhead in the length of the ciphertext is only additive and independent of the message length.

*12:17* [Pub][ePrint]
Enhancing Trust in Reconfigurable Based Hardware Systems with Tags and Monitors, by Devu Manikantan Shila and Vivek Venugopalan and Cameron D Patterson
Extensive use of third party IP cores (e.g., HDL, netlist) and open source tools in the FPGA application design and development process in conjunction with the inadequate bitstream protection measures have raised crucial security concerns in the past for reconfigurable hardware systems. Designing high fidelity and secure methodologies for FPGAs are still infancy and in particular, there are almost no concrete methods/techniques that can ensure trust in FPGA applications not entirely designed and/or developed in a trusted environment. This work strongly suggests the need for an anomaly detection capability within the FPGAs that can continuously monitor the behavior of the underlying FPGA IP cores and the communication activities of IP cores with other IP cores or peripherals for any abnormalities. To capture this need, we propose a technique called FIDelity Enhancing Security (FIDES) methodology for FPGAs that uses a combination of access control policies and behavior learning techniques for anomaly detection. FIDES essentially comprises of two components: (i) {\\em Trusted Wrappers}, a layer of monitors with sensing capabilities distributed across the FPGA fabric; these wrappers embed the output of each IP core $i$ with a tag $\\tau_i$ according to the pre-defined security policy $\\Pi$ and also verifies the embeddings of each input to the IP core to detect any violation of policies. The use of tagging and tracking enables us to capture the generalized interactions of each IP core with its environment (e.g., other IP cores, memory, OS or I/O ports). {\\em Trusted Wrappers} also monitors the statistical properties exhibited by each IP core functions on execution such as power consumption, number of clock cycles and timing variations to detect any anomalous operations; (ii) a {\\em Trusted Anchor} that monitors the communication between the IP cores and the peripherals with regard to the centralized security policies $\\Psi$ and the statistical properties produced by the peripherals. We target FIDES architecture on a Xilinx Zynq 7020 device for a red-black system comprising of sensitive and non-sensitive IP cores. Our FIDES implementation leads to only 1-2\\% overhead in terms of the logic resources per wrapper but 4-5X increase in latency (worst case scenario), measured in terms of clock cycles, as compared to the baseline implementation.

*21:17* [Pub][ePrint]
A Note on the Unsoundness of vnTinyRAM\'s SNARK, by Bryan Parno
Gennaro, Gentry, Parno, and Raykova (GGPR) introduced Quadratic Arithmetic Programs (QAPs) as a way of representing arithmetic circuits in a form amendable to highly efficient cryptographic protocols (EUROCRYPT 2013), particularly for verifiable computation and succinct non-interactive arguments. Subsequently, Parno, Gentry, Howell, and Raykova introduced an improved cryptographic protocol (and implementation), which they dubbed Pinocchio (IEEE S&P 2013).Ben-Sasson et al. then introduced a lightly modified version of the Pinocchio protocol and implemented it as part of their libsnark distribution. Later work by the same authors employed this protocol, as did a few works by others. Many of these works cite the version of the paper which was published at USENIX Security. However, the protocol does not appear in that peer-reviewed paper; instead, it appears only in a technical report, where it is justified via a lemma that lacks a proof. Unfortunately, the lemma is incorrect, and the modified protocol is unsound. With probability one, an adversary can submit false statements and proofs that the verifier will accept. We demonstrate this theoretically, as well as with concrete examples in which the protocol\'s implementation in libsnark accepts invalid statements.

Fixing this problem requires different performance tradeoffs, indicating that the performance results reported by papers building on this protocol (USENIX Security 2013, CRYPTO 2014, NDSS 2014, EUROCRYPT 2015, IEEE S&P 2014, IEEE S&P 2015) are, to a greater or lesser extent, inaccurate.

*15:17* [Pub][ePrint]
Cryptanalysis of Round-Reduced LED, by Ivica Nikoli\\\'c and Lei Wang and Shuang Wu
In this paper we present known-plaintext single-key and chosen-key attacks on round-reduced LED-64 and LED-128.We show that with an application of the recently proposed slidex attacks,

one immediately improves the complexity of the previous single-key 4-step attack on LED-128. Further, we explore the possibility of

multicollisions and show single-key attacks on 6 steps of LED-128. A generalization of our multicollision attack

leads to the statement that no 6-round cipher with two subkeys that alternate, or 2-round cipher with

linearly dependent subkeys, is secure in the single-key model. Next, we exploit the possibility of finding pairs of inputs that follow

a certain differential rather than a differential characteristic, and obtain chosen-key differential distinguishers

for 5-step LED-64, as well as 8-step and 9-step LED-128. We provide examples of inputs that follow the 8-step differential,

i.e. we are able to practically confirm our results on 2/3 of the steps of LED-128. We introduce a new type of

chosen-key differential distinguisher, called random-difference distinguisher, and

successfully penetrate 10 of the total 12 steps of LED-128. We show that this type of attack is generic

in the chosen-key model, and can be applied to any 10-round cipher with two alternating subkeys.

*15:17* [Pub][ePrint]
Fast and Tradeoff-Resilient Memory-Hard Functions for Cryptocurrencies and Password Hashing, by Alex Biryukov and Daniel Dinu and Dmitry Khovratovich
Memory-hard functions are becoming an important tool in the design of password hashing schemes, cryptocurrencies, and more generic proof-of-work primitives that are x86-oriented and can not be computed on dedicated hardware more efficiently. We develop a simple and cryptographically secure approach to the design of such functions and show how to exploit the architecture of modern CPUs and memory chips to make faster and more secure schemes compared to existing alternatives such as scrypt. We also propose cryptographic criteria for the components, that prevent cost reductions using time-memory tradeoffs and side-channel leaks. The concrete proof-of-work instantiation, which we call Argon2, can fill GBytes of RAM within a second, is resilient to various tradeoffs, and is suitable for a wide range of applications, which aim to bind a computation to a certain architecture.

Concerning potential DoS attacks, our scheme is lightweight enough to offset the bottleneck from the CPU to the memory bus thus leaving sufficient computing power for other tasks. We also propose parameters for which our scheme is botnet resistant. As an application, we suggest a cryptocurrency design with fast and memory-hard proof-of-work, which allows memoryless verification.

*15:17* [Pub][ePrint]
Conversions among Several Classes of Predicate Encryption and Their Applications, by Shota Yamada and Nuttapong Attrapadung and Goichiro Hanaoka
Predicate encryption is an advanced form of public-key encryption that yield high flexibility in terms of access control. In the literature, many predicate encryption schemes have been proposed such as fuzzy-IBE, KP-ABE, CP-ABE, (doubly) spatial encryption (DSE), and ABE for arithmetic span programs. In this paper, we study relations among them and show that some of them are in fact equivalent by giving conversions among them. More specifically, our main contributions are as follows: - We show that monotonic, small universe KP-ABE (CP-ABE) with bounds on the size of attribute sets and span programs (or linear secret sharing matrix) can be converted into DSE. Furthermore, we show that DSE implies non-monotonic CP-ABE (and KP-ABE) with the same bounds on parameters. This implies that monotonic/non-monotonic KP/CP-ABE (with the bounds) and DSE are all equivalent in the sense that one implies another.

- We also show that if we start from KP-ABE without bounds on the size of span programs (but bounds on the size of attribute sets), we can obtain ABE for arithmetic span programs. The other direction is also shown: ABE for arithmetic span programs can be converted into KP-ABE.These results imply, somewhat surprisingly, KP-ABE without bounds on span program sizes is in fact equivalent to ABE for arithmetic span programs, which was thought to be more expressive or at least incomparable.

By applying these conversions to existing schemes, we obtain many non-trivial consequences. We obtain the first non-monotonic, large universe CP-ABE (that supports span programs) with constant-size ciphertexts, the first ABE for arithmetic span programs with adaptive security, the first ciphertext-policy version of ABE for arithmetic span programs, the first KP-ABE with constant-size private keys, and even more.

We also obtain the first attribute-based signature scheme that supports non-monotone span programs and achieves constant-size signatures via our technique.