169 research outputs found
Alternating and empty alternating auxiliary stack automata
AbstractWe consider variants of alternating auxiliary stack automata and characterize their computational power when the number of alternations is bounded by a constant or unlimited. In this way we get new characterizations of NP, the polynomial hierarchy, PSpace, and bounded query classes like co-DP=NL〈NP[1]〉 and Θ2P=PNP[O(logn)], in a uniform framework
Model checking Branching-Time Properties of Multi-Pushdown Systems is Hard
We address the model checking problem for shared memory concurrent programs
modeled as multi-pushdown systems. We consider here boolean programs with a
finite number of threads and recursive procedures. It is well-known that the
model checking problem is undecidable for this class of programs. In this
paper, we investigate the decidability and the complexity of this problem under
the assumption of bounded context-switching defined by Qadeer and Rehof, and of
phase-boundedness proposed by La Torre et al. On the model checking of such
systems against temporal logics and in particular branching time logics such as
the modal -calculus or CTL has received little attention. It is known that
parity games, which are closely related to the modal -calculus, are
decidable for the class of bounded-phase systems (and hence for bounded-context
switching as well), but with non-elementary complexity (Seth). A natural
question is whether this high complexity is inevitable and what are the ways to
get around it. This paper addresses these questions and unfortunately, and
somewhat surprisingly, it shows that branching model checking for MPDSs is
inherently an hard problem with no easy solution. We show that parity games on
MPDS under phase-bounding restriction is non-elementary. Our main result shows
that model checking a context bounded MPDS against a simple fragment of
CTL, consisting of formulas that whose temporal operators come from the set
{\EF, \EX}, has a non-elementary lower bound
REGULAR LANGUAGES: TO FINITE AUTOMATA AND BEYOND - SUCCINCT DESCRIPTIONS AND OPTIMAL SIMULATIONS
\uc8 noto che i linguaggi regolari \u2014 o di tipo 3 \u2014 sono equivalenti agli automi a stati finiti. Tuttavia, in letteratura sono presenti altre caratterizzazioni di questa classe di linguaggi, in termini di modelli riconoscitori e grammatiche. Per esempio, limitando le risorse computazionali di modelli pi\uf9 generali, quali grammatiche context-free, automi a pila e macchine di Turing, che caratterizzano classi di linguaggi pi\uf9 ampie, \ue8 possibile ottenere modelli che generano o riconoscono solamente i linguaggi regolari. I dispositivi risultanti forniscono delle rappresentazioni alternative dei linguaggi di tipo 3, che, in alcuni casi, risultano significativamente pi\uf9 compatte rispetto a quelle dei modelli che caratterizzano la stessa classe di linguaggi. Il presente lavoro ha l\u2019obiettivo di studiare questi modelli formali dal punto di vista della complessit\ue0 descrizionale, o, in altre parole, di analizzare le relazioni tra le loro dimensioni, ossia il numero di simboli utilizzati per specificare la loro descrizione. Sono presentati, inoltre, alcuni risultati connessi allo studio della famosa domanda tuttora aperta posta da Sakoda e Sipser nel 1978, inerente al costo, in termini di numero di stati, per l\u2019eliminazione del nondeterminismo dagli automi stati finiti sfruttando la capacit\ue0 degli automi two-way deterministici di muovere la testina avanti e indietro sul nastro di input.It is well known that regular \u2014 or type 3 \u2014 languages are equivalent to finite automata. Nevertheless, many other characterizations of this class of languages in terms of computational devices and generative models are present in the literature. For example, by suitably restricting more general models such as context-free grammars, pushdown automata, and Turing machines, that characterize wider classes of languages, it is possible to obtain formal models that generate or recognize regular languages only. The resulting formalisms provide alternative representations of type 3 languages that may be significantly more concise than other models that share the same expressing power. The goal of this work is to investigate these formal systems from a descriptional complexity perspective, or, in other words, to study the relationships between their sizes, namely the number of symbols used to write down their descriptions. We also present some results related to the investigation of the famous question posed by Sakoda and Sipser in 1978, concerning the size blowups from nondeterministic finite automata to two-way deterministic finite automata
On state-alternating context-free grammars
AbstractState-alternating context-free grammars are introduced, and the language classes obtained from them are compared to the classes of the Chomsky hierarchy as well as to some well-known complexity classes. In particular, state-alternating context-free grammars are compared to alternating context-free grammars (Theoret. Comput. Sci. 67 (1989) 75–85) and to alternating pushdown automata. Further, various derivation strategies are considered, and their influence on the expressive power of (state-) alternating context-free grammars is investigated
Deterministic Real-Time Tree-Walking-Storage Automata
We study deterministic tree-walking-storage automata, which are finite-state
devices equipped with a tree-like storage. These automata are generalized stack
automata, where the linear stack storage is replaced by a non-linear tree-like
stack. Therefore, tree-walking-storage automata have the ability to explore the
interior of the tree storage without altering the contents, with the possible
moves of the tree pointer corresponding to those of tree-walking automata. In
addition, a tree-walking-storage automaton can append (push) non-existent
descendants to a tree node and remove (pop) leaves from the tree. Here we are
particularly considering the capacities of deterministic tree-walking-storage
automata working in real time. It is shown that even the non-erasing variant
can accept rather complicated unary languages as, for example, the language of
words whose lengths are powers of two, or the language of words whose lengths
are Fibonacci numbers. Comparing the computational capacities with automata
from the classical automata hierarchy, we derive that the families of languages
accepted by real-time deterministic (non-erasing) tree-walking-storage automata
is located between the regular and the deterministic context-sensitive
languages. There is a context-free language that is not accepted by any
real-time deterministic tree-walking-storage automaton. On the other hand,
these devices accept a unary language in non-erasing mode that cannot be
accepted by any classical stack automaton, even in erasing mode and arbitrary
time. Basic closure properties of the induced families of languages are shown.
In particular, we consider Boolean operations (complementation, union,
intersection) and AFL operations (union, intersection with regular languages,
homomorphism, inverse homomorphism, concatenation, iteration). It turns out
that the two families in question have the same properties and, in particular,
share all but one of these closure properties with the important family of
deterministic context-free languages.Comment: In Proceedings NCMA 2023, arXiv:2309.0733
Foundations of Software Science and Computation Structures
This open access book constitutes the proceedings of the 25th International Conference on Foundations of Software Science and Computational Structures, FOSSACS 2022, which was held during April 4-6, 2022, in Munich, Germany, as part of the European Joint Conferences on Theory and Practice of Software, ETAPS 2022. The 23 regular papers presented in this volume were carefully reviewed and selected from 77 submissions. They deal with research on theories and methods to support the analysis, integration, synthesis, transformation, and verification of programs and software systems
Foundations of Software Science and Computation Structures
This open access book constitutes the proceedings of the 25th International Conference on Foundations of Software Science and Computational Structures, FOSSACS 2022, which was held during April 4-6, 2022, in Munich, Germany, as part of the European Joint Conferences on Theory and Practice of Software, ETAPS 2022. The 23 regular papers presented in this volume were carefully reviewed and selected from 77 submissions. They deal with research on theories and methods to support the analysis, integration, synthesis, transformation, and verification of programs and software systems
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