A Small-Step Operational Semantics for GP 2
Abstract
The operational semantics of a programming language is said to be small-step if each transition step is an atomic computation step in the language. A semantics with this property faithfully corresponds to the implementation of the language. The previous semantics of the graph programming language GP 2 is not fully small-step because the loop and branching commands are defined in big-step style. In this paper, we present a truly small-step operational semantics for GP 2 which, in particular, accurately models diverging computations. To obtain small-step definitions of all commands, we equip the transition relation with a stack of host graphs and associated operations. We prove that the new semantics is non-blocking in that every computation either diverges or eventually produces a result graph or the failure state. We also show the finite nondeterminism property, viz. that each configuration has only a finite number of direct successors. The previous semantics of GP 2 is neither non-blocking nor does it have the finite nondeterminism property. We also show that, for a program and a graph that terminate, both semantics are equivalent, and that the old semantics can be simulated with the new one.
Keywords
Cite
@article{arxiv.2112.11077,
title = {A Small-Step Operational Semantics for GP 2},
author = {Brian Courtehoute and Detlef Plump},
journal= {arXiv preprint arXiv:2112.11077},
year = {2021}
}
Comments
In Proceedings GCM 2021, arXiv:2112.10217