QCaml/CI/CI.ml

open Lacaml.D

module Ds = Determinant_space

type t =
  {
    det_space   : Ds.t ;
    m_H         : Matrix.t lazy_t ;
    m_S2        : Matrix.t lazy_t ;
    eigensystem : (Mat.t * Vec.t) lazy_t;
    n_states    : int;
  }

let det_space    t = t.det_space

let n_states     t = t.n_states

let m_H          t = Lazy.force t.m_H

let m_S2         t = Lazy.force t.m_S2

let eigensystem  t = Lazy.force t.eigensystem 

let eigenvectors t = 
  let (x,_) = eigensystem t in x

let eigenvalues t = 
  let (_,x) = eigensystem t in x

let h_integrals mo_basis = 
  let one_e_ints  = MOBasis.one_e_ints mo_basis
  and two_e_ints  = MOBasis.two_e_ints mo_basis
  in
  ( (fun i j _ -> one_e_ints.{i,j}), 
    (fun i j k l s s' ->
       if s' = Spin.other s then
         ERI.get_phys two_e_ints i j k l
       else
         (ERI.get_phys two_e_ints i j k l) -. 
         (ERI.get_phys two_e_ints i j l k) 
    ) )


let h_ij mo_basis ki kj =
  let integrals =
    List.map (fun f -> f mo_basis)
      [ h_integrals ]
  in
  CIMatrixElement.make integrals ki kj 
  |> List.hd


let create_matrix_arbitrary f det_space =
  lazy (
    let det = 
      match Ds.determinants det_space with
      | Ds.Arbitrary a -> a
      | _ -> assert false
    in

    let ndet = Ds.size det_space in

    let v = Vec.make0 ndet in

    Array.init ndet
      (fun i -> let ki = det.(i) in
        Printf.eprintf "%8d / %8d\r%!" i ndet;
        let j = ref 1 in
        Ds.determinant_stream det_space
        |> Stream.iter (fun kj -> v.{!j} <- f ki kj ; incr j);
        Vector.sparse_of_vec v)
    |> Matrix.sparse_of_vector_array
  )


(* Create a matrix using the fact that the determinant space is made of
   the outer product of spindeterminants.  *)
let create_matrix_spin f det_space = 
  lazy (
    let ndet = Ds.size det_space in
    let a, b = 
      match Ds.determinants det_space with
      | Ds.Spin (a,b) -> (a,b)
      | _ -> assert false
    in
    let n_beta = Array.length b in


    (** Array of (list of singles, list of doubles) in the beta spin *)
    let degree_bb = 
      Array.map (fun det_i ->
          let deg = Spindeterminant.degree det_i in
          let doubles =
            Array.mapi (fun i det_j -> 
                let d = deg det_j in
                if d < 3 then
                  Some (i,d,det_j)
                else
                  None
              ) b
            |> Array.to_list
            |> Util.list_some
          in
          let singles = 
            List.filter (fun (i,d,det_j) -> d < 2) doubles
            |> List.map (fun (i,_,det_j) -> (i,det_j))
          in
          let doubles = 
            List.map (fun (i,_,det_j) -> (i,det_j)) doubles
          in
          (singles, doubles)
        ) b
    in
    let a = Array.to_list a
    and b = Array.to_list b
    in

    let task (i,i_alfa) = 
        let result = Array.init n_beta (fun _ -> []) in
        (** Update function when ki and kj are connected *)
        let update i j ki kj =
          let x = f ki kj in
          if abs_float x > Constants.epsilon then
            result.(i) <- (j, x) :: result.(i) ;
        in
        let j = ref 1 in
        let deg_a = Spindeterminant.degree i_alfa in
        List.iter (fun j_alfa ->
            let degree_a = deg_a j_alfa in
            begin
              match degree_a with
              | 2 ->
                let i' = ref 0 in
                List.iteri (fun ib i_beta ->
                    let ki = Determinant.of_spindeterminants i_alfa i_beta in
                    let kj = Determinant.of_spindeterminants j_alfa i_beta in
                    update !i' (ib + !j) ki kj;
                    incr i';
                  ) b;
              | 1 -> 
                let i' = ref 0 in
                List.iteri (fun ib i_beta ->
                    let ki = Determinant.of_spindeterminants i_alfa i_beta in
                    let singles, _ = degree_bb.(ib) in
                    List.iter (fun (j', j_beta) ->
                        let kj = Determinant.of_spindeterminants j_alfa j_beta in
                        update !i' (j' + !j) ki kj
                      ) singles;
                    incr i';
                  ) b;
              | 0 ->
                let i' = ref 0 in
                List.iteri (fun ib i_beta ->
                    let ki = Determinant.of_spindeterminants i_alfa i_beta in
                    let _singles, doubles = degree_bb.(ib) in
                    List.iter (fun (j', j_beta) ->
                        let kj = Determinant.of_spindeterminants j_alfa j_beta in
                        update !i' (j' + !j) ki kj
                      ) doubles;
                    incr i';
                  ) b;
              | _ -> ();
            end;
            j := !j + n_beta
          ) a;
          let r = 
            Array.map (fun l ->
                List.rev l
                |> Vector.sparse_of_assoc_list ndet
            ) result 
          in (i,r)
    in

    let result =
      if Parallel.master then
        Array.init ndet (fun _ -> Vector.sparse_of_assoc_list ndet [])
      else
        Array.init ndet (fun _ -> Vector.sparse_of_assoc_list ndet [])
    in

    List.mapi (fun i i_alfa -> i*n_beta, i_alfa) a
    |> Stream.of_list
    |> Farm.run ~ordered:false ~f:task
    |> Stream.iter (fun (k, r) ->
        Array.iteri (fun j r_j -> result.(k+j) <- r_j) r;
        Printf.eprintf "%8d / %8d\r%!" (k+1) ndet;
      ) ;
    Matrix.sparse_of_vector_array result
  )


let make ?(n_states=1) det_space = 

  let m_H = 

    let mo_basis = Ds.mo_basis det_space in

    (* While in a sequential region, initiate the parallel
       4-idx transformation *)
    ignore @@ MOBasis.two_e_ints mo_basis;

    let f = 
      match Ds.determinants det_space with
      | Ds.Arbitrary _ -> create_matrix_arbitrary
      | Ds.Spin      _ -> create_matrix_spin
    in
    f (fun ki kj -> h_ij mo_basis ki kj) det_space 
  in

  let m_S2 =
    let f = 
      match Ds.determinants det_space with
      | Ds.Arbitrary _ -> create_matrix_arbitrary
      | Ds.Spin      _ -> create_matrix_spin
    in
    f (fun ki kj -> CIMatrixElement.make_s2 ki kj) det_space 
  in

  let eigensystem = lazy (
    let m_H =
      Lazy.force m_H
    in
    let diagonal =
      Vec.init (Matrix.dim1 m_H) (fun i -> Matrix.get m_H i i)
    in
    let matrix_prod psi = 
      Matrix.mm ~transa:`T m_H psi
    in
    Davidson.make ~n_states diagonal matrix_prod
  )
  in
  { det_space ; m_H ; m_S2 ; eigensystem ; n_states }
FCI OK 2019-02-22 00:18:32 +01:00			`open Lacaml.D`

S2 is programmed in CI 2019-02-22 19:19:11 +01:00			`module Ds = Determinant_space`
FCI OK 2019-02-22 00:18:32 +01:00
			`type t =`
			`{`
S2 is programmed in CI 2019-02-22 19:19:11 +01:00			`det_space : Ds.t ;`
Davidson with sparse matrix 2019-02-28 12:30:20 +01:00			`m_H : Matrix.t lazy_t ;`
			`m_S2 : Matrix.t lazy_t ;`
FCI OK 2019-02-22 00:18:32 +01:00			`eigensystem : (Mat.t * Vec.t) lazy_t;`
spin fci 2019-02-28 16:55:50 +01:00			`n_states : int;`
FCI OK 2019-02-22 00:18:32 +01:00			`}`

			`let det_space t = t.det_space`

spin fci 2019-02-28 16:55:50 +01:00			`let n_states t = t.n_states`

ROHF OK 2019-02-26 11:58:53 +01:00			`let m_H t = Lazy.force t.m_H`
FCI OK 2019-02-22 00:18:32 +01:00
ROHF OK 2019-02-26 11:58:53 +01:00			`let m_S2 t = Lazy.force t.m_S2`
S2 is programmed in CI 2019-02-22 19:19:11 +01:00
FCI OK 2019-02-22 00:18:32 +01:00			`let eigensystem t = Lazy.force t.eigensystem`

			`let eigenvectors t =`
			`let (x,_) = eigensystem t in x`

			`let eigenvalues t =`
			`let (_,x) = eigensystem t in x`

S2 is programmed in CI 2019-02-22 19:19:11 +01:00			`let h_integrals mo_basis =`
FCI OK 2019-02-22 00:18:32 +01:00			`let one_e_ints = MOBasis.one_e_ints mo_basis`
			`and two_e_ints = MOBasis.two_e_ints mo_basis`
			`in`
S2 is programmed in CI 2019-02-22 19:19:11 +01:00			`( (fun i j _ -> one_e_ints.{i,j}),`
			`(fun i j k l s s' ->`
			`if s' = Spin.other s then`
			`ERI.get_phys two_e_ints i j k l`
			`else`
			`(ERI.get_phys two_e_ints i j k l) -.`
			`(ERI.get_phys two_e_ints i j l k)`
			`) )`



			`let h_ij mo_basis ki kj =`
			`let integrals =`
			`List.map (fun f -> f mo_basis)`
			`[ h_integrals ]`
			`in`
			`CIMatrixElement.make integrals ki kj`
			`\|> List.hd`

FCI OK 2019-02-22 00:18:32 +01:00
Cleaning 2019-02-28 19:37:54 +01:00			`let create_matrix_arbitrary f det_space =`
			`lazy (`
			`let det =`
			`match Ds.determinants det_space with`
			`\| Ds.Arbitrary a -> a`
			`\| _ -> assert false`
			`in`
FCI OK 2019-02-22 00:18:32 +01:00
Cleaning 2019-02-28 19:37:54 +01:00			`let ndet = Ds.size det_space in`
spin fci 2019-02-28 16:55:50 +01:00
Cleaning 2019-02-28 19:37:54 +01:00			`let v = Vec.make0 ndet in`

			`Array.init ndet`
			`(fun i -> let ki = det.(i) in`
spin fci 2019-02-28 16:55:50 +01:00			`Printf.eprintf "%8d / %8d\r%!" i ndet;`
			`let j = ref 1 in`
			`Ds.determinant_stream det_space`
Cleaning 2019-02-28 19:37:54 +01:00			`\|> Stream.iter (fun kj -> v.{!j} <- f ki kj ; incr j);`
spin fci 2019-02-28 16:55:50 +01:00			`Vector.sparse_of_vec v)`
Cleaning 2019-02-28 19:37:54 +01:00			`\|> Matrix.sparse_of_vector_array`
			`)`


			`(* Create a matrix using the fact that the determinant space is made of`
			`the outer product of spindeterminants. *)`
			`let create_matrix_spin f det_space =`
			`lazy (`
			`let ndet = Ds.size det_space in`
			`let a, b =`
			`match Ds.determinants det_space with`
			`\| Ds.Spin (a,b) -> (a,b)`
			`\| _ -> assert false`
			`in`
			`let n_beta = Array.length b in`

spin fci 2019-02-28 16:55:50 +01:00
Cleaning 2019-02-28 19:37:54 +01:00			`(** Array of (list of singles, list of doubles) in the beta spin *)`
			`let degree_bb =`
			`Array.map (fun det_i ->`
Accelerated CI 2019-02-28 18:18:26 +01:00			`let deg = Spindeterminant.degree det_i in`
			`let doubles =`
			`Array.mapi (fun i det_j ->`
Cleaning 2019-02-28 19:37:54 +01:00			`let d = deg det_j in`
			`if d < 3 then`
			`Some (i,d,det_j)`
			`else`
			`None`
Accelerated CI 2019-02-28 18:18:26 +01:00			`) b`
			`\|> Array.to_list`
			`\|> Util.list_some`
			`in`
			`let singles =`
			`List.filter (fun (i,d,det_j) -> d < 2) doubles`
			`\|> List.map (fun (i,_,det_j) -> (i,det_j))`
			`in`
			`let doubles =`
			`List.map (fun (i,_,det_j) -> (i,det_j)) doubles`
			`in`
			`(singles, doubles)`
			`) b`
Cleaning 2019-02-28 19:37:54 +01:00			`in`
			`let a = Array.to_list a`
			`and b = Array.to_list b`
			`in`
Parallelized FCI and 4idx 2019-03-02 18:50:12 +01:00
			`let task (i,i_alfa) =`
Reduced memory in fci 2019-03-02 17:05:15 +01:00			`let result = Array.init n_beta (fun _ -> []) in`
			`(** Update function when ki and kj are connected *)`
			`let update i j ki kj =`
			`let x = f ki kj in`
			`if abs_float x > Constants.epsilon then`
			`result.(i) <- (j, x) :: result.(i) ;`
			`in`
Cleaning 2019-02-28 19:37:54 +01:00			`let j = ref 1 in`
			`let deg_a = Spindeterminant.degree i_alfa in`
			`List.iter (fun j_alfa ->`
			`let degree_a = deg_a j_alfa in`
			`begin`
			`match degree_a with`
			`\| 2 ->`
Reduced memory in fci 2019-03-02 17:05:15 +01:00			`let i' = ref 0 in`
Cleaning 2019-02-28 19:37:54 +01:00			`List.iteri (fun ib i_beta ->`
			`let ki = Determinant.of_spindeterminants i_alfa i_beta in`
			`let kj = Determinant.of_spindeterminants j_alfa i_beta in`
			`update !i' (ib + !j) ki kj;`
			`incr i';`
			`) b;`
			`\| 1 ->`
Reduced memory in fci 2019-03-02 17:05:15 +01:00			`let i' = ref 0 in`
Cleaning 2019-02-28 19:37:54 +01:00			`List.iteri (fun ib i_beta ->`
			`let ki = Determinant.of_spindeterminants i_alfa i_beta in`
			`let singles, _ = degree_bb.(ib) in`
			`List.iter (fun (j', j_beta) ->`
			`let kj = Determinant.of_spindeterminants j_alfa j_beta in`
			`update !i' (j' + !j) ki kj`
			`) singles;`
			`incr i';`
			`) b;`
			`\| 0 ->`
Reduced memory in fci 2019-03-02 17:05:15 +01:00			`let i' = ref 0 in`
Cleaning 2019-02-28 19:37:54 +01:00			`List.iteri (fun ib i_beta ->`
			`let ki = Determinant.of_spindeterminants i_alfa i_beta in`
			`let _singles, doubles = degree_bb.(ib) in`
			`List.iter (fun (j', j_beta) ->`
			`let kj = Determinant.of_spindeterminants j_alfa j_beta in`
			`update !i' (j' + !j) ki kj`
			`) doubles;`
			`incr i';`
			`) b;`
			`\| _ -> ();`
			`end;`
			`j := !j + n_beta`
			`) a;`
Parallelized FCI and 4idx 2019-03-02 18:50:12 +01:00			`let r =`
			`Array.map (fun l ->`
			`List.rev l`
			`\|> Vector.sparse_of_assoc_list ndet`
			`) result`
			`in (i,r)`
Reduced memory in fci 2019-03-02 17:05:15 +01:00			`in`
Parallelized FCI and 4idx 2019-03-02 18:50:12 +01:00
Reduced memory in fci 2019-03-02 17:05:15 +01:00			`let result =`
Parallelized FCI and 4idx 2019-03-02 18:50:12 +01:00			`if Parallel.master then`
			`Array.init ndet (fun _ -> Vector.sparse_of_assoc_list ndet [])`
			`else`
			`Array.init ndet (fun _ -> Vector.sparse_of_assoc_list ndet [])`
Reduced memory in fci 2019-03-02 17:05:15 +01:00			`in`
Parallelized FCI and 4idx 2019-03-02 18:50:12 +01:00
			`List.mapi (fun i i_alfa -> i*n_beta, i_alfa) a`
			`\|> Stream.of_list`
			`\|> Farm.run ~ordered:false ~f:task`
			`\|> Stream.iter (fun (k, r) ->`
			`Array.iteri (fun j r_j -> result.(k+j) <- r_j) r;`
			`Printf.eprintf "%8d / %8d\r%!" (k+1) ndet;`
			`) ;`
Reduced memory in fci 2019-03-02 17:05:15 +01:00			`Matrix.sparse_of_vector_array result`
Cleaning 2019-02-28 19:37:54 +01:00			`)`



			`let make ?(n_states=1) det_space =`
spin fci 2019-02-28 16:55:50 +01:00
Cleaning 2019-02-28 19:37:54 +01:00			`let m_H =`
Parallelized FCI and 4idx 2019-03-02 18:50:12 +01:00
Cleaning 2019-02-28 19:37:54 +01:00			`let mo_basis = Ds.mo_basis det_space in`
Parallelized FCI and 4idx 2019-03-02 18:50:12 +01:00
			`(* While in a sequential region, initiate the parallel`
			`4-idx transformation *)`
			`ignore @@ MOBasis.two_e_ints mo_basis;`

Cleaning 2019-02-28 19:37:54 +01:00			`let f =`
			`match Ds.determinants det_space with`
			`\| Ds.Arbitrary _ -> create_matrix_arbitrary`
			`\| Ds.Spin _ -> create_matrix_spin`
			`in`
			`f (fun ki kj -> h_ij mo_basis ki kj) det_space`
Using less memory 2019-02-28 12:50:42 +01:00			`in`
spin fci 2019-02-28 16:55:50 +01:00
Cleaning 2019-02-28 19:37:54 +01:00			`let m_S2 =`
			`let f =`
			`match Ds.determinants det_space with`
			`\| Ds.Arbitrary _ -> create_matrix_arbitrary`
			`\| Ds.Spin _ -> create_matrix_spin`
			`in`
			`f (fun ki kj -> CIMatrixElement.make_s2 ki kj) det_space`
FCI OK 2019-02-22 00:18:32 +01:00			`in`
spin fci 2019-02-28 16:55:50 +01:00
FCI OK 2019-02-22 00:18:32 +01:00			`let eigensystem = lazy (`
spin fci 2019-02-28 16:55:50 +01:00			`let m_H =`
			`Lazy.force m_H`
			`in`
Davidson with sparse matrix 2019-02-28 12:30:20 +01:00			`let diagonal =`
			`Vec.init (Matrix.dim1 m_H) (fun i -> Matrix.get m_H i i)`
			`in`
			`let matrix_prod psi =`
			Matrix.mm ~transa:`T m_H psi
			`in`
spin fci 2019-02-28 16:55:50 +01:00			`Davidson.make ~n_states diagonal matrix_prod`
FCI OK 2019-02-22 00:18:32 +01:00			`)`
			`in`
spin fci 2019-02-28 16:55:50 +01:00			`{ det_space ; m_H ; m_S2 ; eigensystem ; n_states }`
FCI OK 2019-02-22 00:18:32 +01:00
Davidson works 2019-02-27 14:56:59 +01:00