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Retargetable Analysis of Machine Code
Křoustek, Jakub ; Janoušek, Jan (oponent) ; Návrat,, Pavol (oponent) ; Kolář, Dušan (vedoucí práce)
Program analysis is a computer-science methodology whose task is to analyse the behavior of a given program. The methods of program analysis can also be used in other methodologies such as reverse engineering, re-engineering, code migration, etc. In this thesis, we focus on program analysis of a machine-code and we address the limitations of a nowadays approaches by proposing novel methods of a fast and accurate retargetable analysis (i.e. they are designed to be independent of a particular target platform). We focus on two types of analysis - dynamic analysis (i.e. run-time analysis) and static analysis (i.e. analysing application without its execution). The contribution of this thesis within the dynamic analysis lays in the extension and enhancement of existing methods and their implementation as a retargetable debugger and two types of a retargetable translated simulator. Within the static analysis, we present a concept and implementation of a retargetable decompiler that performs a program transformation from a machine code into a human-readable form of representation. All of these tools are based on several novel methods defined by the author. According to our experimental results and users feed-back, all of the proposed tools are at least fully competitive to existing solutions, while outperforming these solutions in several ways.
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Harnessing Forest Automata for Verification of Heap Manipulating Programs
Šimáček, Jiří ; Abdulla, Parosh (oponent) ; Křetínský, Mojmír (oponent) ; Vojnar, Tomáš (vedoucí práce)
This work addresses verification of infinite-state systems, more specifically, verification of programs manipulating complex dynamic linked data structures. Many different approaches emerged to date, but none of them provides a~sufficiently robust solution which would succeed in all possible scenarios appearing in practice. Therefore, in this work, we propose a new approach which aims at improving the current state of the art in several dimensions. Our approach is based on using tree automata, but it is also partially inspired by some ideas taken from the methods based on separation logic. Apart from that, we also present multiple advancements within the implementation of various tree automata operations, crucial for our verification method to succeed in practice. Namely, we provide an optimised algorithm for computing simulations over labelled transition systems which then translates into more efficient computation of simulations over tree automata. We also give a new algorithm for checking inclusion over tree automata, and we provide experimental evaluation demonstrating
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Acceleration of Object Detection Using Classifiers
Juránek, Roman ; Kälviäinen, Heikki (oponent) ; Sojka, Eduard (oponent) ; Zemčík, Pavel (vedoucí práce)
Detection of objects in computer vision is a complex task. One of most popular and well explored approaches is the use of statistical classifiers and scanning windows. In this approach, classifiers learned by AdaBoost algorithm (or some modification) are often used as they achieve low error rates, high detection rates and they are suitable for detection in real-time applications. Object detection run-time which uses such classifiers can be implemented by various methods and properties of underlying architecture can be used for speed-up of the detection. For the purpose of acceleration, graphics hardware, multi-core architectures, SIMD or other means can be used. The detection is often implemented on programmable hardware. The contribution of this thesis is to introduce an optimization technique which enhances object detection performance with respect to an user defined cost function. The optimization balances computations of previously learned classifiers between two or more run-time implementations in order to minimize the cost function. The optimization method is verified on a basic example -- division of a classifier to a pre-processing unit implemented in FPGA, and a post-processing unit in standard PC.
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Network-wide Security Analysis
de Silva, Hidda Marakkala Gayan Ruchika ; Šafařík,, Jiří (oponent) ; Šlapal, Josef (oponent) ; Švéda, Miroslav (vedoucí práce)
The objective of the research is to model and analyze the effects of dynamic routing protocols. The thesis addresses the analysis of service reachability, configurations, routing and security filters on dynamic networks in the event of device or link failures. The research contains two main sections, namely, modeling and analysis. First section consists of modeling of network topology, protocol behaviors, device configurations and filters. In the modeling, graph algorithms, routing redistribution theory, relational algebra and temporal logics were used. For the analysis of reachability, a modified topology table was introduced. This is a unique centralized table for a given network and invariant for network states. For the analysis of configurations, a constraint-based analysis was developed by using XSD Prolog. Routing and redistribution were analyzed by using routing information bases and for analyzing the filtering rules, a SAT-based decision procedure was incorporated. A part of the analysis was integrated to a simulation tool at OMNeT++ environment. There are several innovations introduced in this thesis. Filtering network graph, modified topology table, general state to reduce the state space, modeling devices as filtering nodes and constraint-based analysis are the key innovations. Abstract network graph, forwarding device model and redistribution with routing information are extensions of the existing research. Finally, it can be concluded that this thesis discusses novel approaches, modeling methods and analysis techniques in the area of dynamic networks. Integration of these methods into a simulation tool will be a very demanding product for the network designers and the administrators.
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Analysis and Testing of Concurrent Programs
Letko, Zdeněk ; Lourenco, Joao (oponent) ; Sekanina, Lukáš (oponent) ; Vojnar, Tomáš (vedoucí práce)
The thesis starts by providing a taxonomy of concurrency-related errors and an overview of their dynamic detection. Then, concurrency coverage metrics which measure how well the synchronisation and concurrency-related behaviour of tested programs has been examined are proposed together with a~methodology for deriving such metrics. The proposed metrics are especially suitable for saturation-based and search-based testing. Next, a novel coverage-based noise injection techniques that maximise the number of interleavings witnessed during testing are proposed. A comparison of various existing noise injection heuristics and the newly proposed heuristics on a set of benchmarks is provided, showing that the proposed techniques win over the existing ones in some cases. Finally, a novel use of stochastic optimisation algorithms in the area of concurrency testing is proposed in the form of their application for finding suitable combinations of values of the many parameters of tests and the noise injection techniques. The approach has been implemented in a prototype way and tested on a set of benchmark programs, showing its potential to significantly improve the testing process.
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Acceleration Methods for Evolutionary Design of Digital Circuits
Vašíček, Zdeněk ; Miller, Julian (oponent) ; Zelinka,, Ivan (oponent) ; Sekanina, Lukáš (vedoucí práce)
Although many examples showing the merits of evolutionary design over conventional design techniques utilized in the field of digital circuits design have been published, the evolutionary approaches are usually hardly applicable in practice due to the various so-called scalability problems. The scalability problem represents a general problem that refers to a situation in which the evolutionary algorithm is able to provide a solution to a small problem instances only. For example, the scalability of evaluation of a candidate digital circuit represents a serious issue because the time needed to evaluate a candidate solution grows exponentially with the increasing number of primary inputs. In this thesis, the scalability problem of evaluation of a candidate digital circuit is addressed. Three different approaches to overcoming this problem are proposed. Our goal is to demonstrate that the evolutionary design approach can produce interesting and human competitive solutions when the problem of scalability is reduced and thus a sufficient number of generations can be utilized. In order to increase the performance of the evolutionary design of image filters, a domain specific FPGA-based accelerator has been designed. The evolutionary design of image filters is a kind of regression problem which requires to evaluate a large number of training vectors as well as generations in order to find a satisfactory solution. By means of the proposed FPGA accelerator, very efficient nonlinear image filters have been discovered. One of the discovered implementations of an impulse noise filter consisting of four evolutionary designed filters is protected by the Czech utility model. A different approach has been introduced in the area of logic synthesis. A method combining formal verification techniques with evolutionary design that allows a significant acceleration of the fitness evaluation procedure was proposed. The proposed system can produce complex and simultaneously innovative designs, overcoming thus the major bottleneck of the evolutionary synthesis at gate level. The proposed method has been evaluated using a set of benchmark circuits and compared with conventional academia as well as commercial synthesis tools. In comparison with the conventional synthesis tools, the average improvement in terms of the number of gates provided by our system is approximately 25%. Finally, the problem of the multiple constant multiplier design, which belongs to the class of problems where a candidate solution can be perfectly evaluated in a short time, has been investigated. We have demonstrated that there exists a class of circuits that can be evaluated efficiently if a domain knowledge is utilized (in this case the linearity of components).
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Evolutionary Approach to Synthesis and Optimization of Ordinary and Polymorphic Circuits
Gajda, Zbyšek ; Schmidt, Jan (oponent) ; Zelinka,, Ivan (oponent) ; Sekanina, Lukáš (vedoucí práce)
This thesis deals with the evolutionary design and optimization of ordinary and polymorphic circuits. New extensions of Cartesian Genetic Programming (CGP) that allow reducing of the computational time and obtaining more compact circuits are proposed and evaluated. Second part of the thesis is focused on new methods for synthesis of polymorphic circuits. Proposed methods, based on polymorphic binary decision diagrams and polymorphic multiplexing, extend the ordinary circuit representations with the aim of including polymorphic gates. In order to reduce the number of gates in circuits synthesized using proposed methods, an evolutionary optimization based on CGP is implemented and evaluated. The implementations of polymorphic circuits optimized by CGP represent the best known solutions if the number of gates is considered as the target criterion.
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Simulace a protiřetězce pro efektivní práci s konečnými automaty
Holík, Lukáš ; Černá, Ivana (oponent) ; Jančar, Petr (oponent) ; Vojnar, Tomáš (vedoucí práce)
This thesis is focused on techniques for finite automata and their use in practice, with the main emphasis on nondeterministic tree automata. This concerns namely techniques for size reduction and language inclusion testing, which are two problems that are crucial for many applications of tree automata. For size reduction of tree automata, we adapt the simulation quotient technique that is well established for finite word automata. We give efficient algorithms for computing tree automata simulations and we also introduce a new type of relation that arises from a combination of tree automata downward and upward simulation and that is very well suited for quotienting. The combination principle is relevant also for word automata. We then generalise the so called antichain universality and language inclusion checking technique developed originally for finite word automata for tree automata. Subsequently, we improve the antichain technique for both word and tree automata by combining it with the simulation-based inclusion checking techniques, significantly improving efficiency of the antichain method. We then show how the developed reduction and inclusion checking methods improve the method of abstract regular tree model checking, the method that was the original motivation for starting the work on tree automata. Both the reduction and the language inclusion methods are based on relatively simple and general principles that can be further extended for other types of automata and related formalisms. An example is our adaptation of the reduction methods for alternating Büchi automata, which results in an efficient alternating automata size reduction technique.
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On-line Data Analysis Based on Visual Codebooks
Beran, Vítězslav ; Honec, Jozef (oponent) ; Sojka, Eduard (oponent) ; Zemčík, Pavel (vedoucí práce)
This work introduces the new adaptable method for on-line video searching in real-time based on visual codebook. The new method addresses the high computational efficiency and retrieval performance when used on on-line data. The method originates in procedures utilized by static visual codebook techniques. These standard procedures are modified to be able to adapt to changing data. The procedures, that improve the new method adaptability, are dynamic inverse document frequency, adaptable visual codebook and flowing inverted index. The developed adaptable method was evaluated and the presented results show how the adaptable method outperforms the static approaches when evaluating on the video searching tasks. The new adaptable method is based on introduced flowing window concept that defines the ways of selection of data, both for system adaptation and for processing. Together with the concept, the mathematical background is defined to find the best configuration when applying the concept to some new method. The practical application of the adaptable method is particularly in the video processing systems where significant changes of the data domain, unknown in advance, is expected. The method is applicable in embedded systems monitoring and analyzing the broadcasted TV on-line signals in real-time.
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Physically-based Modeling and Simulation
Dvořák, Radim ; Racek, Stanislav (oponent) ; Šujanský,, Milan (oponent) ; Zbořil, František (vedoucí práce)
The thesis deals with the modeling of air pollution transportation and dispersion processes in the atmosphere, more precisely with the numerical approaches to solve such models. The modeling of air pollution has a great importance for prediction of the contaminations and it helps with understanding of the process and with elimination of its consequences. The models which are described by partial differential equations, namely advection-diffusion equations, and thus they can be solved by numerous analytical/numerical methods are in the scope of the thesis. In particular, well known method of lines (MoL) and several models based on it together with the possibility to accelerate the computation are studied in the first half of the work. It is shown that MoL approach is still suitable for many concrete models and it has a great potential for parallelization on graphics cards. Quite young ELLAM method and its application to solved atmospheric advection-diffusion equations is the second objective. A concrete form of ELLAM method and its proposed adaptation approaches are evaluated and it is shown that it overcomes the current state of the art methods in many cases.
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