Compiler Construction With Embedded Xinu

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Revision as of 20:31, 28 July 2010 by Amallen (talk | contribs) (added link to our Concurrent MiniJava grammar)
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Overview

Having students construct a compiler which targets a runtime that uses their own, or a provided, Xinu operating system is one of the potential tracks for a professor that is Teaching With Xinu.

Including Embedded Xinu in a compiler construction course allows students to explore the compilation of high level language constructs that rely on interacting with the underlying runtime. Many traditional compilers courses simply target a processor or simulator, but by targeting a platform (a processor and operating system combination) one can extend the source language to include more advanced language features such as I/O operations and thread creation, manipulation, and concurrency. This also allows students to run their test cases on real hardware and see these programs actually interacting with a real runtime. In modern programming these high level language features are vital, and it is important for students to see what the processor and runtime are doing when they use these features in their own programs.

Course Outcomes

Course development can parallel learning objectives and topics associated with many Programming Language Translation or Compiler Construction courses. [1] However, by targeting a platform with an operating system students can also focus on learning how compilers interact with the runtime to achieve thread concurrency and synchronization; topics which many traditional compilers courses avoid. [2, 3, 4]

Topics

  • Lexical Analysis
  • Syntax Analysis
  • Semantic Analysis
  • IR Translation
  • Instruction Selection
  • Register Allocation

Learning Objectives

  • Recognize various classes of grammars, languages, and automata, and employ these to solve common software problems.
  • Explain the major steps involved in compiling a high-level programming language down to a low-level target machine language.
  • Construct and use the major components of a modern compiler.
  • Work together effectively in teams on a substantial software implementation project.

Potential Course Structure

The course outlined below describes a compiler construction course focusing on a semester long project in which students build most of the pieces of a complete working compiler. For this example course we take the compiler project from Appel and Palsberg's Modern Compiler Implementation in Java [2] and modify it to target a MIPS platform running the Xinu operating system. The links in the outline below describe the changes necessary in each assignment to add high level I/O and concurrency features to the language, including the modifications for targeting a Xinu backend instead of the book's intended MIPS simulator.

Appel and Palsberg's MiniJava language is a subset of the standard Java language, and this means test cases written in MiniJava can be compiled and run using standard Java compilers. To use standard Java compilers to compile programs written in our modified MiniJava language one needs our Xinu.java helper class.

Course Outline
Week Topics Assignments
01 Introduction Project 1: Interpreter
02 Lexical Analysis, Automata Project 2: Scanner
03 Syntax Analysis, Grammars Homework 1: Automata and Grammars
04 Parser Generators Project 3: Parser
05 Abstract Syntax Trees
06 Semantic Analysis Project 4: Semantic Analysis
07 Activation Records
08 IR Translation
09 Basic Blocks Project 5: Translation
10 Instruction Selection Homework 2: Activation Records
11 Liveness Analysis
12 Register Allocation
13 Register Allocation Project 6: Instruction Selection
14 Advanced Topics
15 Advanced Topics Homework 3: Register Allocation
Books

References

[1] Course topics and learning objectives have been adapted from the ACM's Computing Curricula 2001 Computer Science.

[2] Andrew W. Appel and Jens Palsberg, Modern Compiler Implementation in Java, 2nd Edition, Cambridge University Press, 2002

[3] A. V. Aho, M. Lam, R. Sethi, and J. D. Ullman. Compilers: Principles, Techniques and Tools. Pearson, 2nd edition, 1985.

[4] S. Muchnick. Advanced Compiler Design and Implementation. Morgan Kaufmann, 1997.


This work funded in part by NSF grant DUE-CCLI-0737476.