TLC: temporal logic of distributed components-Reference-Cited by-同舟云学术

TLC: temporal logic of distributed components

Published:2020-08-02 Issue:ICFP Volume:4 Page:1-30
ISSN:2475-1421
Container-title:Proceedings of the ACM on Programming Languages
language:en
Short-container-title:Proc. ACM Program. Lang.

Author:

Griffin Jeremiah¹,Lesani Mohsen¹,Shadab Narges¹,Yin Xizhe¹

Affiliation:

1. University of California at Riverside, USA

Abstract

Distributed systems are critical to reliable and scalable computing; however, they are complicated in nature and prone to bugs. To manage this complexity, network middleware has been traditionally built in layered stacks of components.We present a novel approach to compositional verification of distributed stacks to verify each component based on only the specification of lower components. We present TLC (Temporal Logic of Components), a novel temporal program logic that offers intuitive inference rules for verification of both safety and liveness properties of functional implementations of distributed components. To support compositional reasoning, we define a novel transformation on the assertion language that lowers the specification of a component to be used as a subcomponent. We prove the soundness of TLC and the lowering transformation with respect to a novel operational semantics for stacks of composed components in partially synchronous networks. We successfully apply TLC to compose and verify a stack of fundamental distributed components.

Publisher

Association for Computing Machinery (ACM)

Subject

Safety, Risk, Reliability and Quality,Software

Link

https://dl.acm.org/doi/pdf/10.1145/3409005

Reference50 articles.

1. A Temporal Logic of Nested Calls and Returns

2. Rajeev Alur and Thomas A Henzinger. 1999. Reactive modules. Formal methods in system design 15 1 ( 1999 ) 7-48. Rajeev Alur and Thomas A Henzinger. 1999. Reactive modules. Formal methods in system design 15 1 ( 1999 ) 7-48.

3. Appendix. 2020. Submitted Supplement Document. Appendix. 2020. Submitted Supplement Document.

4. Verifying distributed programs via canonical sequentialization

5. Edoardo Biagioni Robert Harper and Peter Lee. 2001. A network protocol stack in Standard ML. Higher-Order and Symbolic Computation 14 4 ( 2001 ) 309-356. Edoardo Biagioni Robert Harper and Peter Lee. 2001. A network protocol stack in Standard ML. Higher-Order and Symbolic Computation 14 4 ( 2001 ) 309-356.

Cited by 6 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Adaptive Control and Simulation of Production Processes Using Temporal Neuro-Fuzzy Petri Net;2024 7th International Conference on Information Technologies in Engineering Education (Inforino);2024-04-16

2. Message Chains for Distributed System Verification;Proceedings of the ACM on Programming Languages;2023-10-16

3. Enabling Bounded Verification of Doubly-Unbounded Distributed Agreement-Based Systems via Bounded Regions;Proceedings of the ACM on Programming Languages;2023-04-06

4. Design and Implementation of Information-Analytical and Industrial and Technological Processes in Production Based on Neuro-Fuzzy Petri Nets;2022 VI International Conference on Information Technologies in Engineering Education (Inforino);2022-04-12

5. Modeling of Industrial and Technological Processes in Complex Systems Based on Neuro-Fuzzy Petri Nets;Journal of Physics: Conference Series;2021-11-01