cclib 2.0: An updated architecture for interoperable computational chemistry

Eric Berquist; Amanda Dumi; Shiv Upadhyay; Omri D Abarbanel; Minsik Cho; Sagar Gaur; Victor Hugo Gano Gil; Geoffrey R Hutchison; Oliver S Lee; Andrew S Rosen; Sanjeed Schamnad; Felipe S S Schneider; Casper Steinmann; Maxim Stolyarchuk; Jonathon E Vandezande; Weronika Zak; Karol M Langner

doi:10.1063/5.0216778

cclib 2.0: An updated architecture for interoperable computational chemistry

Eric Berquist, Amanda Dumi, Shiv Upadhyay, Omri D Abarbanel, Minsik Cho, Sagar Gaur, Victor Hugo Gano Gil, Geoffrey R Hutchison, Oliver S Lee, Andrew S Rosen, Sanjeed Schamnad, Felipe S S Schneider, Casper Steinmann, Maxim Stolyarchuk, Jonathon E Vandezande, Weronika Zak, Karol M Langner^*

^*Kontaktforfatter

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

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Abstract

Interoperability in computational chemistry is elusive, impeded by the independent development of software packages and idiosyncratic nature of their output files. The cclib library was introduced in 2006 as an attempt to improve this situation by providing a consistent interface to the results of various quantum chemistry programs. The shared API across programs enabled by cclib has allowed users to focus on results as opposed to output and to combine data from multiple programs or develop generic downstream tools. Initial development, however, did not anticipate the rapid progress of computational capabilities, novel methods, and new programs; nor did it foresee the growing need for customizability. Here, we recount this history and present cclib 2, focused on extensibility and modularity. We also introduce recent design pivots—the formalization of cclib’s intermediate data representation as a tree-based structure, a new combinator-based parser organization, and parsed chemical properties as extensible objects.

Originalsprog	Engelsk
Artikelnummer	042501
Tidsskrift	Journal of Chemical Physics
Vol/bind	161
Udgave nummer	4
Antal sider	12
ISSN	0021-9606
DOI	https://doi.org/10.1063/5.0216778
Status	Udgivet - 28 jul. 2024

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10.1063/5.0216778Licens: CC BY 4.0

Open Access ArticleForlagets udgivne version, 4,59 MBLicens: CC BY 4.0

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Berquist, E., Dumi, A., Upadhyay, S., Abarbanel, O. D., Cho, M., Gaur, S., Gano Gil, V. H., Hutchison, G. R., Lee, O. S., Rosen, A. S., Schamnad, S., Schneider, F. S. S., Steinmann, C., Stolyarchuk, M., Vandezande, J. E., Zak, W., & Langner, K. M. (2024). cclib 2.0: An updated architecture for interoperable computational chemistry. Journal of Chemical Physics, 161(4), Artikel 042501. https://doi.org/10.1063/5.0216778

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title = "cclib 2.0: An updated architecture for interoperable computational chemistry",

abstract = "Interoperability in computational chemistry is elusive, impeded by the independent development of software packages and idiosyncratic nature of their output files. The cclib library was introduced in 2006 as an attempt to improve this situation by providing a consistent interface to the results of various quantum chemistry programs. The shared API across programs enabled by cclib has allowed users to focus on results as opposed to output and to combine data from multiple programs or develop generic downstream tools. Initial development, however, did not anticipate the rapid progress of computational capabilities, novel methods, and new programs; nor did it foresee the growing need for customizability. Here, we recount this history and present cclib 2, focused on extensibility and modularity. We also introduce recent design pivots—the formalization of cclib{\textquoteright}s intermediate data representation as a tree-based structure, a new combinator-based parser organization, and parsed chemical properties as extensible objects.",

author = "Eric Berquist and Amanda Dumi and Shiv Upadhyay and Abarbanel, {Omri D} and Minsik Cho and Sagar Gaur and {Gano Gil}, {Victor Hugo} and Hutchison, {Geoffrey R} and Lee, {Oliver S} and Rosen, {Andrew S} and Sanjeed Schamnad and Schneider, {Felipe S S} and Casper Steinmann and Maxim Stolyarchuk and Vandezande, {Jonathon E} and Weronika Zak and Langner, {Karol M}",

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Berquist, E, Dumi, A, Upadhyay, S, Abarbanel, OD, Cho, M, Gaur, S, Gano Gil, VH, Hutchison, GR, Lee, OS, Rosen, AS, Schamnad, S, Schneider, FSS, Steinmann, C, Stolyarchuk, M, Vandezande, JE, Zak, W & Langner, KM 2024, 'cclib 2.0: An updated architecture for interoperable computational chemistry', Journal of Chemical Physics, bind 161, nr. 4, 042501. https://doi.org/10.1063/5.0216778

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AU - Gano Gil, Victor Hugo

AU - Hutchison, Geoffrey R

AU - Lee, Oliver S

AU - Rosen, Andrew S

AU - Schamnad, Sanjeed

AU - Schneider, Felipe S S

AU - Steinmann, Casper

AU - Stolyarchuk, Maxim

AU - Vandezande, Jonathon E

AU - Zak, Weronika

AU - Langner, Karol M

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cclib 2.0: An updated architecture for interoperable computational chemistry

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