10
1
mirror of https://gitlab.com/scemama/QCaml.git synced 2024-11-18 12:03:40 +01:00
QCaml/linear_algebra/lib/matrix.ml

471 lines
11 KiB
OCaml

open Lacaml.D
open Common
type ('a, 'b) t = Mat.t
let dim1 t = Mat.dim1 t
let dim2 t = Mat.dim2 t
let out_of_place f t =
let result = lacpy t in
f result;
result
let relabel t = t
let make m n x = Mat.make m n x
let make0 m n = Mat.make0 m n
let create m n = Mat.create m n
let identity m = Mat.identity m
let fill_inplace t x = Mat.fill t x
let add a b = Mat.add a b
let sub a b = Mat.sub a b
let mul a b = Mat.mul a b
let div a b = Mat.div a b
let add_inplace ~c a b = ignore @@ Mat.add ~c a b
let sub_inplace ~c a b = ignore @@ Mat.sub ~c a b
let mul_inplace ~c a b = ignore @@ Mat.mul ~c a b
let div_inplace ~c a b = ignore @@ Mat.div ~c a b
let add_const_diag_inplace x a =
Mat.add_const_diag x a
let add_const_diag x a =
out_of_place (fun t -> add_const_diag_inplace x t) a
let add_const_inplace x a =
ignore @@ Mat.add_const x ~b:a a
let add_const x a =
Mat.add_const x a
external to_bigarray_inplace : ('a,'b) t -> (float, Stdlib.Bigarray.float64_elt, Stdlib.Bigarray.fortran_layout) Stdlib.Bigarray.Array2.t = "%identity"
external of_bigarray_inplace : (float, Stdlib.Bigarray.float64_elt, Stdlib.Bigarray.fortran_layout) Stdlib.Bigarray.Array2.t -> ('a,'b) t = "%identity"
let to_bigarray t = lacpy t
let of_bigarray t = lacpy t
let reshape_inplace m n a =
assert ( (dim1 a) * (dim2 a) = m*n);
let b =
to_bigarray a
|> Bigarray.genarray_of_array2
in
Bigarray.reshape_2 b m n
let reshape_vec_inplace m n v =
assert ( Vector.dim v = m*n);
let b =
Vector.to_bigarray_inplace v
|> Bigarray.genarray_of_array1
in
Bigarray.reshape_2 b m n
let col_inplace t j =
Mat.col t j
|> Vector.of_bigarray_inplace
let transpose t =
Mat.transpose_copy t
let transpose_inplace t =
let mat = to_bigarray_inplace t in
let d1 = dim1 t in
let d2 = dim2 t in
assert (d1 = d2);
for j=1 to d1 do
for i=1 to (j-1) do
let ij, ji = mat.{i,j}, mat.{j,i} in
mat.{i,j} <- ji;
mat.{j,i} <- ij
done;
done
let to_col_vecs t =
Mat.to_col_vecs t
|> Array.map Vector.of_bigarray_inplace
let to_col_vecs_list t =
Mat.to_col_vecs_list t
|> List.rev_map Vector.of_bigarray_inplace
|> List.rev
let detri_inplace t =
Mat.detri t
let detri t =
out_of_place detri_inplace t
let as_vec_inplace t =
Mat.as_vec t
|> Vector.of_bigarray_inplace
let as_vec t =
lacpy t
|> Mat.as_vec
|> Vector.of_bigarray_inplace
let random ?rnd_state ?(from= -. 1.0) ?(range=2.0) m n =
Mat.random ?rnd_state ~from ~range m n
let map_inplace f ~b a =
ignore @@ Mat.map f ~b a
let map f a =
Mat.map f a
let scale_inplace x t =
Mat.scal x t
let scale x t =
out_of_place (fun t -> scale_inplace x t) t
let of_diag v =
Vector.to_bigarray_inplace v
|> Mat.of_diag
let diag t =
Mat.copy_diag t
|> Vector.of_bigarray_inplace
let gemv_n_inplace ?m ?n ?(beta=0.) y ?(alpha=1.) ?(ar=1) ?(ac=1) t v =
let y = Vector.to_bigarray_inplace y in
let v = Vector.to_bigarray_inplace v in
ignore @@ gemv ?m ?n ~beta ~trans:`N ~y ~alpha ~ar ~ac t v
let gemv_t_inplace ?m ?n ?(beta=0.) y ?(alpha=1.) ?(ar=1) ?(ac=1) t v =
let y = Vector.to_bigarray_inplace y in
let v = Vector.to_bigarray_inplace v in
ignore @@ gemv ?m ?n ~beta ~trans:`T ~y ~alpha ~ar ~ac t v
let gemv_n ?m ?n ?(beta=0.) ?y ?(alpha=1.) ?(ar=1) ?(ac=1) t v =
let v = Vector.to_bigarray_inplace v in
let y =
match y with
| None -> None
| Some y -> Some (Vector.to_bigarray_inplace y)
in
gemv ?m ?n ~beta ?y ~trans:`N ~alpha ~ar ~ac t v
|> Vector.of_bigarray_inplace
let gemv_t ?m ?n ?(beta=0.) ?y ?(alpha=1.) ?(ar=1) ?(ac=1) t v =
let v = Vector.to_bigarray_inplace v in
let y =
match y with
| None -> None
| Some y -> Some (Vector.to_bigarray_inplace y)
in
gemv ?m ?n ~beta ?y ~trans:`T ~alpha ~ar ~ac t v
|> Vector.of_bigarray_inplace
let gemm_inplace ?m ?n ?k ?(beta=0.) ~c ?(transa=`N) ?(alpha=1.0) a ?(transb=`N) b =
ignore @@ gemm ?m ?n ?k ~beta ~c ~transa ~alpha a ~transb b
let gemm_nn_inplace ?m ?n ?k ?(beta=0.) ~c ?(alpha=1.0) a b =
gemm_inplace ?m ?n ?k ~beta ~c ~alpha a b ~transa:`N ~transb:`N
let gemm_nt_inplace ?m ?n ?k ?(beta=0.) ~c ?(alpha=1.0) a b =
gemm_inplace ?m ?n ?k ~beta ~c ~alpha a b ~transa:`N ~transb:`T
let gemm_tn_inplace ?m ?n ?k ?(beta=0.) ~c ?(alpha=1.0) a b =
gemm_inplace ?m ?n ?k ~beta ~c ~alpha a b ~transa:`T ~transb:`N
let gemm_tt_inplace ?m ?n ?k ?(beta=0.) ~c ?(alpha=1.0) a b =
gemm_inplace ?m ?n ?k ~beta ~c ~alpha a b ~transa:`T ~transb:`T
let gemm ?m ?n ?k ?beta ?c ?(transa=`N) ?(alpha=1.0) a ?(transb=`N) b =
let c =
match c with
| Some x -> Some (lacpy x)
| None -> None
in
gemm ?m ?n ?k ?beta ?c ~transa ~alpha a ~transb b
let gemm_nn ?m ?n ?k ?beta ?c ?(alpha=1.0) a b =
gemm ?m ?n ?k ?beta ?c ~alpha a b ~transa:`N ~transb:`N
let gemm_nt ?m ?n ?k ?beta ?c ?(alpha=1.0) a b =
gemm ?m ?n ?k ?beta ?c ~alpha a b ~transa:`N ~transb:`T
let gemm_tn ?m ?n ?k ?beta ?c ?(alpha=1.0) a b =
gemm ?m ?n ?k ?beta ?c ~alpha a b ~transa:`T ~transb:`N
let gemm_tt ?m ?n ?k ?beta ?c ?(alpha=1.0) a b =
gemm ?m ?n ?k ?beta ?c ~alpha a b ~transa:`T ~transb:`T
let gemm_trace ?(transa=`N) a ?(transb=`N) b =
Mat.gemm_trace ~transa a ~transb b
let gemm_nn_trace a b = gemm_trace a b ~transa:`N ~transb:`N
let gemm_nt_trace a b = gemm_trace a b ~transa:`N ~transb:`T
let gemm_tn_trace a b = gemm_trace a b ~transa:`T ~transb:`N
let gemm_tt_trace a b = gemm_trace a b ~transa:`T ~transb:`T
let init_cols = Mat.init_cols
let of_col_vecs a =
Array.map Vector.to_bigarray_inplace a
|> Mat.of_col_vecs
let of_col_vecs_list a =
List.rev_map Vector.to_bigarray_inplace a
|> List.rev
|> Mat.of_col_vecs_list
let of_array a =
Bigarray.Array2.of_array Bigarray.Float64 Bigarray.fortran_layout a
let to_array a =
let result = Array.make_matrix (Mat.dim1 a) (Mat.dim2 a) 0. in
for i=1 to Mat.dim1 a do
let result_i = result.(i-1) in
for j=1 to Mat.dim2 a do
result_i.(j-1) <- a.{i,j}
done
done;
result
let normalize_mat_inplace t =
let norm = Mat.as_vec t |> nrm2 in
Mat.scal norm t
let normalize_mat t =
out_of_place normalize_mat_inplace t
let diagonalize_symm m_H =
let m_V = lacpy m_H in
let result =
syevd ~vectors:true m_V
|> Vector.of_bigarray_inplace
in
m_V, result
let sycon t =
lacpy t
|> sycon
let xt_o_x ~o ~x =
gemm o x
|> gemm ~transa:`T x
let x_o_xt ~o ~x =
gemm o x ~transb:`T
|> gemm x
let amax t =
Mat.as_vec t |> amax
let pp ppf m =
let rows = Mat.dim1 m
and cols = Mat.dim2 m
in
let rec aux first last =
if (first <= last) then begin
Format.fprintf ppf "@[\n\n %a@]@ " (Lacaml.Io.pp_lfmat
~row_labels:
(Array.init rows (fun i -> Printf.sprintf "%d " (i + 1)))
~col_labels:
(Array.init (min 5 (cols-first+1)) (fun i -> Printf.sprintf "-- %d --" (i + first) ))
~print_right:false
~print_foot:false
() ) (lacpy ~ac:first ~n:(min 5 (cols-first+1)) m);
(aux [@tailcall]) (first+5) last
end
in
aux 1 cols
let sysv_inplace ~b a =
sysv a b
let sysv ~b a =
out_of_place (fun b -> sysv_inplace ~b a) b
let debug_matrix name a =
Format.printf "@[%s =\n@[%a@]@]@." name pp a
let outer_product_inplace m ?(alpha=1.0) u v =
ger ~alpha (Vector.to_bigarray_inplace u) (Vector.to_bigarray_inplace v) m
let outer_product ?(alpha=1.0) u v =
let m = make0 (Vector.dim u) (Vector.dim v) in
outer_product_inplace m ~alpha u v;
m
let of_file filename =
let ic = Scanf.Scanning.open_in filename in
let rec read_line accu =
let result =
try
Some (Scanf.bscanf ic " %d %d %f" (fun i j v ->
(i,j,v) :: accu))
with End_of_file -> None
in
match result with
| Some accu -> (read_line [@tailcall]) accu
| None -> List.rev accu
in
let data = read_line [] in
Scanf.Scanning.close_in ic;
let isize, jsize =
List.fold_left (fun (accu_i,accu_j) (i,j,_) ->
(max i accu_i, max j accu_j)) (0,0) data
in
let result =
Lacaml.D.Mat.of_array
(Array.make_matrix isize jsize 0.)
in
List.iter (fun (i,j,v) -> result.{i,j} <- v) data;
result
let sym_of_file filename =
let result =
of_file filename
in
for j=1 to Mat.dim1 result do
for i=1 to j do
result.{j,i} <- result.{i,j}
done;
done;
result
let copy ?m ?n ?br ?bc ?ar ?ac a =
lacpy a ?m ?n ?br ?bc ?ar ?ac
let copy_inplace ?m ?n ?br ?bc ~b ?ar ?ac a =
ignore @@ lacpy ?m ?n ?br ?bc ~b ?ar ?ac a
let scale_cols_inplace a v =
Vector.to_bigarray_inplace v
|> Mat.scal_cols a
let scale_cols a v =
let a' = copy a in
Vector.to_bigarray_inplace v
|> Mat.scal_cols a' ;
a'
let scale_rows_inplace v a =
let v' = Vector.to_bigarray_inplace v in
Mat.scal_rows v' a
let scale_rows v a =
let a' = copy a in
let v' = Vector.to_bigarray_inplace v in
Mat.scal_rows v' a' ;
a'
let svd a =
let d, u, vt =
gesvd (lacpy a)
in
u, (Vector.of_bigarray_inplace d), vt
let svd' a =
let d, u, vt =
gesvd (lacpy a)
in
u, (Vector.of_bigarray_inplace d), vt
let qr a =
let result = lacpy a in
let tau = geqrf result in
let r =
let r = to_bigarray result in
for j=1 to Mat.dim2 r do
for i=j+1 to Mat.dim2 r do
r.{i,j} <- 0.
done
done;
of_bigarray r
in
orgqr ~tau result;
let q = result in
q, r
let exponential_iterative a =
assert (dim1 a = dim2 a);
let rec loop result accu n =
let b = scale (1./.n) a in
let new_accu = gemm accu b in
let residual =
sub new_accu accu
|> amax
|> abs_float
in
let result = add result new_accu in
if residual > Constants.epsilon then
loop result new_accu (n+.1.)
else
result
in
let id = identity (dim1 a) in
loop id id 1.
let exponential a =
let n = dim1 a in
assert (n = dim2 a);
let a2 = gemm a a in
let (u, w, vt) = svd a2 in
let tau = Vector.map (fun x -> -. sqrt x) w in
let cos_tau = Vector.cos tau in
let sin_tau_tau = Vector.mul (Vector.sin tau) (Vector.reci tau) in
let result =
add (gemm (scale_cols u cos_tau) vt) (gemm (scale_cols u sin_tau_tau) @@ gemm vt a)
in
(* Post-condition: Check if exp(-A) * exp(A) = I *)
let id = identity n in
let test =
gemm_tn ~beta:(-.1.0) ~c:id result result
|> amax
|> abs_float
in
assert (test < Constants.epsilon);
result
let to_file ~filename ?(sym=false) ?(cutoff=0.) t =
let oc = open_out filename in
let n = Mat.dim1 t in
let m = Mat.dim2 t in
if sym then
for j=1 to n do
for i=1 to j do
if (abs_float (t.{i,j}) > cutoff) then
Printf.fprintf oc "%4d %4d %20.12e\n" i j (t.{i,j})
done;
done
else
for j=1 to n do
for i=1 to m do
if (abs_float (t.{i,j}) > cutoff) then
Printf.fprintf oc "%4d %4d %20.12e\n" i j (t.{i,j})
done;
done;
close_out oc
let (%:) t (i,j) = t.{i,j}
let set t i j v = t.{i,j} <- v