Verification Runtime Analysis: Get the Most Out of Partial Verification

Martin Ring; Fritjof Bornebusch; Christoph Lüth; Robert Wille; Rolf Drechsler

Verification Runtime Analysis: Get the Most Out of Partial Verification

Martin Ring
, Fritjof Bornebusch
, Christoph Lüth
, Robert Wille
, Rolf Drechsler

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

The design of modern systems has reached a complexity which makes it inevitable to apply verification methods in order to guarantee its correct and safe execution. The verification methods frequently produce proof obligations that can not be solved anymore due to the huge search space. However, by setting enough variables to fixed values, the search space is obviously reduced and solving engines eventually may be able to complete the verification task. Although this results in a partial verification, the results may still be valuable - in particular as opposed to the alternative of no verification at all. However, so far no systematic investigation has been conducted on which variables to fix in order to reduce verification runtime as much as possible while, at the same time, still getting most coverage. This paper addresses this question by proposing a corresponding verification runtime analysis. Experimental evaluations confirm the potential of this approach.

Original language	English
Title of host publication	Design, Automation and Test in Europe (DATE)
Number of pages	6
Publication status	Published - 2020

Fields of science

102 Computer Sciences
202 Electrical Engineering, Electronics, Information Engineering

JKU Focus areas

Digital Transformation

Cite this

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title = "Verification Runtime Analysis: Get the Most Out of Partial Verification",

abstract = "The design of modern systems has reached a complexity which makes it inevitable to apply verification methods in order to guarantee its correct and safe execution. The verification methods frequently produce proof obligations that can not be solved anymore due to the huge search space. However, by setting enough variables to fixed values, the search space is obviously reduced and solving engines eventually may be able to complete the verification task. Although this results in a partial verification, the results may still be valuable - in particular as opposed to the alternative of no verification at all. However, so far no systematic investigation has been conducted on which variables to fix in order to reduce verification runtime as much as possible while, at the same time, still getting most coverage. This paper addresses this question by proposing a corresponding verification runtime analysis. Experimental evaluations confirm the potential of this approach.",

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AU - Bornebusch, Fritjof

AU - Lüth, Christoph

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AU - Drechsler, Rolf

PY - 2020

Y1 - 2020

N2 - The design of modern systems has reached a complexity which makes it inevitable to apply verification methods in order to guarantee its correct and safe execution. The verification methods frequently produce proof obligations that can not be solved anymore due to the huge search space. However, by setting enough variables to fixed values, the search space is obviously reduced and solving engines eventually may be able to complete the verification task. Although this results in a partial verification, the results may still be valuable - in particular as opposed to the alternative of no verification at all. However, so far no systematic investigation has been conducted on which variables to fix in order to reduce verification runtime as much as possible while, at the same time, still getting most coverage. This paper addresses this question by proposing a corresponding verification runtime analysis. Experimental evaluations confirm the potential of this approach.

AB - The design of modern systems has reached a complexity which makes it inevitable to apply verification methods in order to guarantee its correct and safe execution. The verification methods frequently produce proof obligations that can not be solved anymore due to the huge search space. However, by setting enough variables to fixed values, the search space is obviously reduced and solving engines eventually may be able to complete the verification task. Although this results in a partial verification, the results may still be valuable - in particular as opposed to the alternative of no verification at all. However, so far no systematic investigation has been conducted on which variables to fix in order to reduce verification runtime as much as possible while, at the same time, still getting most coverage. This paper addresses this question by proposing a corresponding verification runtime analysis. Experimental evaluations confirm the potential of this approach.

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BT - Design, Automation and Test in Europe (DATE)

ER -