Model Checking-Based Genetic Programming with an Application to Mutual Exclusion
Created by W.Langdon from
gp-bibliography.bib Revision:1.8110
- @InProceedings{Katz:2008:TACAS,
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author = "Gal Katz and Doron Peled",
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title = "Model Checking-Based Genetic Programming with an
Application to Mutual Exclusion",
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booktitle = "Tools and Algorithms for the Construction and Analysis
of Systems",
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year = "2008",
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editor = "C. R. Ramakrishnan and Jakob Rehof",
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volume = "4963",
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series = "LNCS",
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pages = "141--156",
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address = "Budapest, Hungary",
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month = mar # " 29-" # apr # " 6",
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publisher = "Springer",
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note = "Held as Part of the Joint European Conferences on
Theory and Practice of Software, ETAPS 2008",
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keywords = "genetic algorithms, genetic programming, STGP, linear
temporal logic",
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isbn13 = "978-3-540-78799-0",
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DOI = "doi:10.1007/978-3-540-78800-3_11",
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size = "16 pages",
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abstract = "Two approaches for achieving correctness of code are
verification and synthesis from specification.
Evidently, it is easier to check a given program for
correctness (although not a trivial task by itself)
than to generate algorithmically
correct-by-construction code. However, formal
verification may give quite limited information about
how to correct the code. Genetic programming repeatedly
generates mutations of code, and then selects the
mutations that remain for the next stage based on a
fitness function, which assists in converging into a
correct program. We use a model checking procedure to
provide the fitness value in every stage. As an
example, we generate algorithms for mutual exclusion,
using this combination of genetic programming and model
checking. The main challenge is to select a fitness
function that will allow constructing correct solutions
with minimal effort. We present our considerations
behind the selection of a fitness function based not
only on the classical outcome of model checking, i.e.,
the existence of an error trace, but on the complete
graph constructed during the model checking process.",
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notes = "Fitness based on graph created by model checking, only
4 fitness levels per ... but then summed to give
combined fitness. Mutation only. Automatic conversion
between Buchi and Streett FSM. Approach is doublly
exponential: p148 {"}The translation may result in a
doubly exponential blowup{"} Deadlock and livelock
detection. Parsimony for bloat control leads to smaller
programs.",
- }
Genetic Programming entries for
Gal Katz
Doron A Peled
Citations