Unboundedness problems for machines with reversal-bounded counters (2301.10198v1)

Abstract: We consider a general class of decision problems concerning formal languages, called ``(one-dimensional) unboundedness predicates'', for automata that feature reversal-bounded counters (RBCA). We show that each problem in this class reduces -- non-deterministically in polynomial time -- to the same problem for just finite automata. We also show an analogous reduction for automata that have access to both a pushdown stack and reversal-bounded counters (PRBCA). This allows us to answer several open questions: For example, we show that it is coNP-complete to decide whether a given (P)RBCA language $L$ is bounded, meaning whether there exist words $w_1,\ldots,w_n$ with $L\subseteq w_1^*\cdots w_n^*$. For PRBCA, even decidability was open. Our methods also show that there is no language of a (P)RBCA of intermediate growth. This means, the number of words of each length grows either polynomially or exponentially. Part of our proof is likely of independent interest: We show that one can translate an RBCA into a machine with $\mathbb{Z}$-counters in logarithmic space, while preserving the accepted language.