Aspect-oriented linearizability proofs

Soham Chakraborty; Thomas A. Henzinger; Ali Sezgin; Viktor Vafeiadis

doi:10.2168/LMCS-11(1:20)2015

Soham Chakraborty ; Thomas A. Henzinger ; Ali Sezgin ; Viktor Vafeiadis - Aspect-oriented linearizability proofs

lmcs:1051 - Logical Methods in Computer Science, April 1, 2015, Volume 11, Issue 1 - https://doi.org/10.2168/LMCS-11(1:20)2015

Aspect-oriented linearizability proofsArticle

Authors: Soham Chakraborty ; Thomas A. Henzinger ; Ali Sezgin ; Viktor Vafeiadis

Linearizability of concurrent data structures is usually proved by monolithic simulation arguments relying on the identification of the so-called linearization points. Regrettably, such proofs, whether manual or automatic, are often complicated and scale poorly to advanced non-blocking concurrency patterns, such as helping and optimistic updates. In response, we propose a more modular way of checking linearizability of concurrent queue algorithms that does not involve identifying linearization points. We reduce the task of proving linearizability with respect to the queue specification to establishing four basic properties, each of which can be proved independently by simpler arguments. As a demonstration of our approach, we verify the Herlihy and Wing queue, an algorithm that is challenging to verify by a simulation proof.

https://doi.org/10.2168/LMCS-11(1:20)2015

Source: arXiv.org:1502.07639

Volume: Volume 11, Issue 1

Published on: April 1, 2015

Imported on: February 28, 2014

Keywords: Computer Science - Logic in Computer Science,Computer Science - Programming Languages

Licence: arXiv.org - Non-exclusive license to distribute

Funding:

Source : OpenAIRE Graph

Semantic Foundations for Real-World Systems; Funder: UK Research and Innovation; Code: EP/H005633/1
Quantitative Reactive Modeling; Funder: European Commission; Code: 267989

Bibliographic References

13 Documents citing this article

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