Includes bibliographical references and index.

Preface xiii PART I VERIFICATION 1. Modeling and Verification of Distributed Systems Using Markov Decision Processes 3 1.1 Introduction 4 1.2 Markov Decision Processes 5 1.3 Markov Decision Well-Formed Net formalism 8 1.4 Case study: Peer-to-Peer Botnets 10 1.5 Conclusion 18 Appendices: Well-formed Net Formalism 21 A.1.1 Syntax of Basic Predicates 22 A.1.2 Markings and Enabling 23 References 25 2 Quantitative Analysis of Distributed Systems in Stoklaim: A Tutorial 27 2.1 Introduction 28 2.2 StoKlaim: Stochastic Klaim 29 2.3 StoKlaim Operational Semantics 34 2.4 MoSL: Mobile Stochastic Logic 43 2.5 jSAM: Java Stochastic Model-Checker 47 2.6 Leader Election in StoKlaim 49 2.7 Concluding Remarks 52 References 53 3 Stochastic Path Properties of Distributed Systems: the CSLTA Approach 57 3.1 Introduction 58 3.2 The Reference Formalisms for System Definition 59 3.3 The Formalism for Path Property Definition: CSLTA 61 3.4 CSLTA at work: a Fault-Tolerant Node 67 3.5 Literature Comparison 71 3.6 Summary and Final Remarks 73 References 75 PART II EVALUATION 4 Failure Propagation in Load-Sharing Complex Systems 81 4.1 Introduction 82 4.2 Building Blocks 84 4.3 Sand Box for Distributed Failures 89 4.4 Summary 102 References 103 5 Approximating Distributions and Transient Probabilities by Matrix Exponential Distributions and Functions 107 5.1 Introduction 108 5.2 Phase Type and Matrix Exponential Distributions 109 5.3 Bernstein Polynomials and Expolynomials 114 5.4 Application of BEs to Distribution Fitting 116 5.5 Application of BEs to Transient Probabilities 121 5.6 Conclusions 124 References 125 6 Worst-Case Analysis of Tandem Queueing Systems Using Network Calculus 129 6.1 Introduction 130 6.2 Basic Network Calculus Modeling: Per-flow Scheduling 132 6.3 Advanced Network Calculus Modeling: Aggregate Multiplexing 148 6.4 Tandem Systems Traversed by Several Flows 152 6.5 Mathematical Programming Approach 154 6.6 Related Work 165 6.7 Numerical Results 166 6.8 Conclusions 168 References 171 7 Cloud Evaluation: Benchmarking and Monitoring 175 7.1 Introduction 176 7.2 Benchmarking 176 7.3 Benchmarking with mOSAIC 184 7.4 Monitoring 185 7.5 Cloud Monitoring in mOSAIC?s Cloud Agency 191 7.6 Conclusions 193 References 195 8 Multiformalism and Multisolution Strategies for Systems Performance 201 8.1 Introduction 202 8.2 Multiformalism and Multisolution 203 8.3 Choosing the Right Strategy 205 8.4 Learning by the Experience 206 8.5 Conclusions and Perspectives 218 References 219 PART III OPTIMIZATION AND SUSTAINABILITY 9 Quantitative Assessment of Distributed Networks Through Hybrid Stochastic Modeling 225 9.1 Introduction 226 9.2 Modeling of Complex Systems 228 9.3 Performance Evaluation of KNXnet/IP Networks Flow Control Mechanism 234 9.4 LCII: On-line Risk Estimation of A Power-Telco Network 248 9.5 Conclusion 259 References 261 10 Design of IT Infrastructures of Data Centers: An Approach Based on Business and Technical Metrics 265 10.1 Introduction 266 10.2 Fundamental Concepts 267 10.3 Business-Oriented Models 270 10.4 Data Center Infrastructure Models 274 10.5 Methodology 277 10.6 Case Study - Data Center Design 283 10.7 Conclusion 292 References 297 11 Software Rejuvenation and its Application in Distributed Systems 301 11.1 Introduction 302 11.2 Software rejuvenation scheduling classification 304 11.3 Software rejuvenation granularity classification 307 11.4 Methods, policies and metrics of software rejuvenation 314 11.5 Software rejuvenation in distributed systems 315 11.6 Summary 318 References 321 12 Machine Learning Based Dynamic Reconfiguration of Distributed Data Management Systems 327 12.1 Introduction 328 12.2 Methodologies 330 12.3 Brief overview of Neural Networks 334 12.4 System Architecture and Performance Prediction Scheme 336 12.5 Experimentation 339 12.6 Conclusions 346 References 347 13 Going Green with the Networked Cloud: Methodologies and Assessment 351 13.1 Introduction 352 13.2 Modeling of Data Centre Power Consumption 353 13.3 Energy Efficiency in the Cloud 356 13.4 Performance Analysis Methodologies and Tools 361 13.5 Case Study: Performance Evaluation of Energy Aware Resource Allocation in the Cloud 366 13.6 Summary 370 References 371 Index 375.

Distributed systems employed in critical infrastructures must fulfill dependability, timeliness, and performance specifications. Since these systems most often operate in an unpredictable environment, their design and maintenance require quantitative evaluation of deterministic and probabilistic timed models. This need gave birth to an abundant literature devoted to formal modeling languages combined with analytical and simulative solution techniques The aim of the book is to provide an overview of techniques and methodologies dealing with such specific issues in the context of distributed systems and covering aspects such as performance evaluation, reliability/availability, energy efficiency, scalability, and sustainability. Specifically, techniques for checking and verifying if and how a distributed system satisfies the requirements, as well as how to properly evaluate non-functional aspects, or how to optimize the overall behavior of the system, are all discussed in the book. The scope has been selected to provide a thorough coverage on issues, models. and techniques relating to validation, evaluation and optimization of distributed systems. The key objective of this book is to help to bridge the gaps between modeling theory and the practice in distributed systems through specific examples.