Estimating parallel runtimes for randomized algorithms in constraint solving

International audienceThis paper presents a detailed analysis of the scalability and par-allelization of Local Search algorithms for constraint-based and SAT (Boolean satisfiability) solvers. We propose a framework to estimate the parallel performance of a given algorithm by analyzing the runtime behavior of its sequential version. Indeed, by approximating the runtime distribution of the sequential process with statistical methods, the runtime behavior of the parallel process can be predicted by a model based on order statistics. We apply this approach to study the parallel performance of a Constraint-Based Local Search solver (Adaptive Search), two SAT Local Search solvers (namely Sparrow and CCASAT), and a propagation-based constraint solver (Gecode, with a random labeling heuristic). We compare the performance predicted by our model to actual parallel implementations of those methods using up to 384 processes. We show that the model is accurate and predicts performance close to the empirical data. Moreover, as we study different types of problems, we observe that the experimented solvers exhibit different behaviors and that their runtime distributions can be approximated by two types of distributions: exponential (shifted and non-shifted) and lognormal. Our results show that the proposed framework estimates the runtime of the parallel algorithm with an average discrepancy of 21% w.r.t. the empirical data across all the experiments with the maximum allowed number of processors for each technique

Quantum Proofs

Quantum information and computation provide a fascinating twist on the notion of proofs in computational complexity theory. For instance, one may consider a quantum computational analogue of the complexity class \class{NP}, known as QMA, in which a quantum state plays the role of a proof (also called a certificate or witness), and is checked by a polynomial-time quantum computation. For some problems, the fact that a quantum proof state could be a superposition over exponentially many classical states appears to offer computational advantages over classical proof strings. In the interactive proof system setting, one may consider a verifier and one or more provers that exchange and process quantum information rather than classical information during an interaction for a given input string, giving rise to quantum complexity classes such as QIP, QSZK, and QMIP* that represent natural quantum analogues of IP, SZK, and MIP. While quantum interactive proof systems inherit some properties from their classical counterparts, they also possess distinct and uniquely quantum features that lead to an interesting landscape of complexity classes based on variants of this model. In this survey we provide an overview of many of the known results concerning quantum proofs, computational models based on this concept, and properties of the complexity classes they define. In particular, we discuss non-interactive proofs and the complexity class QMA, single-prover quantum interactive proof systems and the complexity class QIP, statistical zero-knowledge quantum interactive proof systems and the complexity class \class{QSZK}, and multiprover interactive proof systems and the complexity classes QMIP, QMIP*, and MIP*.Comment: Survey published by NOW publisher

A survey of algorithmic methods in IC reverse engineering

The discipline of reverse engineering integrated circuits (ICs) is as old as the technology itself. It grew out of the need to analyze competitor’s products and detect possible IP infringements. In recent years, the growing hardware Trojan threat motivated a fresh research interest in the topic. The process of IC reverse engineering comprises two steps: netlist extraction and specification discovery. While the process of netlist extraction is rather well understood and established techniques exist throughout the industry, specification discovery still presents researchers with a plurality of open questions. It therefore remains of particular interest to the scientific community. In this paper, we present a survey of the state of the art in IC reverse engineering while focusing on the specification discovery phase. Furthermore, we list noteworthy existing works on methods and algorithms in the area and discuss open challenges as well as unanswered questions. Therefore, we observe that the state of research on algorithmic methods for specification discovery suffers from the lack of a uniform evaluation approach. We point out the urgent need to develop common research infrastructure, benchmarks, and evaluation metrics

On the Generation of Cyber Threat Intelligence: Malware and Network Traffic Analyses

In recent years, malware authors drastically changed their course on the subject of threat design and implementation. Malware authors, namely, hackers or cyber-terrorists perpetrate new forms of cyber-crimes involving more innovative hacking techniques. Being motivated by financial or political reasons, attackers target computer systems ranging from personal computers to organizations’ networks to collect and steal sensitive data as well as blackmail, scam people, or scupper IT infrastructures. Accordingly, IT security experts face new challenges, as they need to counter cyber-threats proactively. The challenge takes a continuous allure of a fight, where cyber-criminals are obsessed by the idea of outsmarting security defenses. As such, security experts have to elaborate an effective strategy to counter cyber-criminals. The generation of cyber-threat intelligence is of a paramount importance as stated in the following quote: “the field is owned by who owns the intelligence”. In this thesis, we address the problem of generating timely and relevant cyber-threat intelligence for the purpose of detection, prevention and mitigation of cyber-attacks. To do so, we initiate a research effort, which falls into: First, we analyze prominent cyber-crime toolkits to grasp the inner-secrets and workings of advanced threats. We dissect prominent malware like Zeus and Mariposa botnets to uncover their underlying techniques used to build a networked army of infected machines. Second, we investigate cyber-crime infrastructures, where we elaborate on the generation of a cyber-threat intelligence for situational awareness. We adapt a graph-theoretic approach to study infrastructures used by malware to perpetrate malicious activities. We build a scoring mechanism based on a page ranking algorithm to measure the badness of infrastructures’ elements, i.e., domains, IPs, domain owners, etc. In addition, we use the min-hashing technique to evaluate the level of sharing among cyber-threat infrastructures during a period of one year. Third, we use machine learning techniques to fingerprint malicious IP traffic. By fingerprinting, we mean detecting malicious network flows and their attribution to malware families. This research effort relies on a ground truth collected from the dynamic analysis of malware samples. Finally, we investigate the generation of cyber-threat intelligence from passive DNS streams. To this end, we design and implement a system that generates anomalies from passive DNS traffic. Due to the tremendous nature of DNS data, we build a system on top of a cluster computing framework, namely, Apache Spark [70]. The integrated analytic system has the ability to detect anomalies observed in DNS records, which are potentially generated by widespread cyber-threats

Computer Aided Verification

This open access two-volume set LNCS 13371 and 13372 constitutes the refereed proceedings of the 34rd International Conference on Computer Aided Verification, CAV 2022, which was held in Haifa, Israel, in August 2022. The 40 full papers presented together with 9 tool papers and 2 case studies were carefully reviewed and selected from 209 submissions. The papers were organized in the following topical sections: Part I: Invited papers; formal methods for probabilistic programs; formal methods for neural networks; software Verification and model checking; hyperproperties and security; formal methods for hardware, cyber-physical, and hybrid systems. Part II: Probabilistic techniques; automata and logic; deductive verification and decision procedures; machine learning; synthesis and concurrency. This is an open access book

Satellite Networks: Architectures, Applications, and Technologies

Since global satellite networks are moving to the forefront in enhancing the national and global information infrastructures due to communication satellites' unique networking characteristics, a workshop was organized to assess the progress made to date and chart the future. This workshop provided the forum to assess the current state-of-the-art, identify key issues, and highlight the emerging trends in the next-generation architectures, data protocol development, communication interoperability, and applications. Presentations on overview, state-of-the-art in research, development, deployment and applications and future trends on satellite networks are assembled

SAVCBS 2004 Specification and Verification of Component-Based Systems: Workshop Proceedings

This is the proceedings of the 2004 SAVCBS workshop. The workshop is concerned with how formal (i.e., mathematical) techniques can be or should be used to establish a suitable foundation for the specification and verification of component-based systems. Component-based systems are a growing concern for the software engineering community. Specification and reasoning techniques are urgently needed to permit composition of systems from components. Component-based specification and verification is also vital for scaling advanced verification techniques such as extended static analysis and model checking to the size of real systems. The workshop considers formalization of both functional and non-functional behavior, such as performance or reliability