On computational open-endedness in Martin-Lof's type theory

by Douglas J. Howe
1991

Published in Proceedings of Sixth Annual IEEE Symposium on Logic in Computer Science, LICS '91.
Official copy (Full text available through most universities.)

Abstract
Computational open-endedness in a type theory is defined as the property that theorems remain true under extensions to the underlying programming language. Some properties related to open-endedness that are relevant to machine implementations of type theory are established. A class of computation systems, specified by a simple but fairly general kind of structural operational semantics, with respect to which P. Martin-Lof's (6th Int. Congress for Logic, Methodology, and Philosophy of Science, p.153-175, 1982) type theory (and most of its descendants) is open-ended is defined. It is shown that any such system validates a useful form of type free reasoning about program equivalence and that symbolic computation procedures can be automatically derived from these specifications. The main result is the definition of a particular computation system that includes a collection of oracles sufficient to provide a classical semantics for Martin-Lof's type theory in which the excluded middle law holds.

On computational open-endedness in Martin-Lof's type theory

by Douglas J. Howe 1991

by Douglas J. Howe
1991