The Z notation: a reference manual
The Z notation: a reference manual
Introduction to HOL: a theorem proving environment for higher order logic
Introduction to HOL: a theorem proving environment for higher order logic
Handbook of logic in computer science (vol. 2)
From LCF to HOL: a short history
Proof, language, and interaction
HOL Light: A Tutorial Introduction
FMCAD '96 Proceedings of the First International Conference on Formal Methods in Computer-Aided Design
A Structure Preserving Encoding of Z in Isabelle/HOL
TPHOLs '96 Proceedings of the 9th International Conference on Theorem Proving in Higher Order Logics
Test-sequence generation with Hol-TestGen with an application to firewall testing
TAP'07 Proceedings of the 1st international conference on Tests and proofs
The Seventeen Provers of the World
TPHOLs '08 Proceedings of the 21st International Conference on Theorem Proving in Higher Order Logics
HOL-Boogie -- An Interactive Prover for the Boogie Program-Verifier
TPHOLs '08 Proceedings of the 21st International Conference on Theorem Proving in Higher Order Logics
Local Theory Specifications in Isabelle/Isar
Types for Proofs and Programs
State Spaces --- The Locale Way
Electronic Notes in Theoretical Computer Science (ENTCS)
HOL-Boogie--An Interactive Prover-Backend for the Verifying C Compiler
Journal of Automated Reasoning
Integrating automated and interactive protocol verification
FAST'09 Proceedings of the 6th international conference on Formal Aspects in Security and Trust
LICS '12 Proceedings of the 2012 27th Annual IEEE/ACM Symposium on Logic in Computer Science
Featherweight OCL: a study for the consistent semantics of OCL 2.3 in HOL
Proceedings of the 12th Workshop on OCL and Textual Modelling
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We present the generic system framework of Isabelle/Isar underlying recent versions of Isabelle. Among other things, Isar provides an infrastructure for Isabelle plug-ins, comprising extensible state components and extensible syntax that can be bound to tactical ML programs. Thus the Isabelle/Isar architecture may be understood as an extension and refinement of the traditional "LCF approach", with explicit infrastructure for building derivative systems. To demonstrate the technical potential of the framework, we apply it to a concrete formal methods tool: the HOL-Z 3.0 environment, which is geared towards the analysis of Z specifications and formal proof of forward-refinements.