Divider verification using symbolic computer algebra and delayed don't care optimization: theory and practical implementation,

Alexander Konrad; Christoph Scholl; Alireza Mahzoon; Daniel Große; Rolf Drechsler

doi:10.1007/s10703-024-00452-3

Divider verification using symbolic computer algebra and delayed don't care optimization: theory and practical implementation,

Alexander Konrad, Christoph Scholl, Alireza Mahzoon, Daniel Große, Rolf Drechsler

Research output: Contribution to journal › Article › peer-review

Abstract

Recent methods based on Symbolic Computer Algebra (SCA) have shown great success in formal verification of multipliers and—more recently—of dividers as well. In this paper we enhance known approaches by the computation of satisfiability don’t cares for so-called Extended Atomic Blocks (EABs) and by Delayed Don’t Care Optimization (DDCO) for optimizing polynomials during backward rewriting. Using those novel methods we are able to extend the applicability of SCA-based methods to further divider architectures which could not be handled by previous approaches. We successfully apply the approach to the fully automatic formal verification of large dividers (with bit widths up to 512).

Original language	English
Number of pages	37
Journal	Formal Methods in System Design: An International Journal
DOIs	https://doi.org/10.1007/s10703-024-00452-3
Publication status	Published - May 2024

Fields of science

202005 Computer architecture
202017 Embedded systems
102 Computer Sciences
102005 Computer aided design (CAD)
102011 Formal languages

JKU Focus areas

Digital Transformation

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10.1007/s10703-024-00452-3

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abstract = "Recent methods based on Symbolic Computer Algebra (SCA) have shown great success in formal verification of multipliers and—more recently—of dividers as well. In this paper we enhance known approaches by the computation of satisfiability don{\textquoteright}t cares for so-called Extended Atomic Blocks (EABs) and by Delayed Don{\textquoteright}t Care Optimization (DDCO) for optimizing polynomials during backward rewriting. Using those novel methods we are able to extend the applicability of SCA-based methods to further divider architectures which could not be handled by previous approaches. We successfully apply the approach to the fully automatic formal verification of large dividers (with bit widths up to 512).",

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AU - Konrad, Alexander

AU - Scholl, Christoph

AU - Mahzoon, Alireza

AU - Große, Daniel

AU - Drechsler, Rolf

PY - 2024/5

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AB - Recent methods based on Symbolic Computer Algebra (SCA) have shown great success in formal verification of multipliers and—more recently—of dividers as well. In this paper we enhance known approaches by the computation of satisfiability don’t cares for so-called Extended Atomic Blocks (EABs) and by Delayed Don’t Care Optimization (DDCO) for optimizing polynomials during backward rewriting. Using those novel methods we are able to extend the applicability of SCA-based methods to further divider architectures which could not be handled by previous approaches. We successfully apply the approach to the fully automatic formal verification of large dividers (with bit widths up to 512).

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JO - Formal Methods in System Design: An International Journal

JF - Formal Methods in System Design: An International Journal

ER -

Divider verification using symbolic computer algebra and delayed don't care optimization: theory and practical implementation,

Abstract

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