research-article

Expressing and verifying probabilistic assertions

Authors:

Adrian Sampson,

Pavel Panchekha,

Todd Mytkowicz,

Kathryn S. McKinley,

Luis CezeAuthors Info & Claims

PLDI '14: Proceedings of the 35th ACM SIGPLAN Conference on Programming Language Design and Implementation

Pages 112 - 122

https://doi.org/10.1145/2594291.2594294

Published: 09 June 2014 Publication History

Abstract

Traditional assertions express correctness properties that must hold on every program execution. However, many applications have probabilistic outcomes and consequently their correctness properties are also probabilistic (e.g., they identify faces in images, consume sensor data, or run on unreliable hardware). Traditional assertions do not capture these correctness properties. This paper proposes that programmers express probabilistic correctness properties with probabilistic assertions and describes a new probabilistic evaluation approach to efficiently verify these assertions. Probabilistic assertions are Boolean expressions that express the probability that a property will be true in a given execution rather than asserting that the property must always be true. Given either specific inputs or distributions on the input space, probabilistic evaluation verifies probabilistic assertions by first performing distribution extraction to represent the program as a Bayesian network. Probabilistic evaluation then uses statistical properties to simplify this representation to efficiently compute assertion probabilities directly or with sampling. Our approach is a mix of both static and dynamic analysis: distribution extraction statically builds and optimizes the Bayesian network representation and sampling dynamically interprets this representation. We implement our approach in a tool called Mayhap for C and C++ programs. We evaluate expressiveness, correctness, and performance of Mayhap on programs that use sensors, perform approximate computation, and obfuscate data for privacy. Our case studies demonstrate that probabilistic assertions describe useful correctness properties and that Mayhap efficiently verifies them.

Supplementary Material

ZIP File (p112-sampson-aux.zip)

This file, `passert-aux.pdf`, is a PDF of the addendum to our PLDI 2014 paper, "Expressing and Verifying Probabilistic Assertions," containing the full semantics for the ProbCore language and a proof of the associated theorem.

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Cited By

Böck MSchröder MCito JFilkov VRay BZhou M(2024)Language-Agnostic Static Analysis of Probabilistic ProgramsProceedings of the 39th IEEE/ACM International Conference on Automated Software Engineering10.1145/3691620.3695031(78-90)Online publication date: 27-Oct-2024
https://dl.acm.org/doi/10.1145/3691620.3695031
Raza MJaved SKazmi MAziz AUl Haque MQazi S(2023)Approximate Computing: Hardware and Software Techniques, Tools and Their ApplicationsJournal of Circuits, Systems and Computers10.1142/S021812662430001033:04Online publication date: 20-Sep-2023
https://doi.org/10.1142/S0218126624300010
Voogd EJohnsen ESilva ASusag ZWąsowski A(2023)Symbolic Semantics for Probabilistic ProgramsQuantitative Evaluation of Systems10.1007/978-3-031-43835-6_23(329-345)Online publication date: 15-Sep-2023
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Index Terms

Expressing and verifying probabilistic assertions

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Published In

cover image ACM Conferences

PLDI '14: Proceedings of the 35th ACM SIGPLAN Conference on Programming Language Design and Implementation

June 2014

619 pages

ISBN:9781450327848

DOI:10.1145/2594291

General Chair:
Michael O'Boyle
University of Edinburgh
,
Program Chair:
Keshav Pingali
University of Texas, Austin

ACM SIGPLAN Notices Volume 49, Issue 6
PLDI '14
June 2014
598 pages
ISSN:0362-1340
EISSN:1558-1160
DOI:10.1145/2666356
Editor:
Andy Gill
University of Kansas, Lawrence, KS
Issue’s Table of Contents

Copyright © 2014 ACM.

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Published: 09 June 2014

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PLDI '14: ACM SIGPLAN Conference on Programming Language Design and Implementation

June 9 - 11, 2014

Edinburgh, United Kingdom

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PLDI '14 Paper Acceptance Rate 52 of 287 submissions, 18%;

Overall Acceptance Rate 406 of 2,067 submissions, 20%

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Cited By

Böck MSchröder MCito JFilkov VRay BZhou M(2024)Language-Agnostic Static Analysis of Probabilistic ProgramsProceedings of the 39th IEEE/ACM International Conference on Automated Software Engineering10.1145/3691620.3695031(78-90)Online publication date: 27-Oct-2024
https://dl.acm.org/doi/10.1145/3691620.3695031
Raza MJaved SKazmi MAziz AUl Haque MQazi S(2023)Approximate Computing: Hardware and Software Techniques, Tools and Their ApplicationsJournal of Circuits, Systems and Computers10.1142/S021812662430001033:04Online publication date: 20-Sep-2023
https://doi.org/10.1142/S0218126624300010
Voogd EJohnsen ESilva ASusag ZWąsowski A(2023)Symbolic Semantics for Probabilistic ProgramsQuantitative Evaluation of Systems10.1007/978-3-031-43835-6_23(329-345)Online publication date: 15-Sep-2023
https://doi.org/10.1007/978-3-031-43835-6_23
Susag ZLahiri SHsu JRoy S(2022)Symbolic execution for randomized programsProceedings of the ACM on Programming Languages10.1145/35633446:OOPSLA2(1583-1612)Online publication date: 31-Oct-2022
https://dl.acm.org/doi/10.1145/3563344
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Jiang HZhang HTang XGovindaraj VSampson JKandemir MZhang DFreund SYahav E(2021)Fluid: a framework for approximate concurrency via controlled dependency relaxationProceedings of the 42nd ACM SIGPLAN International Conference on Programming Language Design and Implementation10.1145/3453483.3454042(252-267)Online publication date: 19-Jun-2021
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Fernando VJoshi KLaurel JMisailovic S(2021)Diamont: Dynamic Monitoring of Uncertainty for Distributed Asynchronous ProgramsRuntime Verification10.1007/978-3-030-88494-9_10(184-206)Online publication date: 6-Oct-2021
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Mangal RSarangmath KNori AOrso A(2021)Probabilistic Lipschitz Analysis of Neural NetworksStatic Analysis10.1007/978-3-030-65474-0_13(274-309)Online publication date: 13-Jan-2021
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Guillén IMarco JGutierrez DJakob WJarabo A(2020)A general framework for pearlescent materialsACM Transactions on Graphics10.1145/3414685.341778239:6(1-15)Online publication date: 27-Nov-2020
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