Common

1. Summary
2. Electrons
3. Element
4. Atomic mass
5. Nuclei
6. Z-matrix

1 Summary

2 Electrons

Data structure which contains the number of α and β electrons.

2.1 Type

type t

2.2 Creation

open Common

val make : int -> int -> t

val of_atoms : ?multiplicity:int -> ?charge:int -> Nuclei.t -> t
(* @param multiplicity default is 1
   @param charge       default is 0
   @raise Invalid_argument if the spin multiplicity is not compatible with
    the molecule and the total charge.
*)

`make`	`make n_alfa n_beta`
`of_atoms`	Creates the data relative to electrons for a molecular system described by `Nuclei.t` for a given total charge and spin multiplicity.

2.3 Access

val charge       : t -> Charge.t
val n_elec       : t -> int
val n_alfa       : t -> int
val n_beta       : t -> int
val multiplicity : t -> int

`charge`	Sum of the charges of the electrons
`n_elec`	Number of electrons
`n_alfa`	Number of alpha electrons
`n_beta`	Number of beta electrons
`multiplicity`	Spin multiplicity: \(2S+1\)

2.4 Printers

val pp : Format.formatter -> t -> unit

2.5 Tests

3 Element

Chemical elements.

3.1 Type

type t =
  |X
  |H                                                 |He
  |Li|Be                              |B |C |N |O |F |Ne
  |Na|Mg                              |Al|Si|P |S |Cl|Ar
  |K |Ca|Sc|Ti|V |Cr|Mn|Fe|Co|Ni|Cu|Zn|Ga|Ge|As|Se|Br|Kr
  |Rb|Sr|Y |Zr|Nb|Mo|Tc|Ru|Rh|Pd|Ag|Cd|In|Sn|Sb|Te|I |Xe
                          |Pt          

exception ElementError of string

open Common

3.2 Conversion

val of_string      : string -> t
val to_string      : t -> string
val to_long_string : t -> string

val to_int : t -> int 
val of_int : int -> t

val to_charge : t -> Charge.t
val of_charge : Charge.t -> t

`of_string`	Creates an `Element.t` from a chemical symbol or from the full name of the element (case insensitive)
`to_string`	Gets the chemical symbol of the `Element.t` in a string
`to_long_string`	Gets the full name of the `Element.t` in a string
`to_int`	Convert to the atomic charge, with `int` type
`of_int`	Create from the atomic charge, with `int` type
`to_charge`	Convert to the atomic charge, with `Charge.t` type
`of_charge`	Create from the atomic charge, with `Charge.t` type

Element.of_string "Fe" ;;
- : Element.t = Particles.Element.Fe

Element.of_string "hydrogen" ;;
- : Element.t = Particles.Element.H

Element.of_string "Kryptonite" ;;
Exception: Particles.Element.ElementError "Element Kryptonite unknown".

Element.(to_long_string Fe) ;;
- : string = "Iron"

Element.(to_string Fe);;
- : string = "Fe"

3.3 Database information

val covalent_radius : t -> Non_negative_float.t
val vdw_radius      : t -> Non_negative_float.t
val mass            : t -> Mass.t
val small_core      : t -> int
val large_core      : t -> int

`covalent_radius`	Covalent radii of the elements, in atomic units
`vdw_radius`	Van der Waals radii of the elements, in atomic units
`mass`	Atomic mass of the elements, in atomic units)
`small_core`	Number of electrons in the small core model (all except the outermost two shells)
`large_core`	Number of electrons in the large core model (all except the outermost shell)

3.4 Printers

val pp      : Format.formatter -> t -> unit
val pp_long : Format.formatter -> t -> unit

4 Atomic mass

Atomic mass, a non-negative float.

include module type of Common.Non_negative_float

5 Nuclei

5.1 Type

Nuclei.t

open Common

type t = (Element.t * Coordinate.t) array

5.2 xyz file lexer/parser

5.2.1 Lexer

nuclei_lexer.mll contains the description of the lexemes used in an xyz file.

{
open Xyz_parser
}

let eol = ['\n']
let white = [' ' '\t']+
let word = [^' ' '\t' '\n']+
let letter = ['A'-'Z' 'a'-'z']
let integer = ['0'-'9']+
let real = '-'? (integer '.' integer | integer '.' | '.' integer) (['e' 'E'] ('+'|'-')? integer)?


rule read_all = parse
  | eof            { EOF }
  | eol            { EOL }
  | white   as w   { SPACE w }
  | integer as i   { INTEGER (int_of_string i) }
  | real    as f   { FLOAT (float_of_string f) }
  | word    as w   { WORD w }


{
(* DEBUG
 let () =
   let ic = open_in "h2o.xyz" in
   let lexbuf = Lexing.from_channel ic in
   while true do
     let s =
      match read_all lexbuf with
      | EOL -> "EOL"
      | SPACE w -> "SPACE("^w^")"
      | INTEGER i -> "INTEGER("^(string_of_int i)^")"
      | FLOAT f -> "FLOAT("^(string_of_float f)^")"
      | WORD w -> "WORD("^w^")"
      | EOF -> "EOF"
     in
     print_endline s
   done;
*)
}

5.2.2 Parser

xyz_parser.mly parses nuclear coordinates in xyz format.

%{
open Common

let make_angstrom x y z =
  Coordinate.(make_angstrom {
    x ; y ; z
  })

let output_of f x y z =
  let a = make_angstrom x y z in
  fun e ->
  {
    Xyz_ast.
    element = f e;
    coord = a ;
  }

let output_of_string = output_of Element.of_string
let output_of_int    = output_of Element.of_int

%}

%token EOL
%token <string> SPACE
%token <string> WORD
%token <int> INTEGER
%token <float> FLOAT
%token EOF

%start input
%type <Xyz_ast.xyz_file> input

%% /* Grammar rules and actions follow */

input:
  | integer title atoms_xyz {
      {
        number_of_atoms = $1;
        file_title = $2;
        nuclei = $3;
      }
    }
;


integer:
  | INTEGER EOL { $1 }
  | INTEGER SPACE EOL { $1 }
  | SPACE INTEGER EOL { $2 }
  | SPACE INTEGER SPACE EOL { $2 }
;

title:
  | title_list EOL { $1 }
;

text:
  | WORD    { $1 }
  | SPACE   { $1 }
  | FLOAT   { (string_of_float $1)}
  | INTEGER { (string_of_int $1)}
;

title_list:
  | { "" }
  | title_list text { ($1 ^ $2) }
;

atoms_xyz:
  | atoms_list EOL { List.rev $1 }
  | atoms_list EOF { List.rev $1 }
;

atoms_list:
  | { [] }
  | atoms_list WORD    SPACE FLOAT SPACE FLOAT SPACE FLOAT       EOL { output_of_string $4 $6 $8 $2 :: $1 }
  | atoms_list WORD    SPACE FLOAT SPACE FLOAT SPACE FLOAT SPACE EOL { output_of_string $4 $6 $8 $2 :: $1 }
  | atoms_list INTEGER SPACE FLOAT SPACE FLOAT SPACE FLOAT       EOL { output_of_int    $4 $6 $8 $2 :: $1 }
  | atoms_list INTEGER SPACE FLOAT SPACE FLOAT SPACE FLOAT SPACE EOL { output_of_int    $4 $6 $8 $2 :: $1 }
  | atoms_list SPACE WORD    SPACE FLOAT SPACE FLOAT SPACE FLOAT       EOL { output_of_string $5 $7 $9 $3 :: $1 }
  | atoms_list SPACE WORD    SPACE FLOAT SPACE FLOAT SPACE FLOAT SPACE EOL { output_of_string $5 $7 $9 $3 :: $1 }
  | atoms_list SPACE INTEGER SPACE FLOAT SPACE FLOAT SPACE FLOAT       EOL { output_of_int    $5 $7 $9 $3 :: $1 }
  | atoms_list SPACE INTEGER SPACE FLOAT SPACE FLOAT SPACE FLOAT SPACE EOL { output_of_int    $5 $7 $9 $3 :: $1 }
;

When an xyz file is read by xyz_parser.mly, it is converted into an xyz_file data structure.

open Common

type nucleus =
  {
    element: Element.t ;
    coord  : Coordinate.angstrom Coordinate.point;
  }

type xyz_file =
  {
    number_of_atoms : int ;
    file_title      : string ;
    nuclei          : nucleus list ;
  }

5.3 Conversion

val of_xyz_string : string -> t
val to_xyz_string  : t -> string
val of_xyz_file   : string -> t

val of_zmt_string : string -> t
val of_zmt_file   : string -> t

val to_string      : t -> string

val of_filename : string -> t

`of_xyz_string`	Create from a string, in xyz format
`of_xyz_file`	Create from a file, in xyz format
`of_zmt_string`	Create from a string, in z-matrix format
`of_zmt_file`	Create from a file, in z-matrix format
`to_string`	Transform to a string, for printing
`of_filename`	Detects the type of file (xyz, z-matrix) and reads the file

5.4 Query

val formula    : t -> string
val repulsion  : t -> float
val charge     : t -> Charge.t
val small_core : t -> int
val large_core : t -> int

`formula`	Returns the chemical formula
`repulsion`	Nuclear repulsion energy, in atomic units
`charge`	Sum of the charges of the nuclei
`small_core`	Number of core electrons in the small core model
`large_core`	Number of core electrons in the large core model

5.5 TREXIO

5.5.1 Read

val of_trexio : Trexio.trexio_file -> t

5.5.2 Write

val to_trexio : Trexio.trexio_file -> t -> unit

5.6 Printers

val pp : Format.formatter -> t -> unit

5.7 Tests

6 Z-matrix

Z-matrix representation of nuclear coordinates.

6.1 Type

type t

6.2 Conversion

val of_string      : string -> t
val to_xyz         : t -> (Element.t * float * float * float) array
val to_xyz_string  : t -> string

`of_string`	Reads a z-matrix from a string
`to_xyz`	Converts to xyz format, as in the `Nuclei` module
`to_xyz_string`	Converts to xyz format, as a string

let zmt = Zmatrix.of_string "
 n
 n    1 nn
 h    1 hn         2 hnn
 h    2 hn         1 hnn          3 dih4
 h    1 hn         2 hnn          4 dih5
 h    2 hn         1 hnn          3 dih5

nn          1.446
hn          1.016
hnn         106.0
dih4        -54.38
dih5         54.38
" ;;
- : Zmatrix.t = N  
N       1 1.446000
H       1 1.016000     2 106.000000
H       2 1.016000     1 106.000000     3 -54.380000
H       1 1.016000     2 106.000000     4 54.380000
H       2 1.016000     1 106.000000     3 54.380000


Zmatrix.to_xyz zmt ;;
- : (Element.t * float * float * float) array =
[|(N, 0., 0., 0.); (N, 0., 0., 1.446);
  (H, -0.976641883073332107, 0., -0.280047553510071046);
  (H, -0.568802835186988709, 0.793909757123734683, 1.726047553510071);
  (H, 0.314092649983635563, 0.924756819385119, -0.280047553510071101);
  (H, -0.568802835186988709, -0.793909757123734683, 1.726047553510071)|]


Zmatrix.to_xyz_string zmt ;;
- : string =
"N 0.000000 0.000000 0.000000
N 0.000000 0.000000 1.446000
H -0.976642 0.000000 -0.280048
H -0.568803 0.793910 1.726048
H 0.314093 0.924757 -0.280048
H -0.568803 -0.793910 1.726048"

6.3 Printers

val pp : Format.formatter -> t -> unit