First-order automation for higher-order-logic theorem proving

Theorem proving is an important approach in formal verification. Higher-order logic is a form of predicate logic that is distinguished from first-order logic by additional quantifiers and stronger semantics. Higher-order logic is more expressive. This paper presents the formalization of the linear space theory in HOL4. A set of properties is characterized in HOL4. This result is used to build the underpinnings for the application of higher-order logic in a wider spectrum of engineering applications.

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Extending a brainiac prover to lambda-free higher-order logic

International Journal on Software Tools for Technology Transfer ◽

10.1007/s10009-021-00639-7 ◽

2021 ◽

Author(s):

Petar Vukmirović ◽

Jasmin Blanchette ◽

Simon Cruanes ◽

Stephan Schulz

Keyword(s):

Data Structures ◽

Theorem Proving ◽

State Of The Art ◽

Higher Order ◽

The State ◽

Order Logic ◽

Automatic Theorem Proving ◽

Higher Order Logic ◽

First Order ◽

Automatic Theorem

AbstractDecades of work have gone into developing efficient proof calculi, data structures, algorithms, and heuristics for first-order automatic theorem proving. Higher-order provers lag behind in terms of efficiency. Instead of developing a new higher-order prover from the ground up, we propose to start with the state-of-the-art superposition prover E and gradually enrich it with higher-order features. We explain how to extend the prover’s data structures, algorithms, and heuristics to $$\lambda $$ λ -free higher-order logic, a formalism that supports partial application and applied variables. Our extension outperforms the traditional encoding and appears promising as a stepping stone toward full higher-order logic.

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Making Automatic Theorem Provers more Versatile

10.29007/n6j7 ◽

2018 ◽

Author(s):

Simon Cruanes

Keyword(s):

Higher Order ◽

Order Logic ◽

Higher Order Logic ◽

Research Directions ◽

First Order ◽

Theorem Provers ◽

Smt Solvers ◽

Automatic Theorem Provers ◽

Automatic Theorem

We argue that automatic theorem provers should become more versatile and should be able to tackle problems expressed in richer input formats. Salient research directions include (i) developing tight combinations of SMT solvers and first-order provers; (ii) adding better handling of theories in first-order provers; (iii) adding support for inductive proving; (iv) adding support for user-defined theories and functions; and (v) bringing to the provers some basic abilities to deal with logics beyond first-order, such as higher-order logic.

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Resolution in type theory

Journal of Symbolic Logic ◽

10.2307/2269949 ◽

1971 ◽

Vol 36 (3) ◽

pp. 414-432 ◽

Cited By ~ 107

Author(s):

Peter B. Andrews

Keyword(s):

Set Theory ◽

Type Theory ◽

Higher Order ◽

Order Logic ◽

First Order Logic ◽

Higher Order Logic ◽

First Order ◽

Different Types ◽

Axiomatic Set Theory ◽

Order Predicate Calculus

In [8] J. A. Robinson introduced a complete refutation procedure called resolution for first order predicate calculus. Resolution is based on ideas in Herbrand's Theorem, and provides a very convenient framework in which to search for a proof of a wff believed to be a theorem. Moreover, it has proved possible to formulate many refinements of resolution which are still complete but are more efficient, at least in many contexts. However, when efficiency is a prime consideration, the restriction to first order logic is unfortunate, since many statements of mathematics (and other disciplines) can be expressed more simply and naturally in higher order logic than in first order logic. Also, the fact that in higher order logic (as in many-sorted first order logic) there is an explicit syntactic distinction between expressions which denote different types of intuitive objects is of great value where matching is involved, since one is automatically prevented from trying to make certain inappropriate matches. (One may contrast this with the situation in which mathematical statements are expressed in the symbolism of axiomatic set theory.).

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