Difference between revisions of "CS598 - Runtime Verification (Spring 2017)"

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Exercise 8 (page 87); Exercises 10,11 (page 121); Exercise 13 (page 151); Exercise 14 (page 169).
Exercise 8 (page 87); Exercises 10,11 (page 121); Exercise 13 (page 151); Exercise 14 (page 169).
:* '''''Efficient Monitoring of Always-Past Temporal Safety (Section 10)''''' {{pdf|CS598-Spring-2017-09.pdf|Book Draft}} (version 8)

Revision as of 19:47, 22 February 2017

Students enrolled in this class are expected to check this web page regularly. Complete lecture notes will be posted here.

Course Description

Runtime verification (RV) is a software analysis approach where programs are formally analyzed as they execute. This can be done using program instrumentation, or using special execution environments (for example, a semantics-based symbolic execution engine), or both. In its most simplistic form, RV can be used to detect or predict bugs in programs. In a more sophisticated form, RV can be used to prove programs correct by systematically executing programs on all their (symbolic) paths. The course will cover the major RV approaches and techniques, as well as semantic foundations.

By the end of the course, students are expected to master the major RV approaches, at both the foundational and the algorithmic levels. They will also read and present papers on RV, and will likely do a (joint) project that falls at the intersection of their area of interest and RV. Since RV is a relatively new area, the course will also stimulate research ideas and possibly lead to some publications.

Meetings: W/F 14:00 - 15:15, 1131 Siebel Center
Credit: 4 credits
Professor: Grigore Rosu (Office: SC 2110)
Office hours: Held by Grigore Rosu in SC 2110; by appointment.

Lecture Notes, Useful Material

The links below provide you with useful material for this class, including complete lecture notes. These materials will be added by need.

  • Some runtime verification systems to try out:
  • JavaMOP (online) for monitor synthesis and runtime monitoring of safety properties
  • RV-Predict for predictive runtime analysis
  • RV-Match for semantics-based runtime verification
  • Safety and Monitoring Foundations 25px-Pdf_icon.png Book Draft Info_circle.png (version 1)
  • Safety Properties (Chapter 3), Monitoring (Chapter 4) 25px-Pdf_icon.png Book Draft Info_circle.png (version 2)
HW1 (due Friday, February 10) Downarrow.png

Exercise 1 (page 16); Exercises 2,3,4,5,6 (page 36); Exercise 7 (page 51).

  • Monitoring ERE is Non-Elementary (Section 6.1) 25px-Pdf_icon.png Book Draft Info_circle.png (version 3)
  • Generating Optimal ERE Monitors (Section 6.1.2) 25px-Pdf_icon.png Book Draft Info_circle.png (version 4)
  • Monitoring Finite-Trace Future-Time LTL (Sections 8 (LTL) and 6 (BTT)) 25px-Pdf_icon.png Book Draft Info_circle.png (version 5)
  • Monitoring Omega-Regular Expressions (Section 9) 25px-Pdf_icon.png Book Draft Info_circle.png (version 6)
  • HW2 version 25px-Pdf_icon.png Book Draft Info_circle.png (version 7)
HW2 (due Wednesday, March 1st) Downarrow.png

Exercise 8 (page 87); Exercises 10,11 (page 121); Exercise 13 (page 151); Exercise 14 (page 169).

  • Efficient Monitoring of Always-Past Temporal Safety (Section 10) 25px-Pdf_icon.png Book Draft Info_circle.png (version 8)
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