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BRÁZDIL, Tomáš, Krishnendu CHATTERJEE, Antonín KUČERA, Petr NOVOTNÝ, Dominik VELAN a Florian ZULEGER. Efficient Algorithms for Asymptotic Bounds on Termination Time in VASS. Online. In Anuj Dawar, Erich Gradel. 2018 33rd Annual ACM/IEEE Symposium on Logic in Computer Science (LICS). Oxford, England: ACM, 2018. s. 185-194. ISBN 978-1-4503-5583-4. Dostupné z: https://dx.doi.org/10.1145/3209108.3209191. [citováno 2024-04-23]

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Základní údaje
Originální název	Efficient Algorithms for Asymptotic Bounds on Termination Time in VASS
Autoři	BRÁZDIL, Tomáš (203 Česká republika, domácí), Krishnendu CHATTERJEE (356 Indie), Antonín KUČERA (203 Česká republika, domácí), Petr NOVOTNÝ (203 Česká republika), Dominik VELAN (203 Česká republika, garant, domácí) a Florian ZULEGER (40 Rakousko)
Vydání	Oxford, England, 2018 33rd Annual ACM/IEEE Symposium on Logic in Computer Science (LICS), od s. 185-194, 10 s. 2018.
Nakladatel	ACM

Další údaje
Originální jazyk	angličtina
Typ výsledku	Stať ve sborníku
Obor	10200 1.2 Computer and information sciences
Stát vydavatele	Velká Británie a Severní Irsko
Utajení	není předmětem státního či obchodního tajemství
Forma vydání	tištěná verze "print"
WWW	ACM Digital Library
Kód RIV	RIV/00216224:14330/18:00100882
Organizační jednotka	Fakulta informatiky
ISBN	978-1-4503-5583-4
ISSN	1043-6871
Doi	http://dx.doi.org/10.1145/3209108.3209191
UT WoS	000545262800020
Klíčová slova anglicky	vector addition systems with states; termination
Štítky	core_A, firank_1, formela-ver
Příznaky	Mezinárodní význam, Recenzováno
Změnil	Změnil: RNDr. Pavel Šmerk, Ph.D., učo 3880. Změněno: 30. 4. 2019 04:27.

Anotace
Vector Addition Systems with States (VASS) provide a well-known and fundamental model for the analysis of concurrent processes, parametrized systems, and are also used as abstract models of programs in resource bound analysis. In this paper we study the problem of obtaining asymptotic bounds on the termination time of a given VASS. In particular, we focus on the practically important case of obtaining polynomial bounds on termination time. Our main contributions are as follows: First, we present a polynomial-time algorithm for deciding whether a given VASS has a linear asymptotic complexity. We also show that if the complexity of a VASS is not linear, it is at least quadratic. Second, we classify VASS according to quantitative properties of their cycles. We show that certain singularities in these properties are the key reason for non-polynomial asymptotic complexity of VASS. In absence of singularities, we show that the asymptotic complexity is always polynomial and of the form Theta(n^k), for some integer k\leq d, where $d$ is the dimension of the VASS. We present a polynomial-time algorithm computing the optimal $k$. For general VASS, the same algorithm, which is based on a complete technique for the construction of ranking functions in VASS, produces a valid lower bound, i.e. a k such that the termination complexity is Omega(n^k). Our results are based on new insights into the geometry of VASS dynamics, which hold the potential for further applicability to VASS analysis.

Anotace

Vector Addition Systems with States (VASS) provide a well-known and fundamental model for the analysis of concurrent processes, parametrized systems, and are also used as abstract models of programs in resource bound analysis. In this paper we study the problem of obtaining asymptotic bounds on the termination time of a given VASS. In particular, we focus on the practically important case of obtaining polynomial bounds on termination time. Our main contributions are as follows: First, we present a polynomial-time algorithm for deciding whether a given VASS has a linear asymptotic complexity. We also show that if the complexity of a VASS is not linear, it is at least quadratic. Second, we classify VASS according to quantitative properties of their cycles. We show that certain singularities in these properties are the key reason for non-polynomial asymptotic complexity of VASS. In absence of singularities, we show that the asymptotic complexity is always polynomial and of the form Theta(n^k), for some integer k\leq d, where $d$ is the dimension of the VASS. We present a polynomial-time algorithm computing the optimal $k$. For general VASS, the same algorithm, which is based on a complete technique for the construction of ranking functions in VASS, produces a valid lower bound, i.e. a k such that the termination complexity is Omega(n^k). Our results are based on new insights into the geometry of VASS dynamics, which hold the potential for further applicability to VASS analysis.

Anotace česky
V článku je studován problém asymptotického odhadu maximální délky výpočtu daného VASS systému.

Návaznosti
GA18-11193S, projekt VaV	Název: Algoritmy pro diskrétní systémy a hry s nekonečně mnoha stavy
GA18-11193S, projekt VaV	Investor: Grantová agentura ČR, Algoritmy pro diskrétní systémy a hry s nekonečně mnoha stavy
MUNI/A/0854/2017, interní kód MU	Název: Rozsáhlé výpočetní systémy: modely, aplikace a verifikace VII.
MUNI/A/0854/2017, interní kód MU	Investor: Masarykova univerzita, Rozsáhlé výpočetní systémy: modely, aplikace a verifikace VII., DO R. 2020_Kategorie A - Specifický výzkum - Studentské výzkumné projekty
MUNI/A/1038/2017, interní kód MU	Název: Zapojení studentů Fakulty informatiky do mezinárodní vědecké komunity 18
MUNI/A/1038/2017, interní kód MU	Investor: Masarykova univerzita, Zapojení studentů Fakulty informatiky do mezinárodní vědecké komunity 18, DO R. 2020_Kategorie A - Specifický výzkum - Studentské výzkumné projekty