用于验证计算的连续抽象数据类型

Sewon Park
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摘要

摘要本文设计了一种命令式编程语言,将实数作为抽象的数据类型提供,使用户可以将实数作为抽象的数学实体来表达实数计算。不像其他常见的实数计算方法,基于缺乏可实现性或超越计算的代数模型,或有限精度近似,如使用缺乏正式基础的双精度计算,我们的语言是基于可计算分析设计的,这是对连续数据进行严格计算的基础。因此,该语言的用户可以很容易地编程实数计算和推理他们的程序的行为,依靠他们对实数的数学知识,而不用担心人为的舍入误差。由于语言是命令式的,我们采用了前置-后置条件风格的程序规范和hoare风格的程序验证方法。因此,该语言的用户可以很容易地编写对实数的计算,指定程序的预期行为,包括终止,并证明规范的正确性。此外,我们建议用其他有趣的连续数据扩展语言,如矩阵、连续实函数等。摘要直接摘自论文。电子邮件:sewonpark17@gmail.com URL: https://sewonpark.com/thesis
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Continuous Abstract Data Types for Verified Computation
Abstract We devise imperative programming languages for verified real number computation where real numbers are provided as abstract data types such that the users of the languages can express real number computation by considering real numbers as abstract mathematical entities. Unlike other common approaches toward real number computation, based on an algebraic model that lacks implementability or transcendental computation, or finite-precision approximation such as using double precision computation that lacks a formal foundation, our languages are devised based on computable analysis, a foundation of rigorous computation over continuous data. Consequently, the users of the language can easily program real number computation and reason about the behaviours of their programs, relying on their mathematical knowledge of real numbers without worrying about artificial roundoff errors. As the languages are imperative, we adopt precondition–postcondition-style program specification and Hoare-style program verification methodologies. Consequently, the users of the language can easily program a computation over real numbers, specify the expected behaviour of the program, including termination, and prove the correctness of the specification. Furthermore, we suggest extending the languages with other interesting continuous data, such as matrices, continuous real functions, et cetera. Abstract taken directly from the thesis. E-mail: sewonpark17@gmail.com URL: https://sewonpark.com/thesis
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POUR-EL’S LANDSCAPE CATEGORICAL QUANTIFICATION POINCARÉ-WEYL’S PREDICATIVITY: GOING BEYOND A TOPOLOGICAL APPROACH TO UNDEFINABILITY IN ALGEBRAIC EXTENSIONS OF John MacFarlane, Philosophical Logic: A Contemporary Introduction, Routledge Contemporary Introductions to Philosophy, Routledge, New York, and London, 2021, xx + 238 pp.
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