Tomáš Peitl scite author profile

Tomáš Peitl

5Publications

58Citation Statements Received

65Citation Statements Given

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TU Wien, Friedrich Schiller University Jena

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Dependency Learning for QBF

Peitl¹,

Slivovsky²,

Szeider³

2019

jair

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Quantified Boolean Formulas (QBFs) can be used to succinctly encode problems from domains such as formal verification, planning, and synthesis. One of the main approaches to QBF solving is Quantified Conflict Driven Clause Learning (QCDCL). By default, QCDCL assigns variables in the order of their appearance in the quantifier prefix so as to account for dependencies among variables. Dependency schemes can be used to relax this restriction and exploit independence among variables in certain cases, but only at the cost of nontrivial interferences with the proof system underlying QCDCL. We introduce dependency learning, a new technique for exploiting variable independence within QCDCL that allows solvers to learn variable dependencies on the fly. The resulting version of QCDCL enjoys improved propagation and increased flexibility in choosing variables for branching while retaining ordinary (long-distance) Q-resolution as its underlying proof system. We show that dependency learning can achieve exponential speedups over ordinary QCDCL. Experiments on standard benchmark sets demonstrate the effectiveness of this technique.

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Dependency Learning for QBF

Peitl

Slivovsky

Szeider

2017

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Quantified Boolean Formulas (QBFs) can be used to succinctly encode problems from domains such as formal verification, planning, and synthesis. One of the main approaches to QBF solving is Quantified Conflict Driven Clause Learning (QCDCL). By default, QCDCL assigns variables in the order of their appearance in the quantifier prefix so as to account for dependencies among variables. Dependency schemes can be used to relax this restriction and exploit independence among variables in certain cases, but only at the cost of nontrivial interferences with the proof system underlying QCDCL. We propose a new technique for exploiting variable independence within QCDCL that allows solvers to learn variable dependencies on the fly. The resulting version of QCDCL enjoys improved propagation and increased flexibility in choosing variables for branching while retaining ordinary (long-distance) Q-resolution as its underlying proof system. In experiments on standard benchmark sets, an implementation of this algorithm shows performance comparable to state-of-the-art QBF solvers.

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Portfolio-Based Algorithm Selection for Circuit QBFs

Hoos

Peitl

Slivovsky

et al. 2018

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Hard QBFs for Merge Resolution

Beyersdorff

Blinkhorn

Mahajan

et al. 2020

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Proof Complexity of Fragments of Long-Distance Q-Resolution

Peitl

Slivovsky

Szeider

2019

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Tomáš Peitl

Dependency Learning for QBF

Dependency Learning for QBF

Portfolio-Based Algorithm Selection for Circuit QBFs

Hard QBFs for Merge Resolution

Proof Complexity of Fragments of Long-Distance Q-Resolution

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