Tuple Interpretations for Higher-Order Complexity

International Conference on Formal Structures for Computation and Deduction Pub Date : 2021-05-03 DOI:10.4230/LIPIcs.FSCD.2021.31

Cynthia Kop, Deivid Vale

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引用次数: 8

Abstract

We develop a class of algebraic interpretations for many-sorted and higher-order term rewriting systems that takes type information into account. Specifically, base-type terms are mapped to \emph{tuples} of natural numbers and higher-order terms to functions between those tuples. Tuples may carry information relevant to the type; for instance, a term of type $\mathsf{nat}$ may be associated to a pair $(\mathsf{cost}, \mathsf{size})$ representing its evaluation cost and size. This class of interpretations results in a more fine-grained notion of complexity than runtime or derivational complexity, which makes it particularly useful to obtain complexity bounds for higher-order rewriting systems. We show that rewriting systems compatible with tuple interpretations admit finite bounds on derivation height. Furthermore, we demonstrate how to mechanically construct tuple interpretations and how to orient $\beta$ and $\eta$ reductions within our technique. Finally, we relate our method to runtime complexity and prove that specific interpretation shapes imply certain runtime complexity bounds.

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高阶复杂性的元组解释

我们为考虑类型信息的多排序和高阶项重写系统开发了一类代数解释。具体来说，基本类型项映射到\emph{自然数元组}，高阶项映射到这些元组之间的函数。元组可以携带与类型相关的信息;例如，类型为$\mathsf{nat}$的项可能与表示其计算成本和大小的对$(\mathsf{cost}, \mathsf{size})$相关联。这类解释产生了比运行时或派生复杂性更细粒度的复杂性概念，这使得获得高阶重写系统的复杂性界限特别有用。我们证明了与元组解释兼容的重写系统在派生高度上承认有限的界。此外，我们还演示了如何机械地构造元组解释，以及如何在我们的技术中定位$\beta$和$\eta$约简。最后，我们将我们的方法与运行时复杂性联系起来，并证明特定的解释形状暗示了某些运行时复杂性界限。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International Conference on Formal Structures for Computation and Deduction

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