Affiliation:
1. Purdue University, USA
2. University of Iowa, USA
Abstract
This paper proposes a new approach to writing and verifying divide-and-conquer programs in Coq. Extending the rich line of previous work on algebraic approaches to recursion schemes, we present an algebraic approach to divide-and-conquer recursion: recursions are represented as a form of algebra, and from outer recursions, one may initiate inner recursions that can construct data upon which the outer recursions may legally recurse. Termination is enforced entirely by the typing discipline of our recursion schemes. Despite this, our approach requires little from the underlying type system, and can be implemented in System
F
ω
plus a limited form of positive-recursive types. Our implementation of the method in Coq does not rely on structural recursion or on dependent types. The method is demonstrated on several examples, including mergesort, quicksort, Harper’s regular-expression matcher, and others. An indexed version is also derived, implementing a form of divide-and-conquer induction that can be used to reason about functions defined via our method.
Publisher
Association for Computing Machinery (ACM)
Subject
Safety, Risk, Reliability and Quality,Software
Reference58 articles.
1. Ki Yung Ahn and Tim Sheard . 2011 . A Hierarchy of Mendler Style Recursion Combinators: Taming Inductive Datatypes with Negative Occurrences . In Proceedings of the 16th ACM SIGPLAN International Conference on Functional Programming (Tokyo, Japan) ( ICFP '11). ACM , New York, NY, USA , 234 - 246 . Ki Yung Ahn and Tim Sheard. 2011. A Hierarchy of Mendler Style Recursion Combinators: Taming Inductive Datatypes with Negative Occurrences. In Proceedings of the 16th ACM SIGPLAN International Conference on Functional Programming (Tokyo, Japan) ( ICFP '11). ACM, New York, NY, USA, 234-246.
2. Defining and Reasoning About Recursive Functions: A Practical Tool for the Coq Proof Assistant