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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
171

Modeling the performance impact of hot code misprediction in Cross-ISA virtual machines = Modelagem do impacto de erros de predição de código quente no desempenho de máquinas virtuais / Modelagem do impacto de erros de predição de código quente no desempenho de máquinas virtuais

Lucas, Divino César Soares, 1985- 04 September 2013 (has links)
Orientadores: Guido Costa Souza de Araújo, Edson Borin / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Computação / Made available in DSpace on 2018-08-23T12:28:12Z (GMT). No. of bitstreams: 1 Lucas_DivinoCesarSoares_M.pdf: 1053361 bytes, checksum: e29ab79838532619ba298ddde8ba0f39 (MD5) Previous issue date: 2013 / Resumo: Máquinas virtuais (MVs) são sistemas que se propõem a eliminar a incompatibilidade entre duas, em geral diferentes, interfaces e dessa forma habilitar a comunicação entre diferentes sistemas. Nesse sentido, atuando como mediadores, uma MV está em um ponto que a permite fomentar o desenvolvimento de soluções inovadoras para vários problemas. Tais sistemas geralmente utilizam técnicas de emulação, por exemplo, interpretação ou tradução dinâmica de binários, para executar o código da aplicação cliente. Para determinar qual técnica de emulação é a ideal para um trecho de código geralmente é necessário que a MV empregue algum tipo de predição para determinar se o benefício de compilar o código supera os custos. Este problema, na maioria dos casos, resume-se a predizer se o dado trecho de código será frequentemente executado ou não, problema conhecido pelo nome de Predição de Código Quente. Em geral, se o preditor sinalizar um trecho de código como quente, a MV imediatamente toma a decisão de compilá-lo. Contudo, um problema surge nesta estratégia, à resposta do preditor é apenas a decisão de uma heurística e é, portanto, suscetível a erros. Quando o preditor sinaliza como quente um trecho de código que não será frequentemente executado, ou seja, um código que de fato é "frio", ele está fazendo uma predição errônea de código quente. Quando uma predição incorreta é feita, ocorre que a técnica de emulação que a MV utilizará para emular o trecho de código não compensará o seu custo e, portanto a MV gastará mais tempo executando o seu próprio código do que o código da aplicação cliente. Neste trabalho, foi avaliado o impacto de predições incorretas de código quente no desempenho de MVs emulando vários tipos de aplicações. Na análise realizada foi avaliado o preditor de código quente baseado em limiar, uma técnica frequentemente utilizada para identificar regiões de código que serão frequentemente executadas. Para fazer esta análise foi criado um modelo matemático para simular o comportamento de tal preditor e a partir deste modelo uma série de resultados puderam ser explorados. Inicialmente é mostrado que este preditor frequentemente erra a predição e, como conseqüência, o tempo gasto fazendo compilações torna-se o maior componente do tempo de execução da MV. Também é mostrado como diferentes limiares de predição afetam o número de predições incorretas e qual o impacto disto no desempenho da MV. Também são apresentados resultados indicando qual o impacto do custo de compilação, tradução e velocidade do código traduzido no desempenho da MV. Por fim é mostrado que utilizando apenas o conjunto de aplicações do SPEC CPU 2006 para avaliar o desempenho de MVs que utilizam o preditor de código quente baseado em limiar pode levar a resultados imprecisos / Abstract: Virtual machines are systems that aim to eliminate the compatibility gap between two, possible distinct, interfaces, thus enabling them to communicate. This way, acting like a mediator, the VM lies at an important position that enables it to foster innovative solutions for many problems. Such systems usually rely on emulation techniques, such as interpretation and dynamic binary translation, to execute guest application code. In order to select the best emulation technique for each code segment, the VM typically needs to predict whether the cost of compiling the code overcome its future execution time. This problem, in the common case, reduce to predicting if the given code region will be frequently executed or not, a problem called Hot Code Prediction. Generally, if the predictor flags a given code region as hot the VM instantly takes the decision to compile it. However, a problem came out from this strategy, the predictor response is only a decision made by means of a heuristic and thus it can be incorrect. Whenever the predictor flags a code region that will be infrequently executed (cold code) as hot code, we say that it is doing a hotness misprediction. Whenever a misprediction happens it means that the technique the VM will use to emulate the code will not have its cost amortized by executing the optimized code and thus the VM will, in fact, spend more time executing its own code rather than the guest application code. In this work we measure the impact of hotness mispredictions in a VM emulating several kinds of applications. In our analysis we evaluate the threshold-based hot code predictor, a technique commonly used to predict hot code fragments. To do so we developed a mathematical model to simulate the behavior of such predictor and we use it to estimate the impact of mispredictions in several benchmarks. We show that this predictor frequently mispredicts the code hotness and as a result the VM emulation performance becomes dominated by miscompilations. Moreover, we show how the threshold choice can affect the number of mispredictions and how this impacts the VM performance. We also show how the compilation, interpretation and steady state execution cost of translated instructions affect the VM performance. At the end we show that using SPEC CPU 2006 benchmarks to measure the performance of a VM using the threshold-based predictor can lead to misleading results / Mestrado / Ciência da Computação / Mestre em Ciência da Computação
172

Genetic Algorithm for Integrated SoftwarePipelining

Cai, Zesi January 2012 (has links)
The purpose of the thesis was to study the feasibility of using geneticalgorithm (GA) to do the integrated software pipelining (ISP). Different from phasedcode generation, ISP is a technique which integrates instruction selection, instructionscheduling, and register allocation together when doing code generation. ISP is able toprovide a lager solution space than phased way does, which means that ISP haspotential to generate more optimized code than phased code generation. However,integrated compiling costs more than phased compiling. GA is stochastic beam searchalgorithm which can accelerate the solution searching and find an optimized result.An experiment was designed for verifying feasibility of implementing GA for ISP(GASP). The implemented algorithm analyzed data dependency graphs of loop bodies,created genes for the graphs and evolved, generated schedules, calculated andevaluated fitness, and obtained optimized codes. The fitness calculation wasimplemented by calculating the maximum value between the smallest possibleresource initiation interval and the smallest possible recurrence initiation interval. Theexperiment was conducted by generating codes from data dependency graphsprovided in FFMPEG and comparing the performance between GASP and integerlinear programming (ILP). The results showed that out of eleven cases that ILP hadgenerated code, GASP performed close to ILP in seven cases. In all twelve cases thatILP did not have result, GASP did generate optimized code. To conclude, the studyindicated that GA was feasible of being implemented for ISP. The generated codesfrom GASP performed similar with the codes from ILP. And for the dependencygraphs that ILP could not solve in a limited time, GASP could also generate optimizedresults.
173

Strong-DISM: A First Attempt to a Dynamically Typed Assembly Language (D-TAL)

Hernandez, Ivory 03 November 2017 (has links)
Dynamically Typed Assembly Language (D-TAL) is not only a lightweight and effective solution to the gap generated by the drop in security produced by the translation of high-level language instructions to low-level language instructions, but it considerably eases up the burden generated by the level of complexity required to implement typed assembly languages statically. Although there are tradeoffs between the static and dynamic approaches, focusing on a dynamic approach leads to simpler, easier to reason about, and more feasible ways to understand deployment of types over monomorphically-typed or untyped intermediate languages. On this occasion, DISM, a simple but powerful and mature untyped assembly language, is extended by the addition of type annotations (on memory and registers) to produce an instance of D-TAL. Strong-DISM, the resulting language, statically, lends itself to simpler analysis about type access and security as the correlation between datatypes and instructions with their respective memory and registers becomes simpler to observe; while dynamically, it disallows operations and further eliminates conditions that from high level languages could be used to violate/circumvent security.
174

A parser generator system to handle complete syntax

Ossher, Harold Leon January 1982 (has links)
To define a language completely, it is necessary to define both its syntax and semantics. If these definitions are in a suitable form, the parser and code-generator of a compiler, respectively, can be generated from them. This thesis addresses the problem of syntax definition and automatic parser generation.
175

Two-Bit Pattern Analysis For Quantitative Information Flow

Meng, Ziyuan 27 March 2014 (has links)
Protecting confidential information from improper disclosure is a fundamental security goal. While encryption and access control are important tools for ensuring confidentiality, they cannot prevent an authorized system from leaking confidential information to its publicly observable outputs, whether inadvertently or maliciously. Hence, secure information flow aims to provide end-to-end control of information flow. Unfortunately, the traditionally-adopted policy of noninterference, which forbids all improper leakage, is often too restrictive. Theories of quantitative information flow address this issue by quantifying the amount of confidential information leaked by a system, with the goal of showing that it is intuitively “small” enough to be tolerated. Given such a theory, it is crucial to develop automated techniques for calculating the leakage in a system. This dissertation is concerned with program analysis for calculating the maximum leakage, or capacity, of confidential information in the context of deterministic systems and under three proposed entropy measures of information leakage: Shannon entropy leakage, min-entropy leakage, and g-leakage. In this context, it turns out that calculating the maximum leakage of a program reduces to counting the number of possible outputs that it can produce. The new approach introduced in this dissertation is to determine two-bit patterns, the relationships among pairs of bits in the output; for instance we might determine that two bits must be unequal. By counting the number of solutions to the two-bit patterns, we obtain an upper bound on the number of possible outputs. Hence, the maximum leakage can be bounded. We first describe a straightforward computation of the two-bit patterns using an automated prover. We then show a more efficient implementation that uses an implication graph to represent the two- bit patterns. It efficiently constructs the graph through the use of an automated prover, random executions, STP counterexamples, and deductive closure. The effectiveness of our techniques, both in terms of efficiency and accuracy, is shown through a number of case studies found in recent literature.
176

Automatic Generation Of Compiled Cycle Level Microarchitecture Simulators For Superspeculative Processors

Chandran, Priya 06 1900 (has links) (PDF)
No description available.
177

Combining Conditional Constant Propagation And Interprocedural Alias Analysis

Nandakumar, K S 05 1900 (has links) (PDF)
No description available.
178

A Domain Specific Language for Digital Forensics and Incident Response Analysis

Stelly, Christopher D 20 December 2019 (has links)
One of the longstanding conceptual problems in digital forensics is the dichotomy between the need for verifiable and reproducible forensic investigations, and the lack of practical mechanisms to accomplish them. With nearly four decades of professional digital forensic practice, investigator notes are still the primary source of reproducibility information, and much of it is tied to the functions of specific, often proprietary, tools. The lack of a formal means of specification for digital forensic operations results in three major problems. Specifically, there is a critical lack of: a) standardized and automated means to scientifically verify accuracy of digital forensic tools; b) methods to reliably reproduce forensic computations (their results); and c) framework for inter-operability among forensic tools. Additionally, there is no standardized means for communicating software requirements between users, researchers and developers, resulting in a mismatch in expectations. Combined with the exponential growth in data volume and complexity of applications and systems to be investigated, all of these concerns result in major case backlogs and inherently reduce the reliability of the digital forensic analyses. This work proposes a new approach to the specification of forensic computations, such that the above concerns can be addressed on a scientific basis with a new domain specific language (DSL) called nugget. DSLs are specialized languages that aim to address the concerns of particular domains by providing practical abstractions. Successful DSLs, such as SQL, can transform an application domain by providing a standardized way for users to communicate what they need without specifying how the computation should be performed. This is the first effort to build a DSL for (digital) forensic computations with the following research goals: 1) provide an intuitive formal specification language that covers core types of forensic computations and common data types; 2) provide a mechanism to extend the language that can incorporate arbitrary computations; 3) provide a prototype execution environment that allows the fully automatic execution of the computation; 4) provide a complete, formal, and auditable log of computations that can be used to reproduce an investigation; 5) demonstrate cloud-ready processing that can match the growth in data volumes and complexity.
179

GPUMap: A Transparently GPU-Accelerated Map Function

Pachev, Ivan 01 March 2017 (has links)
As GPGPU computing becomes more popular, it will be used to tackle a wider range of problems. However, due to the current state of GPGPU programming, programmers are typically required to be familiar with the architecture of the GPU in order to effectively program it. Fortunately, there are software packages that attempt to simplify GPGPU programming in higher-level languages such as Java and Python. However, these software packages do not attempt to abstract the GPU-acceleration process completely. Instead, they require programmers to be somewhat familiar with the traditional GPGPU programming model which involves some understanding of GPU threads and kernels. In addition, prior to using these software packages, programmers are required to transform the data they would like to operate on into arrays of primitive data. Typically, such software packages restrict the use of object-oriented programming when implementing the code to operate on this data. This thesis presents GPUMap, which is a proof-of-concept GPU-accelerated map function for Python. GPUMap aims to hide all the details of the GPU from the programmer, and allows the programmer to accelerate programs written in normal Python code that operate on arbitrarily nested objects using a majority of Python syntax. Using GPUMap, certain types of Python programs are able to be accelerated up to 100 times over normal Python code. There are also software packages that provide simplified GPU acceleration to distributed computing frameworks such as MapReduce and Spark. Unfortunately, these packages do not provide a completely abstracted GPU programming experience, which conflicts with the purpose of the distributed computing frameworks: to abstract the underlying distributed system. This thesis also presents GPU-accelerated RDD (GPURDD), which is a type of Spark Resilient Distributed Dataset (RDD) which incorporates GPUMap into its map, filter, and foreach methods in order to allow Spark applicatons to make use of the abstracted GPU acceleration provided by GPUMap.
180

Rozšíření programovacího jazyka C Plus a jeho překladače / An Extension of the C Plus Programming Language and Its Compiler

Opatřil, Petr January 2017 (has links)
This thesis describes continuing development of new programming language C Plus conceived in earlier Bachelor’s Thesis oriented on enhancing C language with high level constructs with no additional cost. During development, several important languages were compared and C Plus along with its grammar were expanded, advantages of additions were discussed and compared with solutions in other languages. Described enhancements were implemented in the compiler.

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