QCaml/MOBasis/MOBasis.ml

open Lacaml.D
open Util

(** One-electron orthogonal basis set, corresponding to Molecular Orbitals. *)

module HF = HartreeFock_type
module Si = Simulation

type mo_class =
| Core of int
| Inactive of int
| Active of int
| Virtual of int
| Deleted of int

type mo_type =
| RHF | ROHF | CASSCF
| Natural of string
| Localized of string

type t = 
{
  ao_basis        : AOBasis.t;         (* Atomic basis set on which the MOs are built. *)
  mo_type         : mo_type;           (* Kind of MOs (RHF, CASSCF, Localized...       *)
  mo_class        : mo_class array;     (* CI-Class of the MOs *)
  mo_occupation   : Vec.t;             (* Occupation numbers *)
  mo_coef         : Mat.t;             (* Matrix of the MO coefficients in the AO basis *)
  eN_ints         : NucInt.t lazy_t;   (* Electron-nucleus potential integrals *)
  ee_ints         : ERI.t lazy_t;      (* Electron-electron potential integrals *)
  kin_ints        : KinInt.t lazy_t;   (* Kinetic energy integrals *)
}


let mo_matrix_of_ao_matrix ~mo_coef ao_matrix = 
  gemm ~transa:`T mo_coef   @@
  gemm ao_matrix mo_coef  


let ao_matrix_of_mo_matrix ~mo_coef ~ao_overlap mo_matrix =
  let sc = gemm ao_overlap mo_coef  in
  gemm sc @@
  gemm ~transb:`T mo_matrix sc


let four_index_transform ~mo_coef eri_ao =

  let ao_num = Mat.dim1 mo_coef in
  let mo_num = Mat.dim2 mo_coef in
  let eri_mo = ERI.create ~size:mo_num `Dense in

  let mo_num_2 = mo_num * mo_num in
  let ao_num_2 = ao_num * ao_num in
  let ao_mo_num = ao_num * mo_num in

  let range_mo = list_range ~start:1 mo_num in
  let range_ao = list_range ~start:1 ao_num in

  let u = 
      Mat.create mo_num_2 mo_num
  and o = 
      Mat.create ao_num ao_num_2 
  and p = 
      Mat.create ao_num_2 mo_num
  and q = 
      Mat.create ao_mo_num mo_num
  in
  Printf.eprintf "Transforming %d integrals : %!" mo_num;
  List.iter (fun delta ->
      Printf.eprintf "%d %!" delta;
      Mat.fill u 0.;

      List.iter (fun l ->

          let jk = ref 0 in
          List.iter (fun k ->
              List.iter (fun j ->
                  incr jk;
                  ERI.get_phys_all_i eri_ao ~j ~k ~l
                  |> Array.iteri (fun i x -> o.{i+1,!jk} <- x)
              ) range_ao
          ) range_ao;
          (* o_i_jk *)

          let p =
            gemm ~transa:`T ~c:p o mo_coef
            (* p_jk_alpha  = \sum_i o_i_jk c_i_alpha *)
          in
          let p' = 
            Bigarray.reshape_2 (Bigarray.genarray_of_array2 p) ao_num ao_mo_num
            (* p_j_kalpha *)
          in

          let q =
            gemm ~transa:`T ~c:q p' mo_coef
            (* q_kalpha_beta  = \sum_j p_j_kalpha c_j_beta *)
          in
          let q' =
            Bigarray.reshape_2 (Bigarray.genarray_of_array2 q) ao_num mo_num_2
            (* q_k_alphabeta  = \sum_j p_j_kalpha c_j_beta *)
          in

          ignore @@
            gemm ~transa:`T ~beta:1. ~c:u q' mo_coef 
            (* u_alphabeta_gamma = \sum_k q_k_alphabeta c_k_gamma *)

      ) range_ao;
      let u =
        Bigarray.reshape 
          (Bigarray.genarray_of_array2 u)
          [| mo_num ; mo_num ; mo_num |]
        |> Bigarray.array3_of_genarray 
      in
      List.iter (fun gamma ->
          List.iter (fun beta ->
              List.iter (fun alpha ->
                 let x = u.{alpha,beta,gamma} in
                 if x <> 0. then
                    ERI.set_phys eri_mo alpha beta gamma delta x
              ) range_mo
          ) range_mo
      ) range_mo
  ) range_mo;
  Printf.eprintf "\n%!";

  eri_mo


let make ~ao_basis ~mo_type ~mo_class ~mo_occupation ~mo_coef ()  =
  let eN_ints = lazy (
    Lazy.force ao_basis.AOBasis.eN_ints 
    |> NucInt.matrix
    |> mo_matrix_of_ao_matrix ~mo_coef   
    |> NucInt.of_matrix
  )
  and kin_ints = lazy (
    Lazy.force ao_basis.AOBasis.kin_ints 
    |> KinInt.matrix
    |> mo_matrix_of_ao_matrix ~mo_coef  
    |> KinInt.of_matrix
  )
  and ee_ints = lazy (
    Lazy.force ao_basis.AOBasis.ee_ints 
    |> four_index_transform ~mo_coef   
  )
  in
  { ao_basis ; mo_type ; mo_class ; mo_occupation ; mo_coef   ;
    eN_ints ; ee_ints ; kin_ints }


let of_rhf ~frozen_core hf =
  let simulation = hf.HF.simulation in
  let nocc = hf.HF.nocc in
  let ncore =
    if frozen_core then Nuclei.small_core simulation.Si.nuclei
    else 0
  in
  let mo_num = Vec.dim hf.HF.eigenvalues in

  let ao_basis = simulation.Si.ao_basis in
  let mo_type  = RHF in
  let mo_class =
    Array.init mo_num (fun i ->
      if (i < ncore) then Core i
      else 
        if (i < nocc ) then Inactive i
        else Virtual i)
  in
  let mo_occupation =
      Array.init mo_num (fun i ->
        if i < nocc then 2. else 0.)
      |> Vec.of_array
  in
  let mo_coef = hf.HF.eigenvectors in
  make ~ao_basis ~mo_type ~mo_class ~mo_occupation ~mo_coef ()


let of_hartree_fock ~frozen_core = function
| HF.RHF hf -> of_rhf ~frozen_core hf
| _ -> assert false
Four-idx transformation 2018-07-20 16:09:06 +02:00			`open Lacaml.D`
			`open Util`

			`(** One-electron orthogonal basis set, corresponding to Molecular Orbitals. *)`

			`module HF = HartreeFock_type`
			`module Si = Simulation`

			`type mo_class =`
			`\| Core of int`
			`\| Inactive of int`
			`\| Active of int`
			`\| Virtual of int`
			`\| Deleted of int`

			`type mo_type =`
			`\| RHF \| ROHF \| CASSCF`
			`\| Natural of string`
			`\| Localized of string`

			`type t =`
			`{`
			`ao_basis : AOBasis.t; (* Atomic basis set on which the MOs are built. *)`
			`mo_type : mo_type; (* Kind of MOs (RHF, CASSCF, Localized... *)`
			`mo_class : mo_class array; (* CI-Class of the MOs *)`
			`mo_occupation : Vec.t; (* Occupation numbers *)`
			`mo_coef : Mat.t; (* Matrix of the MO coefficients in the AO basis *)`
			`eN_ints : NucInt.t lazy_t; (* Electron-nucleus potential integrals *)`
			`ee_ints : ERI.t lazy_t; (* Electron-electron potential integrals *)`
			`kin_ints : KinInt.t lazy_t; (* Kinetic energy integrals *)`
			`}`



			`let mo_matrix_of_ao_matrix ~mo_coef ao_matrix =`
			gemm ~transa:`T mo_coef @@
			`gemm ao_matrix mo_coef`


			`let ao_matrix_of_mo_matrix ~mo_coef ~ao_overlap mo_matrix =`
			`let sc = gemm ao_overlap mo_coef in`
			`gemm sc @@`
			gemm ~transb:`T mo_matrix sc


			`let four_index_transform ~mo_coef eri_ao =`

			`let ao_num = Mat.dim1 mo_coef in`
			`let mo_num = Mat.dim2 mo_coef in`
			let eri_mo = ERI.create ~size:mo_num `Dense in

			`let mo_num_2 = mo_num * mo_num in`
			`let ao_num_2 = ao_num * ao_num in`
			`let ao_mo_num = ao_num * mo_num in`

			`let range_mo = list_range ~start:1 mo_num in`
			`let range_ao = list_range ~start:1 ao_num in`

			`let u =`
			`Mat.create mo_num_2 mo_num`
			`and o =`
			`Mat.create ao_num ao_num_2`
			`and p =`
			`Mat.create ao_num_2 mo_num`
			`and q =`
			`Mat.create ao_mo_num mo_num`
			`in`
			`Printf.eprintf "Transforming %d integrals : %!" mo_num;`
			`List.iter (fun delta ->`
			`Printf.eprintf "%d %!" delta;`
			`Mat.fill u 0.;`

			`List.iter (fun l ->`

			`let jk = ref 0 in`
			`List.iter (fun k ->`
			`List.iter (fun j ->`
			`incr jk;`
			`ERI.get_phys_all_i eri_ao ~j ~k ~l`
			`\|> Array.iteri (fun i x -> o.{i+1,!jk} <- x)`
			`) range_ao`
			`) range_ao;`
			`(* o_i_jk *)`

			`let p =`
			gemm ~transa:`T ~c:p o mo_coef
			`(* p_jk_alpha = \sum_i o_i_jk c_i_alpha *)`
			`in`
			`let p' =`
			`Bigarray.reshape_2 (Bigarray.genarray_of_array2 p) ao_num ao_mo_num`
			`(* p_j_kalpha *)`
			`in`

			`let q =`
			gemm ~transa:`T ~c:q p' mo_coef
			`(* q_kalpha_beta = \sum_j p_j_kalpha c_j_beta *)`
			`in`
			`let q' =`
			`Bigarray.reshape_2 (Bigarray.genarray_of_array2 q) ao_num mo_num_2`
			`(* q_k_alphabeta = \sum_j p_j_kalpha c_j_beta *)`
			`in`

			`ignore @@`
			gemm ~transa:`T ~beta:1. ~c:u q' mo_coef
			`(* u_alphabeta_gamma = \sum_k q_k_alphabeta c_k_gamma *)`

			`) range_ao;`
			`let u =`
			`Bigarray.reshape`
			`(Bigarray.genarray_of_array2 u)`
			`[\| mo_num ; mo_num ; mo_num \|]`
			`\|> Bigarray.array3_of_genarray`
			`in`
			`List.iter (fun gamma ->`
			`List.iter (fun beta ->`
			`List.iter (fun alpha ->`
			`let x = u.{alpha,beta,gamma} in`
			`if x <> 0. then`
			`ERI.set_phys eri_mo alpha beta gamma delta x`
			`) range_mo`
			`) range_mo`
			`) range_mo`
			`) range_mo;`
			`Printf.eprintf "\n%!";`

			`eri_mo`


			`let make ~ao_basis ~mo_type ~mo_class ~mo_occupation ~mo_coef () =`
			`let eN_ints = lazy (`
			`Lazy.force ao_basis.AOBasis.eN_ints`
			`\|> NucInt.matrix`
			`\|> mo_matrix_of_ao_matrix ~mo_coef`
			`\|> NucInt.of_matrix`
			`)`
			`and kin_ints = lazy (`
			`Lazy.force ao_basis.AOBasis.kin_ints`
			`\|> KinInt.matrix`
			`\|> mo_matrix_of_ao_matrix ~mo_coef`
			`\|> KinInt.of_matrix`
			`)`
			`and ee_ints = lazy (`
			`Lazy.force ao_basis.AOBasis.ee_ints`
			`\|> four_index_transform ~mo_coef`
			`)`
			`in`
			`{ ao_basis ; mo_type ; mo_class ; mo_occupation ; mo_coef ;`
			`eN_ints ; ee_ints ; kin_ints }`


			`let of_rhf ~frozen_core hf =`
			`let simulation = hf.HF.simulation in`
			`let nocc = hf.HF.nocc in`
			`let ncore =`
			`if frozen_core then Nuclei.small_core simulation.Si.nuclei`
			`else 0`
			`in`
			`let mo_num = Vec.dim hf.HF.eigenvalues in`

			`let ao_basis = simulation.Si.ao_basis in`
			`let mo_type = RHF in`
			`let mo_class =`
			`Array.init mo_num (fun i ->`
			`if (i < ncore) then Core i`
			`else`
			`if (i < nocc ) then Inactive i`
			`else Virtual i)`
			`in`
			`let mo_occupation =`
			`Array.init mo_num (fun i ->`
			`if i < nocc then 2. else 0.)`
			`\|> Vec.of_array`
			`in`
			`let mo_coef = hf.HF.eigenvectors in`
			`make ~ao_basis ~mo_type ~mo_class ~mo_occupation ~mo_coef ()`


			`let of_hartree_fock ~frozen_core = function`
			`\| HF.RHF hf -> of_rhf ~frozen_core hf`
			`\| _ -> assert false`