具有Length和MaxDiff的数组的插值结果

IF 0.7 4区数学 Q3 COMPUTER SCIENCE, THEORY & METHODS

ACM Transactions on Computational Logic Pub Date : 2023-06-09 DOI:https://dl.acm.org/doi/10.1145/3587161

Silvio Ghilardi, Alessandro Gianola, Deepak Kapur, Chiara Naso

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引用次数: 0

摘要

在本文中，我们用length和maxdiff操作丰富了McCarthy的扩展数组理论。众所周知，在数组理论中，需要一些差分操作(即某种差分函数显示两个不相等数组的不同之处)来保持插值量词的自由。maxdiff操作返回两个数组不同处的最大索引;因此，它具有惟一确定的语义。length函数是maxdiff操作的自然补充，需要处理实际数组。为这样一个丰富的理论获得插值结果是一项非常困难的任务。我们通过对理论模型及其合并和强合并特性进行深入的语义分析，得出了上述结论。所得结果相对于指标理论是模性的;我们展示了如何通过分层方法将它们转换为具体的插值算法，实现了赋予自由函数符号的线性算法中的多项式约简插值。

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Interpolation Results for Arrays with Length and MaxDiff

In this article, we enrich McCarthy’s theory of extensional arrays with a length and a maxdiff operation. As is well-known, some diff operation (i.e., some kind of difference function showing where two unequal arrays differ) is needed to keep interpolants quantifier free in array theories. Our maxdiff operation returns the max index where two arrays differ; thus, it has a univocally determined semantics.

The length function is a natural complement of such a maxdiff operation and is needed to handle real arrays. Obtaining interpolation results for such a rich theory is a surprisingly hard task. We get such results via a thorough semantic analysis of the models of the theory and of their amalgamation and strong amalgamation properties. The results are modular with respect to the index theory; we show how to convert them into concrete interpolation algorithms via a hierarchical approach realizing a polynomial reduction to interpolation in linear arithmetics endowed with free function symbols.

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来源期刊

ACM Transactions on Computational Logic 工程技术-计算机：理论方法

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： TOCL welcomes submissions related to all aspects of logic as it pertains to topics in computer science. This area has a great tradition in computer science. Several researchers who earned the ACM Turing award have also contributed to this field, namely Edgar Codd (relational database systems), Stephen Cook (complexity of logical theories), Edsger W. Dijkstra, Robert W. Floyd, Tony Hoare, Amir Pnueli, Dana Scott, Edmond M. Clarke, Allen E. Emerson, and Joseph Sifakis (program logics, program derivation and verification, programming languages semantics), Robin Milner (interactive theorem proving, concurrency calculi, and functional programming), and John McCarthy (functional programming and logics in AI). Logic continues to play an important role in computer science and has permeated several of its areas, including artificial intelligence, computational complexity, database systems, and programming languages. The Editorial Board of this journal seeks and hopes to attract high-quality submissions in all the above-mentioned areas of computational logic so that TOCL becomes the standard reference in the field. Both theoretical and applied papers are sought. Submissions showing novel use of logic in computer science are especially welcome.