Higher-order recursion schemes are an expressive formalism used to define languages of possibly infinite ranked trees. They extend regular and context-free grammars, and are equivalent to simply typed ?Y-calculus and collapsible pushdown automata. In this work we prove, under a syntactical constraint called safety, decidability of the model-checking problem for recursion schemes against properties defined by alternating B-automata, an extension of alternating parity automata for infinite trees with a boundedness acceptance condition. We then exploit this result to show how to compute downward closures of languages of finite trees recognized by safe recursion schemes

Barozzini, David

Clemente, Lorenzo

Colcombet, Thomas

Parys, Pawe?

English

International audienceHigher-order recursion schemes are an expressive formalism used to define languages of possibly infinite ranked trees. They extend regular and context-free grammars, and are equivalent to simply typed λY-calculus and collapsible pushdown automata. In this work we prove, under a syntactical constraint called safety, decidability of the model-checking problem for recursion schemes against properties defined by alternating B-automata, an extension of alternating parity automata for infinite trees with a boundedness acceptance condition. We then exploit this result to show how to compute downward closures of languages of finite trees recognized by safe recursion schemes

Parys, Paweł

HAL Descartes

Cost Automata, Safe Schemes, and Downward Closures

Dagstuhl Research Online Publication Server

https://drops.dagstuhl.de/opus/volltexte/2020/12516/pdf/LIPIcs-ICALP-2020-109.pdf

Cost Automata, Safe Schemes, and Downward Closures

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HAL Descartes

Dagstuhl Research Online Publication Server