More Web Proxy on the site http://driver.im/

research-article

Open access

Newtonian Program Analysis via Tensor Product

Authors:

Prathmesh PrabhuAuthors Info & Claims

ACM Transactions on Programming Languages and Systems (TOPLAS), Volume 39, Issue 2

Article No.: 9, Pages 1 - 72

https://doi.org/10.1145/3024084

Published: 21 March 2017 Publication History

Abstract

Recently, Esparza et al. generalized Newton’s method—a numerical-analysis algorithm for finding roots of real-valued functions—to a method for finding fixed-points of systems of equations over semirings. Their method provides a new way to solve interprocedural dataflow-analysis problems. As in its real-valued counterpart, each iteration of their method solves a simpler “linearized” problem.

One of the reasons this advance is exciting is that some numerical analysts have claimed that “‘all’ effective and fast iterative [numerical] methods are forms (perhaps very disguised) of Newton’s method.” However, there is an important difference between the dataflow-analysis and numerical-analysis contexts: When Newton’s method is used in numerical-analysis problems, commutativity of multiplication is relied on to rearrange an expression of the form “a * X * b + c * X * d” into “(a*b + c*d)*X.” Equations with such expressions correspond to path problems described by regular languages. In contrast, when Newton’s method is used for interprocedural dataflow analysis, the “multiplication” operation involves function composition and hence is non-commutative: “a*X*b + c*X*d” cannot be rearranged into “(a*b + c*d)*X.” Equations with such expressions correspond to path problems described by linear context-free languages (LCFLs).

In this article, we present an improved technique for solving the LCFL sub-problems produced during successive rounds of Newton’s method. Our method applies to predicate abstraction, on which most of today’s software model checkers rely.

References

[1]

T. Ball and S. K. Rajamani. 2000. Bebop: A symbolic model checker for Boolean programs. In Spin Workshop.

Digital Library

[2]

A. Bouajjani, J. Esparza, and T. Touili. 2003. A generic approach to the static analysis of concurrent programs with procedures. In POPL.

Digital Library

[3]

R. E. Bryant. 1986. Graph-based algorithms for Boolean function manipulation. IEEE Trans. Comp. C-35, 6 (Aug. 1986), 677--691.

Digital Library

[4]

J. Cocke. 1970. Global common subexpression elimination. Proceedings of the Symposium on Compiler Optimization (1970).

Digital Library

[5]

P. Cousot and R. Cousot. 1978. Static determination of dynamic properties of recursive procedures. In Formal Descriptions of Programming Concepts. North-Holland.

[6]

M. Droste, W. Kuich, and H. Vogler (Eds.). 2009. Handbook of Weighted Automata. Springer-Verlag.

Digital Library

[7]

M. Elder, J. Lim, T. Sharma, T. Andersen, and T. Reps. 2014. Abstract domains of affine relations. Trans. Prog. Lang. Syst. 36, 4 (Jan. 2014).

Digital Library

[8]

J. Esparza, S. Kiefer, and M. Luttenberger. 2008. Newton’s method for omega-continuous semirings. In ICALP.

Digital Library

[9]

J. Esparza, S. Kiefer, and M. Luttenberger. 2010. Newtonian program analysis. J. ACM 57, 6 (2010).

Digital Library

[10]

A. Farzan and Z. Kincaid. 2015. Compositional recurrence analysis. In FMCAD.

Digital Library

[11]

J. P. Gallagher. 2016. Personal communication. (Oct. 2016).

[12]

P. Ganty, R. Iosif, and F. Konečný. 2016. Underapproximation of procedure summaries for integer programs. Softw. Tools for Tech. Transfer (2016). Corrected version available as arXiv:1210.4289v3.

[13]

S. Graf and H. Saïdi. 1997. Construction of abstract state graphs with PVS. In CAV.

Digital Library

[14]

S. L. Graham and M. Wegman. 1976. A fast and usually linear algorithm for data flow analysis. J. ACM 23, 1 (1976), 172--202.

Digital Library

[15]

N. B. B. Grathwohl, D. Kozen, and K. Mamouras. 2014. KAT + B&excl;. In CSL-LICS.

Digital Library

[16]

B. Kafle and J. P. Gallagher. 2015. Horn clause verification with convex polyhedral abstraction and tree automata-based refinement. Computer Languages, Systems 8 Structures (2015).

[17]

B. Kafle, J. P. Gallagher, and P. Ganty. 2016. Solving non-linear Horn clauses using a linear Horn clause solver. In Proceedings of the 3rd Workshop on Horn Clauses for Verification and Synthesis.

[18]

J. B. Kam and J. D. Ullman. 1976. Global data flow analysis and iterative algorithms. J. ACM 23, 1 (1976), 158--171.

Digital Library

[19]

J. B. Kam and J. D. Ullman. 1977. Monotone data flow analysis frameworks. Acta Inf. 7, 3 (1977), 305--318.

Digital Library

[20]

N. Kidd, A. Lal, and T. Reps. 2007. WALi: The Weighted Automaton Library. Retrieved from www.cs.wisc.edu/wpis/wpds/download.php.

[21]

G. A. Kildall. 1973. A unified approach to global program optimization. In POPL.

Digital Library

[22]

Z. Kincaid, J. Breck, A. Forouhi Boroujeni, and T. Reps. 2016. Compositional Recurrence Analysis Revisited. Tech. Rep. TR-1840. Comp. Sci. Dept., Univ. of Wisconsin—Madison.

[23]

J. Knoop and B. Steffen. 1992. The interprocedural coincidence theorem. In CC.

Digital Library

[24]

D. E. Knuth. 1977. A generalization of Dijkstra’s algorithm. Inf. Proc. Let. 6, 1 (1977), 1--5.

[25]

A. Lal, N. Kidd, T. Reps, and T. Touili. 2007. Abstract error projection. In Static Analysis Symp.

Digital Library

[26]

A. Lal and T. Reps. 2006. Improving pushdown system model checking. In CAV.

Digital Library

[27]

A. Lal and T. Reps. 2009. Reducing concurrent analysis under a context bound to sequential analysis. Formal Methods Syst. Des. 35, 1 (2009), 73--97.

Digital Library

[28]

A. Lal, T. Reps, and G. Balakrishnan. 2005. Extended weighted pushdown systems. In CAV.

Digital Library

[29]

A. Lal, T. Touili, N. Kidd, and T. Reps. 2007. Interprocedural Analysis of Concurrent Programs Under a Context Bound. Tech. Rep. TR-1598. Comp. Sci. Dept., University of Wisconsin—Madison.

[30]

A. Lal, T. Touili, N. Kidd, and T. Reps. 2008. Interprocedural analysis of concurrent programs under a context bound. In TACAS.

Digital Library

[31]

G. L. Litvinov, A.Ya. Rodionov, S. N. Sergeev, and A. N. Sobolevski. 2013. Universal algorithms for solving the matrix Bellman equations over semirings. Soft Comput. 17, 10 (2013), 1767--1785.

Digital Library

[32]

R. McNaughton and H. Yamada. 1960. Regular expressions and state graphs for automata. IRE Trans. Elec. Comput. 9 (1960), 39--47.

[33]

U. Möncke and R. Wilhelm. 1991. Grammar flow analysis. In Attribute Grammars, Applications and Systems, (Int. Summer School SAGA). 151--186.

Digital Library

[34]

M. Müller-Olm and H. Seidl. 2004. Precise interprocedural analysis through linear algebra. In POPL.

Digital Library

[35]

M. Müller-Olm and H. Seidl. 2005. Analysis of modular arithmetic. In ESOP.

[36]

G. Ramalingam. 1996. Bounded Incremental Computation. Springer-Verlag.

Digital Library

[37]

T. Reps, S. Horwitz, and M. Sagiv. 1995. Precise interprocedural dataflow analysis via graph reachability. In POPL. 49--61.

Digital Library

[38]

T. Reps, A. Lal, and N. Kidd. 2007. Program analysis using weighted pushdown systems. In FSTTCS.

Digital Library

[39]

T. Reps, S. Schwoon, S. Jha, and D. Melski. 2005. Weighted pushdown systems and their application to interprocedural dataflow analysis. SCP 58, 1--2 (Oct. 2005), 206--263.

Digital Library

[40]

T. Reps, E. Turetsky, and P. Prabhu. 2016. Newtonian program analysis via tensor product. In POPL.

Digital Library

[41]

M. Schlund. 2016. Algebraic Systems of Fixpoint Equations over Semirings: Theory and Applications. Ph.D. Dissertation. Lehrstuhl für Informatik VII, Technischen Universität München, Munich, Germany.

[42]

M. Schlund, M. Terepeta, and M. Luttenberger. 2013. Putting Newton into practice: A solver for polynomial equations over semirings. In LPAR.

[43]

M. Sharir and A. Pnueli. 1981. Two approaches to interprocedural data flow analysis. In Program Flow Analysis: Theory and Applications. Prentice-Hall.

[44]

Static Driver Verifier. 2017. Retrieved from msdn.microsoft.com/en-us/library/windows/hardware/ff552808(v=vs.85).aspx.

[45]

R. A. Tapia. 2008. Inverse, Shifted Inverse, and Rayleigh Quotient Iteration as Newton’s Method. Retrieved from www.frequency.com/video/lecture-series-/18347021.

[46]

R. E. Tarjan. 1981a. Fast algorithms for solving path problems. J. ACM 28, 3 (1981), 594--614.

Digital Library

[47]

R. E. Tarjan. 1981b. A unified approach to path problems. J. ACM 28, 3 (1981), 577--593.

Digital Library

[48]

J. D. Ullman. 1973. Fast algorithms for the elimination of common subexpressions. Acta Inf. 2 (1973), 191--213.

Digital Library

[49]

J. D. Ullman and A. Van Gelder. 1986. Parallel complexity of logical query programs. In Foundations of Computer Science.

Digital Library

[50]

V. Vyssotsky and P. Wegner. 1963. A graph theoretical Fortran source language analyzer. (1963). Unpublished technical report, Bell Labs, Murray-Hill, NJ (as cited in Aho et al., “Compilers: Principles, Techniques, and Tools,” Addison-Wesley, 1986).

Digital Library

[51]

M. Yannakakis. 1990. Graph-theoretic methods in database theory. In PODS.

Digital Library

Cited By

Conrado GGoharshady AKochekov KTsai YZaher A(2023)Exploiting the Sparseness of Control-Flow and Call Graphs for Efficient and On-Demand Algebraic Program AnalysisProceedings of the ACM on Programming Languages10.1145/36228687:OOPSLA2(1993-2022)Online publication date: 16-Oct-2023
https://dl.acm.org/doi/10.1145/3622868
Kincaid ZReps TCyphert J(2021)Algebraic Program AnalysisComputer Aided Verification10.1007/978-3-030-81685-8_3(46-83)Online publication date: 20-Jul-2021
https://dl.acm.org/doi/10.1007/978-3-030-81685-8_3
Breck JCyphert JKincaid ZReps TDonaldson ATorlak E(2020)Templates and recurrences: better togetherProceedings of the 41st ACM SIGPLAN Conference on Programming Language Design and Implementation10.1145/3385412.3386035(688-702)Online publication date: 11-Jun-2020
https://dl.acm.org/doi/10.1145/3385412.3386035
Show More Cited By

Index Terms

Recommendations

Newtonian program analysis via tensor product
POPL '16: Proceedings of the 43rd Annual ACM SIGPLAN-SIGACT Symposium on Principles of Programming Languages

Recently, Esparza et al. generalized Newton's method -- a numerical-analysis algorithm for finding roots of real-valued functions---to a method for finding fixed-points of systems of equations over semirings. Their method provides a new way to solve ...
Newtonian program analysis

This article presents a novel generic technique for solving dataflow equations in interprocedural dataflow analysis. The technique is obtained by generalizing Newton's method for computing a zero of a differentiable function to ω-continuous semirings. ...
Newtonian program analysis via tensor product
POPL '16

Recently, Esparza et al. generalized Newton's method -- a numerical-analysis algorithm for finding roots of real-valued functions---to a method for finding fixed-points of systems of equations over semirings. Their method provides a new way to solve ...

Comments

Please enable JavaScript to view thecomments powered by Disqus.

Information & Contributors

Information

Published In

cover image ACM Transactions on Programming Languages and Systems

ACM Transactions on Programming Languages and Systems Volume 39, Issue 2

June 2017

194 pages

ISSN:0164-0925

EISSN:1558-4593

DOI:10.1145/3062396

Editor:
Andrew Myers
Cornell University, USA

Issue’s Table of Contents

Copyright © 2017 ACM.

Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

Publisher

Association for Computing Machinery

New York, NY, United States

Publication History

Published: 21 March 2017

Accepted: 01 December 2016

Revised: 01 November 2016

Received: 01 February 2016

Published in TOPLAS Volume 39, Issue 2

Permissions

Request permissions for this article.

Request Permissions

Check for updates

Author Tags

Qualifiers

Research-article
Research
Refereed

Funding Sources

ONR
UW—Madison Office of the Vice Chancellor for Research and Graduate Education
AFRL
DARPA CRASH
DARPA MUSE
NSF
ARL
DARPA STAC
Wisconsin Alumni Research Foundation
DARPA

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

5
Total Citations
View Citations
512
Total Downloads

Downloads (Last 12 months)51
Downloads (Last 6 weeks)8

Reflects downloads up to 13 Dec 2024

Other Metrics

View Author Metrics

Citations

Cited By

Conrado GGoharshady AKochekov KTsai YZaher A(2023)Exploiting the Sparseness of Control-Flow and Call Graphs for Efficient and On-Demand Algebraic Program AnalysisProceedings of the ACM on Programming Languages10.1145/36228687:OOPSLA2(1993-2022)Online publication date: 16-Oct-2023
https://dl.acm.org/doi/10.1145/3622868
Kincaid ZReps TCyphert J(2021)Algebraic Program AnalysisComputer Aided Verification10.1007/978-3-030-81685-8_3(46-83)Online publication date: 20-Jul-2021
https://dl.acm.org/doi/10.1007/978-3-030-81685-8_3
Breck JCyphert JKincaid ZReps TDonaldson ATorlak E(2020)Templates and recurrences: better togetherProceedings of the 41st ACM SIGPLAN Conference on Programming Language Design and Implementation10.1145/3385412.3386035(688-702)Online publication date: 11-Jun-2020
https://dl.acm.org/doi/10.1145/3385412.3386035
Kim SVenet AThakur A(2019)Deterministic parallel fixpoint computationProceedings of the ACM on Programming Languages10.1145/33710824:POPL(1-33)Online publication date: 20-Dec-2019
https://dl.acm.org/doi/10.1145/3371082
Reps T(2019)Program Analyses Using Newton’s Method (Invited Paper)Networked Systems10.1007/978-3-030-05529-5_1(3-16)Online publication date: 5-Jan-2019
https://doi.org/10.1007/978-3-030-05529-5_1

View Options

View options

PDF

View or Download as a PDF file.

eReader

View online with eReader.

Login options

Check if you have access through your login credentials or your institution to get full access on this article.

Full Access

Get this Article

Media

Figures

Other

Tables

View Issue’s Table of Contents