System Software

339.022

2KV

Mössenböck

Th 13:45-15:15

HS 18

Begin: 10.10.2024

This course is a KV (combined course consisting of lectures and project work) in which you will learn the concepts and the implementation of various system software components such as garbage collectors, linkers, loaders, debuggers and text editors. In addition to the principal algorithms the course will also discuss case studies of such programs. The course is given in English. It is part of the Major Subjects Software Engineering and Computational Engineering in the Computer Science Master programme.

The course is taught on campus and is not streamed. If you missed a lecture you can watch the video recordings from a previous semester. However, it is strongly recommended, that you attend the lectures, because it is more lively and also gives you the opportunity to ask questions.

Lecture Dates

Date	Topic
10.10.2024	Memory Management
17.10.2024 24.10.2024 31.10.2024	Garbage Collection
07.11.2024 21.11.2024	Linkers/Loaders no lecture on 14.11.
28.11.2024	Debuggers, Text Editors
05.12.2024	Text Editors
12.12.2024	Written Exam
rest	Project
16.01.2025	Project submission

1. Memory Management
   1.1 Overview
   1.2 Allocation and deallocation of memory
   1.3 Simple free list
   1.4 Multiple free lists
   1.5 Buddy system
   1.6 Memory fragmentation

2. Garbage Collection
   2.1 Motivation
   2.2 Basic techniques
       2.2.1 Reference Counting
       2.2.2 Mark & Sweep
       2.2.3 Stop & Copy
   2.3 Variants
       2.3.1 Mark & Compact
       2.3.2 Generation scavenging
   2.4 Incremental garbage collection
       2.4.1 Tricolor marking
       2.4.2 Train algorithm
   2.5 Finding root pointers
       2.5.1 Pointer tables
       2.5.2 Conservative garbage collection
   2.6 Garbage collection in multi-threaded systems
   2.7 Finalization
   2.8 Case study: Java Hotspot VM
   2.9 Case study: .NET

3. Linkers and Loaders
   3.1 Overview
   3.2 Case study: Oberon
       3.2.1 Run-time data structures
       3.2.2 Resolving external references
       3.2.3 Load algorithm
   3.3 Case study: Java
       3.3.1 Overview
       3.3.2 Class files
       3.3.3 Loading phases
       3.3.4 Example: custom class loader
   3.4 Linking/loading in C/C++

4. Debuggers
   4.1 Architecture
   4.2 Case study: Java Platform Debugger

5. Text Editors
   5.1 Data structures for texts
       5.1.1 SimpleText
       5.1.2 GapText
       5.1.3 PieceListText
   5.2 Text representation on the screen (case study)
       5.2.1 Line descriptors
       5.2.2 Positions
       5.2.3 Input handling
       5.2.4 Updating the view
       5.2.5 Scrolling

Exam

The written exam will be on Thursday, December 12, 2024, 13:45-15:15. Please register via Kusss. The room(s) will be announced on December 11 on ssw.jku.at.

In order to pass the course, you will have to implement also the project. The final mark will be computed from the exam (90 points) and from the project (15 points).

Project

Part of the course will be a project in which either a garbage collector, a debugger or a text editor has to be implemented.

The project must be presented via Zoom on January 16, 2025 between 12:00 and 17:00. Further details will follow.

Downloads

The slides can be downloaded from the Kusss page or the Moodle page of this course.
Source code of the prototype editor

Literature

Books

Jones, R., Hosking, A., Moss, E.: The Garbage Collection Handbook. CRC Press, 2012
Jones R., Lins R.: Garbage Collection. Algorithms for Automatic Dynamic Memory Management. Wiley, 1996.
Venners B.: Inside the Java Virtual Machine. McGraw-Hill 1999. www.artima.com/insidejvm/ed2/
Kokosa, K.: Pro .NET Memory Management. Apress 2018.
Levine J.R.: Linkers & Loaders. Morgan Kaufmann, 2000.
Rosenberg J.B.: How Debuggers Work. Algorithms, Data Structures, and Architecture. Wiley, 1996.

Papers

Garbage Collection

General

Wilson P.R.:. Uniprocessor Garbage Collection Techniques. Technical Report, University of Texas, 1994. ftp://ftp.cs.utexas.edu/pub/garbage/bigsurv.ps

Reference counting

Collins, G. E: A method for overlapping and erasure of lists. Communications of the ACM 3, 12 (Dec 1960), 655-657

Mark & Sweep

McCarthy, J.: Recursive functions of symbolic expressions and their computation by machine. Communications of the ACM 3 (1960), 184-195.
Schorr, Waite: An efficient machine-independent procedure for garbage collection in various list structures. Communications of the ACM (August 1967), 501-505

Stop & Copy

Cheney C.J.: A Nonrecursive List Compacting Algorithm. Communications of the ACM, 13(119):677-678, November 1970

Generation Scavenging

Ungar, D.: Generation scavenging: A nondisruptive high performance storage reclamation algorithm. ACM SIGPLAN Notices 19, 5 (May 1984) and ACM Software Engineering Notes 9, 3 (May 1984).
Appel A.W.: Simple Generational Garbage Collection and Fast Allocation. Software Practice and Experience, 1988
Ungar, D., Jackson, F.: An adaptive tenuring policy for generation scavengers. ACM Transactions on Programming Languages and Systems 1, 1 (January 1992), 1-27

Pointer tables and conservative garbage collection

Agesen O., Detlefs D.L.: Finding References in Java Stacks. OOPSLA’97 Garbage Collection and Memory Management Workshop. Atlanta, GA, October 1997. citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.47.6924.
Boehm H.J., Weiser M.: 1988. Garbage collection in an uncooperative environment. Software -- Practice and Experience. 18(9):807-820
Diwan A., Moss E., Hudson R.: Compiler Support for Garbage Collection in a Statically Typed Language. Proceedings PLDI'92, p. 273-282, San Francisco, CA, June 1992.

Safepoints

Agesen O.: GC points in a threaded environment. Technical report, Sun Microsystems, 1998. citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.44.2891

Miscellaneous

Detlefs D., Printezis T.: A Generational Mostly-Concurrent Garbage Collector. Intl. Symp. on Memory Management (ISMM), 2000, 143-154. dl.acm.org/citation.cfm?id=362480
Deutsch, L P., Bobrow, D. G.: An efficient incremental automatic garbage collector. Communications of the ACM 19,9 (Sept. 1976),522-526.
Lieberman, H, Hewitt, C. A real-time garbage collector based on the lifetimes of objects. Communications of the ACM 26, 6 (June 1983), 419-429.

Linkers, Loaders

Lindholm T., Yellin F.: The Java Virtual Machine Specification https://docs.oracle.com/javase/specs/jls/se12/html/
Venners B.: Inside the Java Virtual Machine. McGraw-Hill 1999. www.artima.com/insidejvm/ed2/
Liang S., Bracha G.: Dynamic Class Loading in the Java Virtual Machine. Proceedings of OOPSLA'98, 36-44. dl.acm.org/citation.cfm?id=286945
The Java class loader architecture: www.securingjava.com/chapter-two/chapter-two-7.html
Gutknecht J., Wirth N.: Project Oberon - The Design of an Operating System and Compiler. ACM Press, 1992
Franz M.: Dynamic Linking of Software Components. IEEE Computer 30(3): 74-81, March 1997.
Presser L., White J.R.: Linkers and Loaders. Computing Surveys 4(3): 149-167, September 1972.

Debuggers

The Java Platform Debugger Architecture (JPDA): docs.oracle.com/javase/8/docs/technotes/guides/jpda/
Debugger dbx: en.wikipedia.org/wiki/Dbx_(debugger)

Text Editors

Wiki with links to text editor resources: texteditors.org/cgi-bin/wiki.pl?DesigningTextEditors
Gutknecht J.: Concepts of the Text Editor Lara. Communications of the ACM 28(9): 942-960, Sept. 1985.
Bruce C.: Design and Implementation of an Advanced Text Editor. mclauchlan.site.net.au/scott/C=Hacking/C-Hacking11/zedace.html
Finseth C.A.: The Craft of Text Editing. www.finseth.com/craft/
Various text editor implementations from the GNU Free Software Foundation: https://directory.fsf.org/wiki/Category/Use/editing
Hansen W.J.: Data Structures in a Bit-Mapped Text Editor. BYTE: 183-190, January 1987.