Í. Í. Romeo, L. Mangeruca, T. Villa, A. Sangiovanni-Vincentelli
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引用次数: 4
摘要
寻求形式为A x <= B的表达式的最大解是工程和计算机科学的几个领域中的常见任务。这个最大解通常称为商。在不同的域中,二进制操作和预排序的含义是完全不同的,但是计算最大解决方案的语法却非常相似。本文的目的是寻找一个关于商的通用推理框架。我们只假设我们在一个具有抽象单调乘法和对合的预阶上操作。我们提供了一个条件,称为可容许性,它保证商的存在,并得出它的封闭形式。我们称满足容许条件的结构为预定堆。我们表明,计算机科学中许多现有的理论都是预先排序的堆,因此我们能够为它们推导出一个商,并在文献中包含现有的解决方案。我们引入了筛选堆的概念来处理在多个定义域中给定的结构。我们证明了筛过的堆也有定义良好的商。
Seeking the largest solution to an expression of the form A x <= B is a common task in several domains of engineering and computer science. This largest solution is commonly called quotient. Across domains, the meanings of the binary operation and the preorder are quite different, yet the syntax for computing the largest solution is remarkably similar. This paper is about finding a common framework to reason about quotients. We only assume we operate on a preorder endowed with an abstract monotonic multiplication and an involution. We provide a condition, called admissibility, which guarantees the existence of the quotient, and which yields its closed form. We call preordered heaps those structures satisfying the admissibility condition. We show that many existing theories in computer science are preordered heaps, and we are thus able to derive a quotient for them, subsuming existing solutions when available in the literature. We introduce the concept of sieved heaps to deal with structures which are given over multiple domains of definition. We show that sieved heaps also have well-defined quotients.
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