立方议程:一种独立类型的程序设计语言,具有单一性和高级归纳类型

IF 1.1 3区 计算机科学 Q4 COMPUTER SCIENCE, SOFTWARE ENGINEERING
ANDREA VEZZOSI, ANDERS MÖRTBERG, ANDREAS ABEL
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引用次数: 0

摘要

基于依赖类型理论的证明助手为同一系统内的编程和证明提供了表达语言。然而,所有主要的实现都缺乏强大的关于等式推理的可拓性原则,例如函数和命题的可拓性。这些原则通常是公理化地添加的,这破坏了这些系统的构造性质。三次类型理论通过赋予同伦类型理论和一元基础,特别是一元公理和高归纳类型(hit)计算意义,提供了一个解决方案。本文描述了使用立方原语对依赖类型函数式编程语言Agda进行的扩展,使其成为一个具有本机单一性支持的完备证明助手和hit的通用模式。这些新的原语允许直接定义函数和命题扩展性以及商类型,所有这些都具有计算内容。此外,由于有了共同模式,对于共归纳类型,双相似性等价于相等性。立方体类型理论的采用在不牺牲类型检查和构造性的前提下,通过支持广泛的可扩展性原则扩展了Agda。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cubical Agda: A dependently typed programming language with univalence and higher inductive types
Proof assistants based on dependent type theory provide expressive languages for both programming and proving within the same system. However, all of the major implementations lack powerful extensionality principles for reasoning about equality, such as function and propositional extensionality. These principles are typically added axiomatically which disrupts the constructive properties of these systems. Cubical type theory provides a solution by giving computational meaning to Homotopy Type Theory and Univalent Foundations, in particular to the univalence axiom and higher inductive types (HITs). This paper describes an extension of the dependently typed functional programming language Agda with cubical primitives, making it into a full-blown proof assistant with native support for univalence and a general schema of HITs. These new primitives allow the direct definition of function and propositional extensionality as well as quotient types, all with computational content. Additionally, thanks also to copatterns, bisimilarity is equivalent to equality for coinductive types. The adoption of cubical type theory extends Agda with support for a wide range of extensionality principles, without sacrificing type checking and constructivity.
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来源期刊
Journal of Functional Programming
Journal of Functional Programming 工程技术-计算机:软件工程
CiteScore
1.70
自引率
0.00%
发文量
9
审稿时长
>12 weeks
期刊介绍: Journal of Functional Programming is the only journal devoted solely to the design, implementation, and application of functional programming languages, spanning the range from mathematical theory to industrial practice. Topics covered include functional languages and extensions, implementation techniques, reasoning and proof, program transformation and synthesis, type systems, type theory, language-based security, memory management, parallelism and applications. The journal is of interest to computer scientists, software engineers, programming language researchers and mathematicians interested in the logical foundations of programming.
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