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quack/qcaml-tools/GoDuck.ml

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let quack_dir =
try Sys.getenv "QUACK_ROOT" with
Not_found -> "."
let quack_input = quack_dir ^ "/input/"
let quack_mol = quack_dir ^ "/mol/"
let quack_basis = quack_dir ^ "/basis/"
let quack_int = quack_dir ^ "/int/"
let quack_basis_filename = quack_input ^ "basis"
let quack_molecule_filename = quack_input ^ "molecule"
module Command_line = Qcaml.Common.Command_line
module Util = Qcaml.Common.Util
let () =
let open Command_line in
begin
set_header_doc (Sys.argv.(0) ^ " - QuAcK command");
set_description_doc "Prepares the input data for QuAcK.
Writes $QUACK_ROOT/input/basis and $QUACK_ROOT/input/molecule.
If $QUACK_ROOT is not set, $QUACK_ROOT is replaces by the current
directory.";
set_specs
[ { short='b' ; long="basis" ; opt=Mandatory;
arg=With_arg "<string>";
doc="Name of the file containing the basis set in the $QUACK_ROOT/basis/ directory"; } ;
{ short='x' ; long="xyz" ; opt=Mandatory;
arg=With_arg "<string>";
doc="Name of the file containing the nuclear coordinates in xyz format in the $QUACK_ROOT/mol/ directory without the .xyz extension"; } ;
{ short='m' ; long="multiplicity" ; opt=Optional;
arg=With_arg "<int>";
doc="Spin multiplicity (2S+1). Default is singlet"; } ;
{ short='c' ; long="charge" ; opt=Optional;
arg=With_arg "<int>";
doc="Total charge of the molecule. Specify negative charges with 'm' instead of the minus sign, for example m1 instead of -1. Default is 0"; } ;
{ short='f' ; long="frozen-core" ; opt=Optional;
arg=Without_arg ;
doc="Freeze core MOs. Default is false"; } ;
{ short='r' ; long="rydberg" ; opt=Optional;
arg=With_arg "<int>" ;
doc="Number of Rydberg electrons. Default is 0"; } ;
{ short='u' ; long="range-separation" ; opt=Optional;
arg=With_arg "<float>";
doc="Range-separation parameter."; } ;
]
end;
(* Handle options *)
let basis_file =
quack_basis ^ (Util.of_some @@ Command_line.get "basis")
in
let nuclei_file =
quack_mol ^ (Util.of_some @@ Command_line.get "xyz") ^ ".xyz"
in
let frozen_core = Command_line.get_bool "frozen-core" in
let charge =
match Command_line.get "charge" with
| Some x -> ( if x.[0] = 'm' then
~- (int_of_string (String.sub x 1 (String.length x - 1)))
else
int_of_string x )
| None -> 0
in
let multiplicity =
match Command_line.get "multiplicity" with
| Some x -> int_of_string x
| None -> 1
in
let rydberg =
match Command_line.get "rydberg" with
| Some x -> int_of_string x
| None -> 0
in
let range_separation =
match Command_line.get "range-separation" with
| None -> None
| Some mu -> Some (float_of_string mu)
in
let nuclei =
Qcaml.Particles.Nuclei.of_xyz_file nuclei_file
in
let electrons =
Qcaml.Particles.Electrons.of_atoms ~multiplicity ~charge nuclei
in
let basis =
Qcaml.Gaussian.Basis.of_nuclei_and_basis_filename ~nuclei basis_file
in
let print_basis nuclei basis =
let oc = open_out quack_basis_filename in
let ocf = Format.formatter_of_out_channel oc in
let g_basis = Qcaml.Gaussian.Basis.general_basis basis in
let dict =
Array.to_list nuclei
|> List.mapi (fun i (e, _) ->
(i+1), List.assoc e g_basis
)
in
List.iter (fun (i,b) ->
Format.fprintf ocf "%d %d\n" i (Array.length b);
Array.iter (fun x ->
Format.fprintf ocf "%a" Qcaml.Gaussian.General_basis.pp_gcs x) b
) dict;
close_out oc
in
print_basis nuclei basis;
let print_molecule nuclei electrons =
let oc = open_out quack_molecule_filename in
let nat = Array.length nuclei in
let nela = Qcaml.Particles.Electrons.n_alfa electrons in
let nelb = Qcaml.Particles.Electrons.n_beta electrons in
let ncore =
if frozen_core then
Qcaml.Particles.Nuclei.small_core nuclei
else 0
in
let nryd = rydberg in
Printf.fprintf oc "# nAt nEla nElb nCore nRyd\n";
Printf.fprintf oc " %4d %4d %4d %5d %4d\n" nat nela nelb ncore nryd;
Printf.fprintf oc "# Znuc x y z\n";
let open Qcaml.Common.Coordinate in
Array.iter (fun (element, coord) ->
Printf.fprintf oc "%3s %16.10f %16.10f %16.10f\n"
(Qcaml.Particles.Element.to_string element)
coord.x coord.y coord.z
) nuclei;
close_out oc
in
print_molecule nuclei electrons;
let operators =
match range_separation with
| None -> []
| Some mu -> [ Qcaml.Operators.Operator.of_range_separation mu ]
in
let ao_basis =
Qcaml.Ao.Basis.of_nuclei_and_basis_filename ~kind:`Gaussian
~operators ~cartesian:true ~nuclei basis_file
in
let overlap = Qcaml.Ao.Basis.overlap ao_basis in
let eN_ints = Qcaml.Ao.Basis.eN_ints ao_basis in
let kin_ints = Qcaml.Ao.Basis.kin_ints ao_basis in
let ee_ints = Qcaml.Ao.Basis.ee_ints ao_basis in
let multipole = Qcaml.Ao.Basis.multipole ao_basis in
let x_mat = Qcaml.Gaussian_integrals.Multipole.matrix_x multipole in
let y_mat = Qcaml.Gaussian_integrals.Multipole.matrix_y multipole in
let z_mat = Qcaml.Gaussian_integrals.Multipole.matrix_z multipole in
Qcaml.Gaussian_integrals.Overlap.to_file ~filename:(quack_int ^ "Ov.dat") overlap;
Qcaml.Gaussian_integrals.Electron_nucleus.to_file ~filename:(quack_int ^ "Nuc.dat") eN_ints;
Qcaml.Gaussian_integrals.Kinetic.to_file ~filename:(quack_int ^ "Kin.dat") kin_ints;
Qcaml.Gaussian_integrals.Eri.to_file ~filename:(quack_int ^ "ERI.dat") ee_ints;
Qcaml.Gaussian_integrals.Multipole.to_file ~filename:(quack_int ^ "x.dat") x_mat;
Qcaml.Gaussian_integrals.Multipole.to_file ~filename:(quack_int ^ "y.dat") y_mat;
Qcaml.Gaussian_integrals.Multipole.to_file ~filename:(quack_int ^ "z.dat") z_mat;
match range_separation with
| Some _mu ->
Qcaml.Gaussian_integrals.Eri_long_range.to_file ~filename:(quack_int ^ "ERI_lr.dat") (Qcaml.Ao.Basis.ee_lr_ints ao_basis)
| None -> ()
;
Unix.execv (quack_dir ^ "/bin/QuAcK") [| "QuAcK" |]
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