Added determinant_space

2024-11-06 22:23:42 +01:00 · 2024-06-24 17:44:42 +02:00 · 2024-06-24 17:44:42 +02:00 · a9c5fd16a9
commit a9c5fd16a9
parent 3694f8695c
4 changed files with 465 additions and 1 deletions
--- a/ci/lib/determinant_space.ml
+++ b/ci/lib/determinant_space.ml
@ -0,0 +1,343 @@
 (** Data structures for storing the determinant space.
 If the space is built as the outer product of all {% $\alpha$ %} and {%
 $\beta$ %} determinants, the storage is of type [Spin]. It is sufficient
 to have the arrays of {% $\alpha$ %} and {% $\beta$ %} spindeterminants.
 Otherwise, the space is of type [Arbitrary].
 *)
 open Common
 open Linear_algebra
 type arbitrary_space =
  {
    det         : int array array ;
    det_alfa    : Spindeterminant.t array ;
    det_beta    : Spindeterminant.t array ;
    index_start : int array;
  }
 type determinant_storage =
  | Arbitrary of arbitrary_space
  | Spin      of (Spindeterminant.t array * Spindeterminant.t array)
 type t =
  {
    n_alfa       : int ;
    n_beta       : int ;
    mo_class     : Mo.Class.t ;
    mo_basis     : Mo.Basis.t ;
    determinants : determinant_storage;
  }
 module Ss = Spindeterminant_space
 module Electrons = Particles.Electrons
 module Nuclei = Particles.Nuclei
 let n_alfa   t = t.n_alfa
 let n_beta   t = t.n_beta
 let mo_class t = t.mo_class
 let mo_basis t = t.mo_basis
 let size t =
  match t.determinants with
  | Spin (a,b)  ->  (Array.length a) * (Array.length b)
  | Arbitrary a ->
      let ndet_a = Array.length a.det_alfa in
      a.index_start.(ndet_a)
 let determinant_stream t =
  match t.determinants with
  | Arbitrary a ->
    let det_beta = a.det_beta
    and det_alfa = a.det_alfa
    and det = a.det in
    let n_alfa = Array.length det_alfa in
    let alfa = ref det_alfa.(0)
    and det_i_alfa = ref det.(0) in
    let i_alfa = ref 0
    and k_beta = ref 0
    in
    Stream.from (fun _ ->
        if !i_alfa = n_alfa then None else
          begin
            let i_beta = (!det_i_alfa).(!k_beta) in
            let beta = det_beta.(i_beta) in
            let result =
              Some (Determinant.of_spindeterminants (!alfa) beta)
            in
            incr k_beta;
            if !k_beta = Array.length !det_i_alfa then
              begin
                k_beta := 0;
                incr i_alfa;
                if !i_alfa < n_alfa then
                  begin
                    alfa := det_alfa.(!i_alfa);
                    det_i_alfa := det.(!i_alfa)
                  end
              end;
            result
          end
        )
  | Spin (a,b) ->
    let na = Array.length a
    and nb = Array.length b in
    let i = ref 0
    and j = ref 0 in
    Stream.from (fun _ ->
        if !j < nb then
          let result =
            Determinant.of_spindeterminants a.(!i) b.(!j)
          in
          incr i;
          if !i = na then (i := 0 ; incr j);
          Some result
        else
          None)
 let determinants t = t.determinants
 let determinants_array t =
  let s = determinant_stream t in
  Array.init (size t) (fun _ -> Stream.next s)
 (*
 let determinant t i =
  let alfa, beta =
    match t.determinants with
    | Arbitrary a ->
      let i_alfa =
        let index_start = a.index_start in
        let rec loop i_alfa =
          if index_start.(i_alfa) <= i then
            (loop [@tailcall]) (i_alfa+1)
          else i_alfa
        in loop 0
      in
      let i_beta = i - a.index_start.(i_alfa) in
      let alfa = a.det_alfa.(i_alfa) in
      let beta = a.det_beta.(i_beta) in
      alfa, beta
    | Spin (a,b) ->
      let nb = Array.length b in
      let k = i / nb in
      let j = i - k * nb in
      a.(j), b.(k)
    in
    Determinant.of_spindeterminants alfa beta
 *)
 let fock_diag det_space det =
  let alfa_list =
    Determinant.alfa det
    |> Spindeterminant.to_list
  in
  let beta_list =
    Determinant.beta det
    |> Spindeterminant.to_list
  in
  let mo_basis = mo_basis det_space in
  let mo_num = Mo.Basis.size mo_basis in
  let one_e_ints  = Mo.Basis.one_e_ints mo_basis
  and two_e_ints  = Mo.Basis.two_e_ints mo_basis
  in
  let two_e i j k l = Four_idx_storage.get_phys two_e_ints i j k l in
  let build_array list1 list2 =
    let result = Array.make (mo_num+1) 0. in
    (* Occupied *)
    List.iter (fun i ->
        let x = one_e_ints%:(i,i) in
        result.(i) <- result.(i) +. x;
        result.(0) <- result.(0) +. x;
        List.iter (fun j ->
            if j <> i then
              begin
                let x = two_e i j i j -. two_e i j j i in
                result.(i) <- result.(i) +. x;
                result.(0) <- result.(0) +. 0.5 *. x;
              end
          ) list1;
        List.iter (fun j ->
              begin
                let x = two_e i j i j in
                result.(i) <- result.(i) +. x;
                result.(0) <- result.(0) +. 0.5 *. x;
              end
          ) list2;
      ) list1;
    (* Virtuals*)
    List.iter (fun i ->
        if result.(i) = 0. then
          begin
            let x = one_e_ints%:(i,i) in
            result.(i) <- result.(i) +. x;
            List.iter (fun j ->
                let x = two_e i j i j -. two_e i j j i in
                result.(i) <- result.(i) +. x;
              ) list1;
            List.iter (fun j ->
                  begin
                    let x = two_e i j i j in
                    result.(i) <- result.(i) +. x;
                  end
              ) list2;
          end
     ) (Util.list_range 1 mo_num);
     result
  in
  let alfa, beta =
    build_array alfa_list beta_list,
    build_array beta_list alfa_list
  in
  let e = alfa.(0) +. beta.(0) in
  alfa.(0) <- e;
  beta.(0) <- e;
  alfa, beta
 let spin_of_mo_basis mo_basis f =
  let s = Mo.Basis.simulation mo_basis in
  let e = Simulation.electrons s in
  let n_alfa = Electrons.n_alfa e
  and n_beta = Electrons.n_beta e in
  let det_a = f n_alfa
  and det_b = f n_beta
  in
  let mo_class = Ss.mo_class det_a in
  let determinants =
    let det_alfa = Ss.spin_determinants det_a
    and det_beta = Ss.spin_determinants det_b
    in
    let n_det_beta = Array.length det_beta in
    let n_det_alfa = Array.length det_alfa in
    let ndet = n_det_alfa * n_det_beta in
    Format.printf "Number of determinants : %d %d %d\n%!"
        n_det_alfa n_det_beta ndet;
    Spin (det_alfa, det_beta)
  in
  { n_alfa ; n_beta ; mo_class ; mo_basis ; determinants }
 (*
 let arbitrary_of_mo_basis mo_basis f =
  let s = Mo.Basis.simulation mo_basis in
  let e = Simulation.electrons s in
  let n_alfa = Electrons.n_alfa e
  and n_beta = Electrons.n_beta e in
  let det_a = f n_alfa
  and det_b = f n_beta
  in
  let mo_class = Ss.mo_class det_a in
  let determinants =
    let det_alfa = Ss.spin_determinants det_a
    and det_beta = Ss.spin_determinants det_b
    in
    let n_det_beta = Array.length det_beta in
    let n_det_alfa = Array.length det_alfa in
    let det = Array.make n_det_alfa
        (Array.init n_det_beta (fun i -> i))
    in
    let index_start = Array.init (n_det_alfa+1) (fun i -> i*n_det_beta) in
    let ndet = (index_start.(n_det_alfa)) in
    Format.printf "Number of determinants : %d %d %d\n%!"
        n_det_alfa n_det_beta ndet;
    Arbitrary {
      det_alfa ; det_beta ; det ; index_start
    }
  in
  { n_alfa ; n_beta ; mo_class ; mo_basis ; determinants }
 *)
 let cas_of_mo_basis mo_basis ~frozen_core n m =
  let f n_alfa =
    Ss.cas_of_mo_basis mo_basis ~frozen_core n_alfa n m
  in
  spin_of_mo_basis mo_basis f
 let fci_of_mo_basis mo_basis ~frozen_core =
  let f n_alfa =
    Ss.fci_of_mo_basis mo_basis ~frozen_core n_alfa
  in
  spin_of_mo_basis mo_basis f
 let fci_f12_of_mo_basis mo_basis ~frozen_core mo_num =
  let s = Mo.Basis.simulation mo_basis in
  let e = Simulation.electrons s in
  let n_alfa = Electrons.n_alfa e
  and n_beta = Electrons.n_beta e in
  let n_core = Mo.Frozen_core.num_mos frozen_core in
  let n, m =
      (n_alfa + n_beta - n_core),
      (mo_num - n_core)
  in
  let f n_alfa =
    Ss.cas_of_mo_basis mo_basis ~frozen_core n_alfa n m
  in
  let r =
    spin_of_mo_basis mo_basis f
  in
  { r with mo_class =
    Mo.Class.to_list r.mo_class
    |> List.rev_map (fun i ->
      match i with
      | Mo.Class.Virtual i when i > mo_num -> Mo.Class.Auxiliary i
      | i -> i)
    |> List.rev
    |> Mo.Class.of_list }
 let cas_f12_of_mo_basis mo_basis ~frozen_core n m mo_num =
  let f n_alfa =
    Ss.cas_of_mo_basis mo_basis ~frozen_core n_alfa n m
  in
  let r =
    spin_of_mo_basis mo_basis f
  in
  { r with mo_class =
    Mo.Class.to_list r.mo_class
    |> List.rev_map (fun i ->
      match i with
      | Mo.Class.Virtual i when i > mo_num -> Mo.Class.Auxiliary i
      | i -> i)
    |> List.rev
    |> Mo.Class.of_list
    }
 let pp ppf t =
  Format.fprintf ppf "@[<v 2>[ ";
  let i = ref 0 in
  determinant_stream t
  |> Stream.iter (fun d -> Format.fprintf ppf "@[<v>@[%8d@]@;@[%a@]@]@;" !i
                    Determinant.pp  d; incr i) ;
  Format.fprintf ppf "]@]"
--- a/ci/lib/determinant_space.mli
+++ b/ci/lib/determinant_space.mli
@ -0,0 +1,74 @@
 (**
 The determinant space in which we solve the Schrodinger equation.
 *)
 type t
 type arbitrary_space =
  {
    det         : int array array ;
    det_alfa    : Spindeterminant.t array ;
    det_beta    : Spindeterminant.t array ;
    index_start : int array;
  }
 type determinant_storage =
  | Arbitrary of arbitrary_space
  | Spin      of (Spindeterminant.t array * Spindeterminant.t array)
 (** {1 Accessors} *)
 val n_alfa : t -> int
 (** Number of {% $\alpha$ %} electrons in the {% $\alpha$ %} MOs. *)
 val n_beta : t -> int
 (** Number of {% $\beta$ %} electrons in the {% $\beta$ %} MOs. *)
 val mo_class : t -> Mo.Class.t
 (** The MO classes used to generate the space. *)
 val mo_basis : t -> Mo.Basis.t
 (** The MO basis on which the determinants are expanded. *)
 val determinants : t -> determinant_storage
 (** All the determinants belonging to the space. *)
 val determinants_array : t -> Determinant.t array
 (** All the determinants belonging to the space. *)
 val determinant_stream : t -> Determinant.t Stream.t
 (** All the determinants belonging to the space, as a stream. *)
 val size : t -> int
 (** Size of the determinant space *)
 val fock_diag : t -> Determinant.t -> float array * float array
 (** Returns the diagonal of the {% $\alpha$ %} and {% $\beta$ %} Fock matrices.
    The zero elements contain the energy of the determinant.
 *)
 val fci_of_mo_basis : Mo.Basis.t -> frozen_core:Mo.Frozen_core.t -> t
 (** Creates a space of all possible ways to put [n_alfa] electrons in the {% $\alpha$ %}
    [Active] MOs and [n_beta] electrons in the {% $\beta$ %} [Active] MOs.
    All other MOs are untouched.
 *)
 val cas_of_mo_basis : Mo.Basis.t -> frozen_core:Mo.Frozen_core.t -> int -> int -> t
 (** Creates a CAS(n,m) space of determinants.  *)
 val fci_f12_of_mo_basis : Mo.Basis.t -> frozen_core:Mo.Frozen_core.t -> int -> t
 (** Creates the active space to perform a FCI-F12 with an
    auxiliary basis set. *)
 val cas_f12_of_mo_basis : Mo.Basis.t -> frozen_core:Mo.Frozen_core.t -> int -> int -> int -> t
 (** [cas_of_mo_basis mo_basis m n mo_num] Creates a CAS(n,m) space
  of determinants with an auxiliary basis set defined as the MOs from
  [mo_num+1] to [Mo.Basis.size mo_basis].
 *)
 (** {2 Printing} *)
 val pp : Format.formatter -> t -> unit
--- a/linear_algebra/lib/matrix.mli
+++ b/linear_algebra/lib/matrix.mli
@ -337,7 +337,7 @@ val sysv : b:('a,'b) t -> ('a,'a) t -> ('a,'b) t
 (** Solves %{ $AX=B$ %} when A is symmetric *)
 val (%:) : ('a,'b) t -> (int*int) -> float
-(** [t%.(i,j)] returns the element at i,j. *)
+(** [t%:(i,j)] returns the element at i,j. *)
 val set : ('a,'b) t -> int -> int -> float -> unit
 (** [set t i j v] sets the (i,j)-th element to v *)
--- a/top/install_printers.sh
+++ b/top/install_printers.sh
@ -0,0 +1,47 @@
 #!/bin/bash
 function print_modules ()
 {
    MODULES=$(grep "val pp " ../*/lib/*.mli \
                  | cut -d ":" -f 1 \
                  | sed 's|^../||' \
                  | sed 's|\.mli||' \
                  | sed 's|/lib/| |' \
                  | sed 's/[^ ]*/\u&/g' \
                  | sed 's| |.|' \
                  | grep -v Top.Install_printers )
    for MODULE in $MODULES ; do
        M=($(echo $MODULE | sed 's|\.| |'))
        if [[ "${M[0]}" == "${M[1]}" ]] ; then
            echo "    \"${M[1]}.pp\" ;"
        else
            echo "    \"${M[0]}.${M[1]}.pp\" ;"
        fi
    done
 }    
 cat << EOF
 let printers =
  [
 $(print_modules)
  ]
 let eval_exn str =
  let lexbuf = Lexing.from_string str in
  let phrase = !Toploop.parse_toplevel_phrase lexbuf in
  Toploop.execute_phrase false Format.err_formatter phrase
 let rec install_printers = function
  | [] -> eval_exn "#require \"lacaml.top\";;"
  | printer :: printers ->
      let cmd = Printf.sprintf "#install_printer %s;;" printer in
      eval_exn cmd && install_printers printers
 let () =
  if not (install_printers printers) then
    Format.eprintf "Problem installing QCaml-printers@."
 EOF