English

Whole-grain Petri nets and processes

Logic in Computer Science 2023-01-06 v4 Algebraic Topology Combinatorics Category Theory

Abstract

We present a formalism for Petri nets based on polynomial-style finite-set configurations and etale maps. The formalism supports both a geometric semantics in the style of Goltz and Reisig (processes are etale maps from graphs) and an algebraic semantics in the style of Meseguer and Montanari, in terms of free coloured props, and allows the following unification: for P a Petri net, the Segal space of P-processes is shown to be the free coloured prop-in-groupoids on P. There is also an unfolding semantics \`a la Winskel, which bypasses the classical symmetry problems: with the new formalism, every Petri net admits a universal unfolding, which in turn has associated an event structure and a Scott domain. Since everything is encoded with explicit sets, Petri nets and their processes have elements. In particular, individual-token semantics is native. (Collective-token semantics emerges from rather drastic quotient constructions \`a la Best-Devillers, involving taking {\pi}_0 of the groupoids of states.)

Keywords

Cite

@article{arxiv.2005.05108,
  title  = {Whole-grain Petri nets and processes},
  author = {Joachim Kock},
  journal= {arXiv preprint arXiv:2005.05108},
  year   = {2023}
}

Comments

This is the final 'author version', nearly identical to the version published in JACM. 58 pages. This paper previously had the title 'Elements of Petri nets and processes'

R2 v1 2026-06-23T15:27:26.357Z