A verified theorem prover backend supported by a monotonic library

Vincent Rahli; Liron Cohen; Mark Bickford

doi:10.29007/f58n

A verified theorem prover backend supported by a monotonic library

Vincent Rahli, Liron Cohen, Mark Bickford

Computer Science

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

2 Citations (Scopus)

137 Downloads (Pure)

Abstract

Building a verified proof assistant entails implementing and mechanizing the concept of a library, as well as adding support for standard manipulations on it. In this work we develop such mechanism for the Nuprl proof assistant, and integrate it into the formalization of Nuprl’s meta-theory in Coq. We formally verify that standard operations on the library preserve its validity. This is a key property for any interactive theorem prover, since it ensures consistency. Some unique features of Nuprl, such as the presence of undefined abstractions, make the proof of this property nontrivial. Thus, e.g., to achieve monotonicity the semantics of sequents had to be refined. On a broader view, this work provides a backend for a verified version of Nuprl. We use it, in turn, to develop a tool that converts proofs exported from the Nuprl proof assistant into proofs in the Coq formalization of Nuprl’s meta-theory, so as to be verified.

Original language	English
Title of host publication	LPAR-22. 22nd International Conference on Logic for Programming, Artificial Intelligence and Reasoning
Editors	Gilles Barthe, Geoff Sutcliffe, Margus Veanes
Publisher	EasyChair Publications
Pages	564-582
Number of pages	19
DOIs	https://doi.org/10.29007/f58n
Publication status	Published - 23 Oct 2018
Event	LPAR-22. 22nd International Conference on Logic for Programming, Artificial Intelligence and Reasoning - Awassa, Ethiopia Duration: 17 Nov 2018 → 21 Nov 2018

Publication series

Name	EPiC Series in Computing
Publisher	EasyChair Publications
Volume	57
ISSN (Electronic)	2398-7340

Conference

Conference	LPAR-22. 22nd International Conference on Logic for Programming, Artificial Intelligence and Reasoning
Country/Territory	Ethiopia
City	Awassa
Period	17/11/18 → 21/11/18

Keywords

Coq
Digital Library
Kripke semantics
monotonicity
Nuprl
proof checker
Verified theorem prover backend

Access to Document

10.29007/f58nLicence: None: All rights reserved

Vincent_Rahli_et_al_A_verified_theorem_prover_backend_supported_by_a_monotonic_library_LPAR-22_2018
Checked for eligibility: 22/07/2019
Accepted author manuscript, 688 KBLicence: None: All rights reserved

Cite this

@inproceedings{551c70cba21242c0836d5b6ea6337271,

title = "A verified theorem prover backend supported by a monotonic library",

abstract = "Building a verified proof assistant entails implementing and mechanizing the concept of a library, as well as adding support for standard manipulations on it. In this work we develop such mechanism for the Nuprl proof assistant, and integrate it into the formalization of Nuprl{\textquoteright}s meta-theory in Coq. We formally verify that standard operations on the library preserve its validity. This is a key property for any interactive theorem prover, since it ensures consistency. Some unique features of Nuprl, such as the presence of undefined abstractions, make the proof of this property nontrivial. Thus, e.g., to achieve monotonicity the semantics of sequents had to be refined. On a broader view, this work provides a backend for a verified version of Nuprl. We use it, in turn, to develop a tool that converts proofs exported from the Nuprl proof assistant into proofs in the Coq formalization of Nuprl{\textquoteright}s meta-theory, so as to be verified.",

keywords = "Coq, Digital Library, Kripke semantics, monotonicity, Nuprl, proof checker, Verified theorem prover backend",

author = "Vincent Rahli and Liron Cohen and Mark Bickford",

year = "2018",

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doi = "10.29007/f58n",

language = "English",

series = "EPiC Series in Computing",

publisher = "EasyChair Publications",

pages = "564--582",

editor = "Gilles Barthe and Geoff Sutcliffe and Margus Veanes",

booktitle = "LPAR-22. 22nd International Conference on Logic for Programming, Artificial Intelligence and Reasoning",

note = "LPAR-22. 22nd International Conference on Logic for Programming, Artificial Intelligence and Reasoning ; Conference date: 17-11-2018 Through 21-11-2018",

}

Rahli, V, Cohen, L & Bickford, M 2018, A verified theorem prover backend supported by a monotonic library. in G Barthe, G Sutcliffe & M Veanes (eds), LPAR-22. 22nd International Conference on Logic for Programming, Artificial Intelligence and Reasoning. EPiC Series in Computing, vol. 57, EasyChair Publications, pp. 564-582, LPAR-22. 22nd International Conference on Logic for Programming, Artificial Intelligence and Reasoning, Awassa, Ethiopia, 17/11/18. https://doi.org/10.29007/f58n

A verified theorem prover backend supported by a monotonic library. / Rahli, Vincent; Cohen, Liron; Bickford, Mark.
LPAR-22. 22nd International Conference on Logic for Programming, Artificial Intelligence and Reasoning. ed. / Gilles Barthe; Geoff Sutcliffe; Margus Veanes. EasyChair Publications, 2018. p. 564-582 (EPiC Series in Computing; Vol. 57).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

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N2 - Building a verified proof assistant entails implementing and mechanizing the concept of a library, as well as adding support for standard manipulations on it. In this work we develop such mechanism for the Nuprl proof assistant, and integrate it into the formalization of Nuprl’s meta-theory in Coq. We formally verify that standard operations on the library preserve its validity. This is a key property for any interactive theorem prover, since it ensures consistency. Some unique features of Nuprl, such as the presence of undefined abstractions, make the proof of this property nontrivial. Thus, e.g., to achieve monotonicity the semantics of sequents had to be refined. On a broader view, this work provides a backend for a verified version of Nuprl. We use it, in turn, to develop a tool that converts proofs exported from the Nuprl proof assistant into proofs in the Coq formalization of Nuprl’s meta-theory, so as to be verified.

AB - Building a verified proof assistant entails implementing and mechanizing the concept of a library, as well as adding support for standard manipulations on it. In this work we develop such mechanism for the Nuprl proof assistant, and integrate it into the formalization of Nuprl’s meta-theory in Coq. We formally verify that standard operations on the library preserve its validity. This is a key property for any interactive theorem prover, since it ensures consistency. Some unique features of Nuprl, such as the presence of undefined abstractions, make the proof of this property nontrivial. Thus, e.g., to achieve monotonicity the semantics of sequents had to be refined. On a broader view, this work provides a backend for a verified version of Nuprl. We use it, in turn, to develop a tool that converts proofs exported from the Nuprl proof assistant into proofs in the Coq formalization of Nuprl’s meta-theory, so as to be verified.

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A verified theorem prover backend supported by a monotonic library

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Keywords

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