QCaml/Basis/OneElectronRR.ml

open Util
open Constants

exception NullPair

module Am  = AngularMomentum
module Co  = Coordinate
module Cs  = ContractedShell
module Csp = ContractedShellPair
module Po  = Powers
module Sp  = ShellPair


(** Horizontal and Vertical Recurrence Relations (HVRR) *)
let hvrr_one_e  angMom_a  angMom_b  
    zero_m_array expo_b expo_inv_p
    center_ab center_pa center_pc
    map =

  let maxm = angMom_a.Po.tot + angMom_b.Po.tot  in
  let maxsze = maxm+1 in

  let get_xyz angMom =
    match angMom with
    | { Po.y=0 ; z=0 ; _ } -> Co.X
    | {          z=0 ; _ } -> Co.Y
    | _                    -> Co.Z
  in


  (** Vertical recurrence relations *)
  let rec vrr angMom_a =
    let { Po.x=ax ; y=ay ; z=az } = angMom_a in
    if ax < 0 || ay < 0 || az < 0 then raise Exit
    else
      match angMom_a.Po.tot  with
      | 0 -> zero_m_array
      | _ ->
        let key = Zkey.of_powers_three angMom_a in

        try Zmap.find map key with
        | Not_found -> 
          let result = 
            let xyz   = get_xyz angMom_a in
            let am    = Po.decr xyz angMom_a in
            let amxyz = Po.get xyz am in
            let f1    = Co.get xyz center_pa  in
            let f2    = expo_inv_p *. Co.get xyz center_pc in
            if amxyz < 1 then
                let v1 = vrr am in
                Array.init (maxsze - angMom_a.Po.tot)
                  (fun m -> f1 *. v1.(m) -. f2 *. v1.(m+1))
            else
                let v3 =
                  let amm = Po.decr xyz am in
                  vrr amm
                in
                let v1 = vrr am in
                let f3 = float_of_int amxyz *. expo_inv_p *. 0.5 in
                Array.init (maxsze - angMom_a.Po.tot)
                  (fun m -> f1 *. v1.(m) -.  f2 *. v1.(m+1) +.
                            f3 *. (v3.(m) -. expo_inv_p *. v3.(m+1))
                )
          in Zmap.add map key result;
          result


  (** Horizontal recurrence relations *)
  and hrr angMom_a angMom_b =

    match angMom_b.Po.tot  with
    | 0 -> (vrr angMom_a).(0)
    | _ ->
      let xyz = get_xyz angMom_b in
      let bxyz = Po.get xyz angMom_b in
      if (bxyz < 1) then 0. else
          let ap = Po.incr xyz angMom_a in
          let bm = Po.decr xyz angMom_b in
          let h1 = hrr ap bm in
          let f2 = Co.get xyz center_ab in
          if abs_float f2 < integrals_cutoff then h1 else
              let h2 = hrr angMom_a bm in
              h1 +. f2 *. h2

  in
  hrr angMom_a angMom_b


(** Computes all the one-electron integrals of the contracted shell pair *)
let contracted_class_shell_pair ~zero_m shell_p geometry : float Zmap.t =

  let shell_a = shell_p.Csp.shell_a
  and shell_b = shell_p.Csp.shell_b
  in
  let maxm = 
    (Am.to_int @@ shell_a.totAngMom) + (Am.to_int @@ shell_b.totAngMom) 
  in

  (* Pre-computation of integral class indices *)
  let class_indices = 
    Am.zkey_array (Am.Doublet (shell_a.totAngMom, shell_b.totAngMom))
  in

  let contracted_class = 
    Array.make (Array.length class_indices) 0.;
  in

  (* Compute all integrals in the shell for each pair of significant shell pairs *)

  let norm_coef_scale_p = shell_p.Csp.norm_coef_scale 
  in
  for ab=0 to (Array.length shell_p.Csp.shell_pairs - 1)
  do
    let b = shell_p.Csp.shell_pairs.(ab).Sp.j in
    try
      begin
        let coef_prod = shell_p.Csp.coef.(ab) in

        (** Screening on the product of coefficients *)
        if abs_float coef_prod < 1.e-3 *. integrals_cutoff then
          raise NullPair;


        let expo_pq_inv =
          shell_p.Csp.expo_inv.(ab) 
        in

        let center_ab = 
          shell_p.Csp.center_ab
        in
        let center_p = 
          shell_p.Csp.shell_pairs.(ab).Sp.center
        in
        let center_pa = 
          Co.(center_p |- shell_a.center) 
        in

        for c=0 to Array.length geometry - 1 do
          let element, nucl_coord = geometry.(c) in
          let charge = Element.to_charge element |> Charge.to_float in
          let center_pc =
            Co.(center_p |- nucl_coord ) 
          in
          let norm_pq_sq = 
            Co.dot center_pc center_pc
          in

          let zero_m_array = 
            zero_m ~maxm ~expo_pq_inv ~norm_pq_sq
          in
          match (shell_a.totAngMom, shell_b.totAngMom) with
          | Am.(S,S) -> 
            let integral = zero_m_array.(0) in
            contracted_class.(0) <- contracted_class.(0) -. coef_prod *. integral *. charge
          | _ ->
            let map = Zmap.create (2*maxm) in
            let norm_coef_scale = norm_coef_scale_p in
            (* Compute the integral class from the primitive shell quartet *)
            class_indices
            |> Array.iteri (fun i key ->
                let (angMomA,angMomB) =
                  match Zkey.to_powers key with
                  | Zkey.Six x -> x
                  | _          -> assert false
                in
                let norm = norm_coef_scale.(i) in
                let coef_prod = coef_prod *. norm in
                let integral = 
                  hvrr_one_e
                    angMomA  angMomB
                    zero_m_array
                    shell_b.expo.(b)
                    shell_p.Csp.expo_inv.(ab)
                    center_ab center_pa center_pc
                    map
                in
                contracted_class.(i) <- contracted_class.(i) -. coef_prod *. integral *. charge
              )
      done
  end
  with NullPair -> ()
done;
let result = 
  Zmap.create (Array.length contracted_class)
in
Array.iteri (fun i key -> Zmap.add result key contracted_class.(i)) class_indices;
result
Working on 1e integrals 2018-01-22 15:27:41 +01:00			`open Util`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`open Constants`

			`exception NullPair`
Working on 1e integrals 2018-01-22 15:27:41 +01:00
Working on documenation 2018-02-23 18:41:30 +01:00			`module Am = AngularMomentum`
Cleaning 2018-02-23 15:49:27 +01:00			`module Co = Coordinate`
Working on documenation 2018-02-23 18:41:30 +01:00			`module Cs = ContractedShell`
Cleaning 2018-02-23 15:49:27 +01:00			`module Csp = ContractedShellPair`
			`module Po = Powers`
			`module Sp = ShellPair`

Working on 1e integrals 2018-01-22 15:27:41 +01:00

			`(** Horizontal and Vertical Recurrence Relations (HVRR) *)`
Cleaning 2018-02-23 15:49:27 +01:00			`let hvrr_one_e angMom_a angMom_b`
			`zero_m_array expo_b expo_inv_p`
			`center_ab center_pa center_pc`
			`map =`
Working on 1e integrals 2018-01-22 15:27:41 +01:00
Cleaning 2018-02-23 15:49:27 +01:00			`let maxm = angMom_a.Po.tot + angMom_b.Po.tot in`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`let maxsze = maxm+1 in`
Working on 1e integrals 2018-01-22 15:27:41 +01:00
Working {x;y;z;tot} 2018-02-19 16:01:13 +01:00			`let get_xyz angMom =`
			`match angMom with`
Cleaning 2018-02-23 15:49:27 +01:00			`\| { Po.y=0 ; z=0 ; _ } -> Co.X`
			`\| { z=0 ; _ } -> Co.Y`
			`\| _ -> Co.Z`
Working {x;y;z;tot} 2018-02-19 16:01:13 +01:00			`in`


Working on 1e integrals 2018-01-22 15:27:41 +01:00			`(** Vertical recurrence relations *)`
Working {x;y;z;tot} 2018-02-19 16:01:13 +01:00			`let rec vrr angMom_a =`
Cleaning 2018-02-23 15:49:27 +01:00			`let { Po.x=ax ; y=ay ; z=az } = angMom_a in`
Working {x;y;z;tot} 2018-02-19 16:01:13 +01:00			`if ax < 0 \|\| ay < 0 \|\| az < 0 then raise Exit`
Working on 1e integrals 2018-01-22 15:27:41 +01:00			`else`
Cleaning 2018-02-23 15:49:27 +01:00			`match angMom_a.Po.tot with`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`\| 0 -> zero_m_array`
Working on 1e integrals 2018-01-22 15:27:41 +01:00			`\| _ ->`
Documentation 2018-02-25 00:53:09 +01:00			`let key = Zkey.of_powers_three angMom_a in`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00
			`try Zmap.find map key with`
			`\| Not_found ->`
			`let result =`
Cleaning 2018-02-23 15:49:27 +01:00			`let xyz = get_xyz angMom_a in`
			`let am = Po.decr xyz angMom_a in`
			`let amxyz = Po.get xyz am in`
			`let f1 = Co.get xyz center_pa in`
			`let f2 = expo_inv_p *. Co.get xyz center_pc in`
			`if amxyz < 1 then`
			`let v1 = vrr am in`
			`Array.init (maxsze - angMom_a.Po.tot)`
			`(fun m -> f1 . v1.(m) -. f2 . v1.(m+1))`
			`else`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`let v3 =`
Cleaning 2018-02-23 15:49:27 +01:00			`let amm = Po.decr xyz am in`
Working {x;y;z;tot} 2018-02-19 16:01:13 +01:00			`vrr amm`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`in`
Cleaning 2018-02-23 15:49:27 +01:00			`let v1 = vrr am in`
			`let f3 = float_of_int amxyz . expo_inv_p . 0.5 in`
			`Array.init (maxsze - angMom_a.Po.tot)`
			`(fun m -> f1 . v1.(m) -. f2 . v1.(m+1) +.`
			`f3 . (v3.(m) -. expo_inv_p . v3.(m+1))`
			`)`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`in Zmap.add map key result;`
			`result`
Working on 1e integrals 2018-01-22 15:27:41 +01:00

			`(** Horizontal recurrence relations *)`
Working {x;y;z;tot} 2018-02-19 16:01:13 +01:00			`and hrr angMom_a angMom_b =`
Working on 1e integrals 2018-01-22 15:27:41 +01:00
Cleaning 2018-02-23 15:49:27 +01:00			`match angMom_b.Po.tot with`
			`\| 0 -> (vrr angMom_a).(0)`
			`\| _ ->`
			`let xyz = get_xyz angMom_b in`
			`let bxyz = Po.get xyz angMom_b in`
			`if (bxyz < 1) then 0. else`
			`let ap = Po.incr xyz angMom_a in`
			`let bm = Po.decr xyz angMom_b in`
			`let h1 = hrr ap bm in`
			`let f2 = Co.get xyz center_ab in`
Documentation 2018-02-24 23:57:38 +01:00			`if abs_float f2 < integrals_cutoff then h1 else`
Cleaning 2018-02-23 15:49:27 +01:00			`let h2 = hrr angMom_a bm in`
			`h1 +. f2 *. h2`
Working on 1e integrals 2018-01-22 15:27:41 +01:00
			`in`
Working {x;y;z;tot} 2018-02-19 16:01:13 +01:00			`hrr angMom_a angMom_b`
Working on 1e integrals 2018-01-22 15:27:41 +01:00








			`(** Computes all the one-electron integrals of the contracted shell pair *)`
Working on Nuc 2018-02-05 23:31:46 +01:00			`let contracted_class_shell_pair ~zero_m shell_p geometry : float Zmap.t =`
Working on 1e integrals 2018-01-22 15:27:41 +01:00
Cleaning 2018-02-23 15:49:27 +01:00			`let shell_a = shell_p.Csp.shell_a`
			`and shell_b = shell_p.Csp.shell_b`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`in`
			`let maxm =`
Cleaning 2018-02-23 15:49:27 +01:00			`(Am.to_int @@ shell_a.totAngMom) + (Am.to_int @@ shell_b.totAngMom)`
Working on 1e integrals 2018-01-22 15:27:41 +01:00			`in`

			`(* Pre-computation of integral class indices *)`
			`let class_indices =`
Cleaning 2018-02-23 15:49:27 +01:00			`Am.zkey_array (Am.Doublet (shell_a.totAngMom, shell_b.totAngMom))`
Working on 1e integrals 2018-01-22 15:27:41 +01:00			`in`

			`let contracted_class =`
			`Array.make (Array.length class_indices) 0.;`
			`in`

			`(* Compute all integrals in the shell for each pair of significant shell pairs *)`

Cleaning 2018-02-23 15:49:27 +01:00			`let norm_coef_scale_p = shell_p.Csp.norm_coef_scale`
Working on contraction 2018-02-09 19:41:22 +01:00			`in`
Cleaning 2018-02-23 15:49:27 +01:00			`for ab=0 to (Array.length shell_p.Csp.shell_pairs - 1)`
Working on 1e integrals 2018-01-22 15:27:41 +01:00			`do`
Cleaning 2018-02-23 15:49:27 +01:00			`let b = shell_p.Csp.shell_pairs.(ab).Sp.j in`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`try`
			`begin`
Cleaning 2018-02-23 15:49:27 +01:00			`let coef_prod = shell_p.Csp.coef.(ab) in`
Working on 1e integrals 2018-01-22 15:27:41 +01:00
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`(** Screening on the product of coefficients *)`
Documentation 2018-02-24 23:57:38 +01:00			`if abs_float coef_prod < 1.e-3 *. integrals_cutoff then`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`raise NullPair;`
Working on 1e integrals 2018-01-22 15:27:41 +01:00

Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`let expo_pq_inv =`
Cleaning 2018-02-23 15:49:27 +01:00			`shell_p.Csp.expo_inv.(ab)`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`in`

			`let center_ab =`
Cleaning 2018-02-23 15:49:27 +01:00			`shell_p.Csp.center_ab`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`in`
Nuclear Integrals OK 2018-02-06 12:02:00 +01:00			`let center_p =`
Cleaning 2018-02-23 15:49:27 +01:00			`shell_p.Csp.shell_pairs.(ab).Sp.center`
Nuclear Integrals OK 2018-02-06 12:02:00 +01:00			`in`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`let center_pa =`
Cleaning 2018-02-23 15:49:27 +01:00			`Co.(center_p \|- shell_a.center)`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`in`

Working on Nuc 2018-02-05 23:31:46 +01:00			`for c=0 to Array.length geometry - 1 do`
			`let element, nucl_coord = geometry.(c) in`
			`let charge = Element.to_charge element \|> Charge.to_float in`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`let center_pc =`
Cleaning 2018-02-23 15:49:27 +01:00			`Co.(center_p \|- nucl_coord )`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`in`
			`let norm_pq_sq =`
Cleaning 2018-02-23 15:49:27 +01:00			`Co.dot center_pc center_pc`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`in`

			`let zero_m_array =`
			`zero_m ~maxm ~expo_pq_inv ~norm_pq_sq`
			`in`
Cleaning 2018-02-23 15:49:27 +01:00			`match (shell_a.totAngMom, shell_b.totAngMom) with`
			`\| Am.(S,S) ->`
			`let integral = zero_m_array.(0) in`
Working on Nuc 2018-02-05 23:31:46 +01:00			`contracted_class.(0) <- contracted_class.(0) -. coef_prod . integral . charge`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`\| _ ->`
			`let map = Zmap.create (2*maxm) in`
			`let norm_coef_scale = norm_coef_scale_p in`
			`(* Compute the integral class from the primitive shell quartet *)`
			`class_indices`
			`\|> Array.iteri (fun i key ->`
			`let (angMomA,angMomB) =`
CLeaning Zkey 2018-02-25 01:40:12 +01:00			`match Zkey.to_powers key with`
Removed arrays 2018-02-06 17:13:25 +01:00			`\| Zkey.Six x -> x`
			`\| _ -> assert false`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`in`
			`let norm = norm_coef_scale.(i) in`
			`let coef_prod = coef_prod *. norm in`
			`let integral =`
Cleaning 2018-02-23 15:49:27 +01:00			`hvrr_one_e`
			`angMomA angMomB`
			`zero_m_array`
			`shell_b.expo.(b)`
			`shell_p.Csp.expo_inv.(ab)`
			`center_ab center_pa center_pc`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`map`
			`in`
Working on Nuc 2018-02-05 23:31:46 +01:00			`contracted_class.(i) <- contracted_class.(i) -. coef_prod . integral . charge`
Working on Nuclear integrals 2018-02-03 23:26:20 +01:00			`)`
			`done`
			`end`
			`with NullPair -> ()`
			`done;`
			`let result =`
			`Zmap.create (Array.length contracted_class)`
			`in`
			`Array.iteri (fun i key -> Zmap.add result key contracted_class.(i)) class_indices;`
			`result`

Working on 1e integrals 2018-01-22 15:27:41 +01:00