Abstract
The thesis of this dissertation is that compilers can and should allow programmers to extend programming languages with new syntax, features, and restrictions by writing extension modules that act as plugins for the compiler. We call compilers designed around this idea extension-oriented. The central challenge in designing and building an extension-oriented compiler is the creation of extension interfaces that are simultaneously powerful, to allow effective extensions; convenient, to make these extensions easy to write; and composable, to make it possible to use independently-written extensions together. This dissertation proposes and evaluates extension-oriented syntax trees (XSTs) as a way to meet these challenges. The key interfaces to XSTs are grammar statements, a convenient, composable interface to extend the input parser; syntax patterns, a way to manipulate XSTs in terms of the original program syntax; canonicalizers, which put XSTs into a canonical form to extend the reach of syntax patterns; and attributes, a lazy computation mechanism to structure analyses on XSTs and allow extensions to cooperate. We have implemented these interfaces in a small procedural language called zeta. Using zeta, we have built an extension-oriented compiler for C called xoc and then 13 extensions to C ranging in size from 16 lines to 245 lines.To evaluate XSTs and xoc, this dissertation examines two examples in detail: a reimplementation of the programming language Alef and a reimplementation of the Linux kernel checker Sparse. Both of these examples consist of a handful of small extensions
Cite
CITATION STYLE
Cox, R. S. (2008). An Extension-Oriented Compiler. Computer, 110.
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