A brief history
The OpenRSP core functionality
Work on the OpenRSP project began in the mid-2000's when the first work started on what has become the present version of the program. During this time, the theoretical foundation of response theory on which OpenRSP was based was developed and used to create program routines that were connected to the Dalton quantum chemistry program. This version of the code was used to compute several response properties for which analytic calculation had not been carried out before.
In 2008, we have generalized OpenRSP for the DIRAC program package which enabled us to access a wealth of response properties at the 4-component relativistic level.
In 2011, work was started on a version - then still a part of Dalton - where recursion was used to achieve an open-ended implementation of the theory, so that one set of routines could be used to manage the calculation of any response property. This version forms the basis of the present-day core functionality of the OpenRSP, but was since developed further to include features such as calculation of single residues of response properties (of use in the calculation of multiphoton strengths), calculation of multiple properties in one invocation with reuse of common intermediate results, and restructuring of calls to external routines to reduce recalculation of various contributions such as perturbed one- and two-electron integrals.
OpenRSP as a modular library with an API
In order to make OpenRSP into a modular library that was not tied to any one particular quantum chemistry program - or host program - work began in 2013 on developing an application programming interface (API) for OpenRSP, involving the creation of clearly defined interfaces between OpenRSP and other codes, the use of callback routines in order to abstract the way in which the OpenRSP core asks for contributions from external libraries, and the development of the QcMatrix library to abstract and mediate matrix operations so that OpenRSP is agnostic to the underlying implementation of such operations. The first host program to make use of this modular functionality is the LSDalton quantum chemistry program.
Libraries for external contributions
During the course of its execution, OpenRSP identifies various contributions that it must get from libraries external to it in order to be able to assemble the response property or properties to be calculated, such as perturbed one- and two-electron integral contributions, exchange-correlation contributions if a density-functional theory calculation is requested, or solution of so-called response equations. Therefore, the development of libraries that can provide such functionality at a sufficient level of generality - although not necessarily driven by the demands of OpenRSP - has nevertheless been an important concurrent task, and has resulted in the creation of sophisticated software without which OpenRSP would not be able to do what it does best. Some of the libraries that are presently used or have been used by OpenRSP are listed below:
- Gen1Int for the calculation of perturbed one-electron integrals
- cgto-diff-eri for the calculation of perturbed two-electron integrals
- HODI for the calculation of perturbed integrals
- XCint and XCfun for the calculation of exchange-correlation contributions
- A linear response equation solver by Sonia Coriani et al.
- FraME for a polarizable embedding description of molecular surroundings
- PCMSolver for a polarizable continuum description of molecular surroundings