Course details

Formal Program Analysis

FAD Acad. year 2018/2019 Winter semester

Current academic year

An overview of various methods of analysis and verification of programs with formal roots. Model checking of finite-state systems: the basic principles, specification of properties to be verified, temporal logics, the state explosion problem and existing approaches to solving it, efficient storage of state spaces, state space reductions, modular verification, automated abstraction (with a stress on predicate abstraction that plays a key role in software model checking). Model checking of infinite-state systems: cut-offs, symbolic model checking, abstraction, automated induction. Theorem proving, SAT solving, SMT solving. Various ways of static analysis, dataflow analysis, constraint-based analysis, type analysis, metacompilation, abstract interpretation. Dynamic analysis with a formal basis, algorithms like Eraser or Daikon, applications automated inference methods in dynamic analysis.

Guarantor

Language of instruction

Czech, English

Completion

Examination (written+oral)

Time span

  • 26 hrs lectures

Assessment points

  • 100 pts final exam

Department

Lecturer

Instructor

Subject specific learning outcomes and competences

Acquaintance with possibilities, limitations, and principles of the state-of-the-art methods of program analysis on a formal basis. Ability to apply them in advanced projects and an overall knowledge of the way these techniques can evolve in the future.
A deeper ability to read and create formal texts.

Learning objectives

The goal of the course is to acquaint the students with principles, possibilities, and restrictions of the currently most successful methods known, resp. being studied, in the area of applying formal methods for an automated analysis and verification of programs.

Prerequisite knowledge and skills

Acquaintance with basics of logics, algebra, graph theory, theory of formal languages and automata, compilers, and computability and complexity.

Study literature

  • Clarke, E.M., Grumberg, O., Peled, D.A.: Model Checking, MIT Press, 2000. ISBN 0-262-03270-8
  • Berard, B., Bidoit, M., Finkel, A., Laroussinie, F., Petit, A., Petrucci, L., Schnoebelen, P., McKenzie, P.: Systems and Software Verification: Model-Checking Techniques and Tools, Springer-Verlag, 2001. ISBN 3-540-41523-8
  • Monin, J.F., Hinchey, M.G.: Understanding Formal Methods, Springer-Verlag, 2003. ISBN 1-852-33247-6
  • Valmari, A.: The State Explosion Problem. In Reisig, W., Rozenberg, G.: Lectures on Petri Nets I: Basic Models, Lecture Notes in Computer Science, č.1491, s. 429-528. Springer-Verlag, 1998. ISBN 3-540-65306-6
  • Nielson, F., Nielson, H.R., Hankin, C.: Principles of Program Analysis, Springer-Verlag, 2005. ISBN 3-540-65410-0
  • Schwartzbach, M.I.: Lecture Notes on Static Analysis, BRICS, Department of Computer Science, University of Aarhus, Denmark, 2006.

Syllabus of lectures

  1. An overview of the existing methods of formal analysis and verification of programs, their possibilities, advantages and disadvantages.
  2. Model checking of finite-state systems: the basic principle, specification of properties to be checked, temporal logics.
  3. The state explosion problem and possibilities of fighting it, efficient state space storage, state space reduction.
  4. Modular verification, automated abstraction with a stress on predicate abstraction, Craig interpolants.
  5. Model checking of infinite-state systems: cut-offs, symbolic verification, abstraction, automated induction.
  6. Theorem proving.
  7. SAT solving, SMT solving.
  8. Static analysis based on dataflow analysis.
  9. Constraint-based static analysis.
  10. Type analysis.
  11. Metacompilation.
  12. Abstract interpretation.
  13. Dynamic analysis on a formal basis, algorithms like Eraser and Daikon, using automated inference methods in dynamic analysis.

Progress assessment

Discussions within the lectures, a check of the prepared report.

Controlled instruction

Lectures and a preparation of a report.

Course inclusion in study plans

Back to top