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QCaml/Basis/ERI.ml
2018-06-29 16:04:40 +02:00

382 lines
12 KiB
OCaml

(** Electron-electron repulsion integrals *)
open Util
open Constants
include FourIdxStorage
module Am = AngularMomentum
module As = AtomicShell
module Asp = AtomicShellPair
module Bs = Basis
module Cs = ContractedShell
module Csp = ContractedShellPair
module Cspc = ContractedShellPairCouple
module Fis = FourIdxStorage
let cutoff = integrals_cutoff
(** (00|00)^m : Fundamental electron repulsion integral
$ \int \int \phi_p(r1) 1/r_{12} \phi_q(r2) dr_1 dr_2 $
maxm : Maximum total angular momentum
expo_pq_inv : $1./p + 1./q$ where $p$ and $q$ are the exponents of
$\phi_p$ and $\phi_q$
norm_pq_sq : square of the distance between the centers of $\phi_p$
and $\phi_q$
*)
let zero_m ~maxm ~expo_pq_inv ~norm_pq_sq =
assert (expo_pq_inv <> 0.);
let norm_pq_sq =
if norm_pq_sq > integrals_cutoff then norm_pq_sq else 0.
in
let exp_pq = 1. /. expo_pq_inv in
let t = norm_pq_sq *. exp_pq in
let f = two_over_sq_pi *. (sqrt exp_pq) in
let result = boys_function ~maxm t in
let rec aux accu k = function
| 0 -> result.(k) <- result.(k) *. accu
| l ->
begin
result.(k) <- result.(k) *. accu;
let new_accu = -. accu *. exp_pq in
aux new_accu (k+1) (l-1)
end
in
aux f 0 maxm;
result
let class_of_contracted_shell_pair_couple shell_pair_couple =
let shell_p = Cspc.shell_pair_p shell_pair_couple
and shell_q = Cspc.shell_pair_q shell_pair_couple
in
if Array.length (Csp.shell_pairs shell_p) + (Array.length (Csp.shell_pairs shell_q)) < 4 then
TwoElectronRR.contracted_class_shell_pair_couple ~zero_m shell_pair_couple
else
TwoElectronRRVectorized.contracted_class_shell_pairs ~zero_m shell_p shell_q
let filter_contracted_shell_pairs ?(cutoff=integrals_cutoff) shell_pairs =
List.map (fun pair ->
match Cspc.make ~cutoff pair pair with
| Some cspc ->
let cls = class_of_contracted_shell_pair_couple cspc in
(pair, Zmap.fold (fun key value accu -> max (abs_float value) accu) cls 0. )
(* TODO \sum_k |coef_k * integral_k| *)
| None -> (pair, -1.)
) shell_pairs
|> List.filter (fun (_, schwartz_p_max) -> schwartz_p_max >= cutoff)
|> List.map fst
(* TODO
let filter_contracted_shell_pair_couples ?(cutoff=integrals_cutoff) shell_pair_couples =
List.map (fun pair ->
let cls =
class_of_contracted_shell_pairs pair pair
in
(pair, Zmap.fold (fun key value accu -> max (abs_float value) accu) cls 0. )
) shell_pairs
|> List.filter (fun (_, schwartz_p_max) -> schwartz_p_max >= cutoff)
|> List.map fst
*)
let store_class ?(cutoff=integrals_cutoff) data contracted_shell_pair_couple cls =
let to_powers x =
let open Zkey in
match to_powers x with
| Three x -> x
| _ -> assert false
in
let shell_p = Cspc.shell_pair_p contracted_shell_pair_couple
and shell_q = Cspc.shell_pair_q contracted_shell_pair_couple
in
Array.iteri (fun i_c powers_i ->
let i_c = Cs.index (Csp.shell_a shell_p) + i_c + 1 in
let xi = to_powers powers_i in
Array.iteri (fun j_c powers_j ->
let j_c = Cs.index (Csp.shell_b shell_p) + j_c + 1 in
let xj = to_powers powers_j in
Array.iteri (fun k_c powers_k ->
let k_c = Cs.index (Csp.shell_a shell_q) + k_c + 1 in
let xk = to_powers powers_k in
Array.iteri (fun l_c powers_l ->
let l_c = Cs.index (Csp.shell_b shell_q) + l_c + 1 in
let xl = to_powers powers_l in
let key = Zkey.of_powers_twelve xi xj xk xl in
let value = Zmap.find cls key in
set_chem data i_c j_c k_c l_c value
) (Cs.zkey_array (Csp.shell_b shell_q))
) (Cs.zkey_array (Csp.shell_a shell_q))
) (Cs.zkey_array (Csp.shell_b shell_p))
) (Cs.zkey_array (Csp.shell_a shell_p))
let of_basis basis =
let n = Bs.size basis
and shell = Bs.contracted_shells basis
in
let eri_array =
Fis.create ~size:n `Dense
(*
Fis.create ~size:n `Sparse
*)
in
let t0 = Unix.gettimeofday () in
let shell_pairs =
Csp.of_contracted_shell_array shell
|> filter_contracted_shell_pairs ~cutoff
in
Printf.printf "%d significant shell pairs computed in %f seconds\n"
(List.length shell_pairs) (Unix.gettimeofday () -. t0);
let t0 = Unix.gettimeofday () in
let ishell = ref 0 in
List.iter (fun shell_p ->
let () =
if (Cs.index (Csp.shell_a shell_p) > !ishell) then
(ishell := Cs.index (Csp.shell_a shell_p) ; print_int !ishell ; print_newline ())
in
let sp =
Csp.shell_pairs shell_p
in
try
List.iter (fun shell_q ->
let () =
if Cs.index (Csp.shell_a shell_q) >
Cs.index (Csp.shell_a shell_p) then
raise Exit
in
let sq = Csp.shell_pairs shell_q in
let cspc =
if Array.length sp < Array.length sq then
Cspc.make ~cutoff shell_p shell_q
else
Cspc.make ~cutoff shell_q shell_p
in
match cspc with
| Some cspc ->
let cls =
class_of_contracted_shell_pair_couple cspc
in
store_class ~cutoff eri_array cspc cls
| None -> ()
) shell_pairs
with Exit -> ()
) shell_pairs ;
Printf.printf "Computed ERIs in %f seconds\n%!" (Unix.gettimeofday () -. t0);
eri_array
(*
let of_basis_parallel basis =
let store_class ?(cutoff=integrals_cutoff) push_socket contracted_shell_pair_couple cls =
let to_powers x =
let open Zkey in
match to_powers x with
| Three x -> x
| _ -> assert false
in
let shell_p = Cspc.shell_pair_p contracted_shell_pair_couple
and shell_q = Cspc.shell_pair_q contracted_shell_pair_couple
in
let msg = ref [] in
Array.iteri (fun i_c powers_i ->
let i_c = Cs.index (Csp.shell_a shell_p) + i_c + 1 in
let xi = to_powers powers_i in
Array.iteri (fun j_c powers_j ->
let j_c = Cs.index (Csp.shell_b shell_p) + j_c + 1 in
let xj = to_powers powers_j in
Array.iteri (fun k_c powers_k ->
let k_c = Cs.index (Csp.shell_a shell_q) + k_c + 1 in
let xk = to_powers powers_k in
Array.iteri (fun l_c powers_l ->
let l_c = Cs.index (Csp.shell_b shell_q) + l_c + 1 in
let xl = to_powers powers_l in
let key = Zkey.of_powers_twelve xi xj xk xl in
let value = Zmap.find cls key in
msg := (i_c,j_c,k_c,l_c,value) :: !msg;
) (Cs.zkey_array (Csp.shell_b shell_q))
) (Cs.zkey_array (Csp.shell_a shell_q))
) (Cs.zkey_array (Csp.shell_b shell_p))
) (Cs.zkey_array (Csp.shell_a shell_p));
Zmq.Socket.send_all push_socket ["0" ; Bytes.to_string (Marshal.to_bytes !msg []) ]
in
let n = Bs.size basis
and shell = Bs.contracted_shells basis
in
let eri_array =
Fis.create ~size:n `Dense
(*
Fis.create ~size:n `Sparse
*)
in
let t0 = Unix.gettimeofday () in
let shell_pairs =
Csp.of_contracted_shell_array shell
|> filter_contracted_shell_pairs ~cutoff
in
Printf.printf "%d significant shell pairs computed in %f seconds\n%!"
(List.length shell_pairs) (Unix.gettimeofday () -. t0);
let t0 = Unix.gettimeofday () in
let ishell = ref 0 in
let zmq_port = 12345 in
begin
match Unix.fork () with
| 0 -> Printf.printf "pouet\n%!"
| pid -> Printf.printf "coucou\n%!"
end;
begin
match Unix.fork () with
| 0 -> begin
let zmq_addr = Printf.sprintf "tcp://localhost:%d" zmq_port in
let zmq = ref None in
Printf.printf "PID %d OK\n%!" 0;
Parmap.pariter ~chunksize:1
~init:(fun rank ->
let zmq_context =
Zmq.Context.create ()
in
let push_socket =
Zmq.Socket.create zmq_context Zmq.Socket.push
in
Printf.printf "Init %d OK\n%!" rank;
Zmq.Socket.connect push_socket zmq_addr;
zmq := Some (zmq_context, push_socket)
)
(fun shell_p ->
let push_socket =
match !zmq with
| Some (_, push_socket) -> push_socket
| None -> failwith "ZMQ"
in
let () =
if (Cs.index (Csp.shell_a shell_p) > !ishell) then
(ishell := Cs.index (Csp.shell_a shell_p) ; print_int !ishell ; print_newline ())
in
let sp =
Csp.shell_pairs shell_p
in
try
List.iter (fun shell_q ->
let () =
if Cs.index (Csp.shell_a shell_q) >
Cs.index (Csp.shell_a shell_p) then
raise Exit
in
let sq = Csp.shell_pairs shell_q in
let cspc =
if Array.length sp < Array.length sq then
Cspc.make ~cutoff shell_p shell_q
else
Cspc.make ~cutoff shell_q shell_p
in
match cspc with
| Some cspc -> let cls = class_of_contracted_shell_pair_couple cspc in
store_class ~cutoff push_socket cspc cls
| None -> ()
) shell_pairs
with Exit -> ()
) (Parmap.L shell_pairs)
~finalize:(fun _ ->
let zmq_context, push_socket =
match !zmq with
| Some (zmq_context, push_socket) -> zmq_context, push_socket
| None -> failwith "ZMQ"
in
Zmq.Socket.close push_socket;
Zmq.Context.terminate zmq_context
);
let zmq_context =
Zmq.Context.create ()
in
let push_socket = Zmq.Socket.create zmq_context Zmq.Socket.push in
Zmq.Socket.connect push_socket zmq_addr;
Zmq.Socket.send_all push_socket [ "1" ; ""];
Zmq.Socket.close push_socket;
Zmq.Context.terminate zmq_context;
ignore @@ exit 0
end
| pid -> begin
Printf.printf "PID %d OK\n%!" pid;
let zmq_addr = Printf.sprintf "tcp://*:%d" zmq_port in
let zmq_context =
Zmq.Context.create ()
in
let pull_socket =
Zmq.Socket.create zmq_context Zmq.Socket.pull
in
Zmq.Socket.bind pull_socket zmq_addr;
try
while true do
match Zmq.Socket.recv_all pull_socket with
| "0" :: rest :: [] ->
List.iter (fun (i,j,k,l,value) ->
set_chem eri_array i j k l value) (Marshal.from_bytes (Bytes.of_string rest) 0)
| "1" :: _ -> raise Exit
| _ -> invalid_arg "ERI"
done
with Exit -> ();
Zmq.Socket.close pull_socket;
Zmq.Context.terminate zmq_context;
ignore (Unix.wait ())
end
end;
Printf.printf "Computed ERIs in %f seconds\n%!" (Unix.gettimeofday () -. t0);
eri_array
*)