The Polynomial Complexity of Vector Addition Systems with States

Zuleger, Florian

doi:10.1007/978-3-030-45231-5_32

Cited by 5 publications

(4 citation statements)

References 21 publications

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“…We also mention the quest for abstract program models whose resource bound analysis problem is decidable, and for which the obtainable resource bounds can be precisely characterised. We list here the size-change abstraction, whose worst-case complexity has been completely characterised as polynomial (with rational coefficients) (Colcombet et al, 2014;Zuleger, 2015), vector-addition systems (Brázdil et al, 2018;Zuleger, 2020), for which polynomial complexity can be decided, and LOOP programs (Ben-Amram and Hamilton, 2019), for which multivariate polynomial bounds can be computed. We are not aware of similar results for program models that induce logarithmic bounds.…”

Section: Related Workmentioning

confidence: 99%

Type-based analysis of logarithmic amortised complexity

Hofmann

Leutgeb

Obwaller

et al. 2021

Math. Struct. Comp. Sci.

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We introduce a novel amortised resource analysis couched in a type-and-effect system. Our analysis is formulated in terms of the physicist’s method of amortised analysis and is potentialbased. The type system makes use of logarithmic potential functions and is the first such system to exhibit logarithmic amortised complexity. With our approach, we target the automated analysis of self-adjusting data structures, like splay trees, which so far have only manually been analysed in the literature. In particular, we have implemented a semi-automated prototype, which successfully analyses the zig-zig case of splaying, once the type annotations are fixed.

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Section: Related Workmentioning

confidence: 99%

Type-based analysis of logarithmic amortised complexity

Hofmann

Leutgeb

Obwaller

et al. 2021

Math. Struct. Comp. Sci.

Self Cite

View full text Add to dashboard Cite

show abstract

“…We also mention the quest for abstract program models whose resource bound analysis problem is decidable, and for which the obtainable resource bounds can be precisely characterised. We list here the size-change abstraction, whose worst-case complexity has been completely characterised as polynomial (with rational coefficients) [14,56], vector-addition systems [12,57], for which polynomial complexity can be decided, and LOOP programs [10], for which multivariate polynomial bounds can be computed. We are not aware of similar results for programs models that induce logarithmic bounds.…”

Section: Related Workmentioning

confidence: 99%

Type-Based Analysis of Logarithmic Amortised Complexity

Hofmann¹,

Leutgeb²,

Moser³

et al. 2021

Preprint

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We introduce a novel amortised resource analysis couched in a type-and-effect system. Our analysis is formulated in terms of the physicist's method of amortised analysis, and is potential-based. The type system makes use of logarithmic potential functions and is the first such system to exhibit logarithmic amortised complexity. With our approach we target the automated analysis of self-adjusting data structures, like splay trees, which so far have only manually been analysed in the literature. In particular, we have implemented a semi-automated prototype, which successfully analyses the zig-zig case of splaying, once the type annotations are fixed.

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“…□ A natural question is whether Theorem 4.2 can be extended to other complexity classes such as O (𝑛 𝑘 ). Recall that the problem whether L A ∈ O (𝑛 𝑘 ) for a given demonic VASS A is decidable in polynomial time, and ifL A ∉ O (𝑛 𝑘 ), then L A ∈ Ω(𝑛 𝑘+1 )[20]. However, our proof of Theorem 4.2 requires G 𝑘 being closed under function composition, which does not hold for O (𝑛 𝑘 ) and 𝑘 ≥ 2.…”

mentioning

confidence: 97%

“…In the same paper, it is also shown that if L is not polynomial, then it is at least exponential, i.e., L ∈ 2 Ω (𝑛) . A recent result of [20] shows that if the termination complexity of a given demonic VASS is polynomial, then there is 𝑘 ∈ N computable in polynomial time such that L is Θ(𝑛 𝑘 ). A polynomial-time algorithm deciding the linearity of L for probabilistic VASS , i.e., VASS with demonic non-determinism and probabilistic choice 2 , is given in [2].…”

mentioning

confidence: 99%

Efficient Analysis of VASS Termination Complexity

Kučera

Leroux

Velan

2020

Proceedings of the 35th Annual ACM/IEEE Symposium on Logic in Computer Science

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The termination complexity of a given VASS is a function L assigning to every 𝑛 the length of the longest nonterminating computation initiated in a configuration with all counters bounded by 𝑛. We show that for every VASS with demonic nondeterminism and every fixed 𝑘, the problem whether L ∈ G 𝑘 , where G 𝑘 is the 𝑘-th level in the Grzegorczyk hierarchy, is decidable in polynomial time. Furthermore, we show that if L ∉ G 𝑘 , then L grows at least as fast as the generator 𝐹 𝑘+1 of G 𝑘+1 . Hence, for every terminating VASS, the growth of L can be reasonably characterized by the leastFurthermore, we consider VASS with both angelic and demonic nondeterminism, i.e., VASS games where the players aim at lowering/raising the termination time. We prove that for every fixed 𝑘, the problem whether L ∈ G 𝑘 for a given VASS game is NP-complete. Furthermore, if L ∉ G 𝑘 , then L grows at least as fast as 𝐹 𝑘+1 .CCS Concepts: • Theory of computation → Abstract machines.

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The Polynomial Complexity of Vector Addition Systems with States

Cited by 5 publications

References 21 publications

Type-based analysis of logarithmic amortised complexity

Type-based analysis of logarithmic amortised complexity

Type-Based Analysis of Logarithmic Amortised Complexity

Efficient Analysis of VASS Termination Complexity

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