Legend:
Library
Module
Module type
Parameter
Class
Class type
Library
Module
Module type
Parameter
Class
Class type
package lacaml
type t = matMatrix operations
Creation of matrices
val random :
?rnd_state:Random.State.t ->
?re_from:float ->
?re_range:float ->
?im_from:float ->
?im_range:float ->
int ->
int ->
Lacaml_complex64.matrandom ?rnd_state ?re_from ?re_range ?im_from ?im_range m n
Creation of matrices and accessors
val create : int -> int -> Lacaml_complex64.matcreate m n
val make : int -> int -> Lacaml_complex64.num_type -> Lacaml_complex64.matmake m n x
val make0 : int -> int -> Lacaml_complex64.matmake0 m n x
val of_array : Lacaml_complex64.num_type array array -> Lacaml_complex64.matof_array ar
val to_array : Lacaml_complex64.mat -> Lacaml_complex64.num_type array arrayto_array mat
val of_list : Lacaml_complex64.num_type list list -> Lacaml_complex64.matof_list ls
val to_list : Lacaml_complex64.mat -> Lacaml_complex64.num_type list listto_array mat
val of_col_vecs : Lacaml_complex64.vec array -> Lacaml_complex64.matof_col_vecs ar
val to_col_vecs : Lacaml_complex64.mat -> Lacaml_complex64.vec arrayto_col_vecs mat
val of_col_vecs_list : Lacaml_complex64.vec list -> Lacaml_complex64.matof_col_vecs_list ar
val to_col_vecs_list : Lacaml_complex64.mat -> Lacaml_complex64.vec listto_col_vecs_list mat
val as_vec : Lacaml_complex64.mat -> Lacaml_complex64.vecas_vec mat
val init_rows :
int ->
int ->
(int -> int -> Lacaml_complex64.num_type) ->
Lacaml_complex64.matinit_cols m n f
val init_cols :
int ->
int ->
(int -> int -> Lacaml_complex64.num_type) ->
Lacaml_complex64.matinit_cols m n f
val create_mvec : int -> Lacaml_complex64.matcreate_mvec m
val make_mvec : int -> Lacaml_complex64.num_type -> Lacaml_complex64.matmake_mvec m x
val mvec_of_array : Lacaml_complex64.num_type array -> Lacaml_complex64.matmvec_of_array ar
val mvec_to_array : Lacaml_complex64.mat -> Lacaml_complex64.num_type arraymvec_to_array mat
val from_col_vec : Lacaml_complex64.vec -> Lacaml_complex64.matfrom_col_vec v
val from_row_vec : Lacaml_complex64.vec -> Lacaml_complex64.matfrom_row_vec v
val empty : Lacaml_complex64.matempty, the empty matrix.
val identity : int -> Lacaml_complex64.matidentity n
val of_diag :
?n:int ->
?br:int ->
?bc:int ->
?b:Lacaml_complex64.mat ->
?ofsx:int ->
?incx:int ->
Lacaml_complex64.vec ->
Lacaml_complex64.matof_diag ?n ?br ?bc ?b ?ofsx ?incx x
val dim1 : Lacaml_complex64.mat -> intdim1 m
val dim2 : Lacaml_complex64.mat -> intdim2 m
val has_zero_dim : Lacaml_complex64.mat -> boolhas_zero_dim mat checks whether matrix mat has a dimension of size zero. In this case it cannot contain data.
val col : Lacaml_complex64.mat -> int -> Lacaml_complex64.veccol m n
val copy_row :
?vec:Lacaml_complex64.vec ->
Lacaml_complex64.mat ->
int ->
Lacaml_complex64.veccopy_row ?vec mat int
Matrix transformations
val swap :
?uplo:[ `U | `L ] ->
?m:int ->
?n:int ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
?br:int ->
?bc:int ->
Lacaml_complex64.mat ->
unitswap ?m ?n ?ar ?ac a ?br ?bc b swaps the contents of (sub-matrices) a and b.
val transpose_copy : Lacaml_complex64.Types.Mat.unoptranspose_copy ?m ?n ?br ?bc ?b ?ar ?ac a
val detri :
?up:bool ->
?n:int ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
unitdetri ?up ?n ?ar ?ac a takes a triangular (sub-)matrix a, i.e. one where only the upper (iff up is true) or lower triangle is defined, and makes it a symmetric matrix by mirroring the defined triangle along the diagonal.
val packed :
?up:bool ->
?n:int ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.vecpacked ?up ?n ?ar ?ac a
val unpacked :
?up:bool ->
?n:int ->
Lacaml_complex64.vec ->
Lacaml_complex64.matunpacked ?up x
Operations on one matrix
val fill :
?m:int ->
?n:int ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.num_type ->
unitfill ?m ?n ?ar ?ac a x fills the specified sub-matrix in a with value x.
val sum :
?m:int ->
?n:int ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.num_typesum ?m ?n ?ar ?ac a computes the sum of all elements in the m-by-n submatrix starting at row ar and column ac.
val add_const : Lacaml_complex64.num_type -> Lacaml_complex64.Types.Mat.unopadd_const c ?m ?n ?br ?bc ?b ?ar ?ac a adds constant c to the designated m by n submatrix in a and stores the result in the designated submatrix in b.
val neg : Lacaml_complex64.Types.Mat.unopneg ?m ?n ?br ?bc ?b ?ar ?ac a computes the negative of the elements in the m by n (sub-)matrix of the matrix a starting in row ar and column ac. If b is given, the result will be stored in there using offsets br and bc, otherwise a fresh matrix will be used. The resulting matrix is returned.
val reci : Lacaml_complex64.Types.Mat.unopreci ?m ?n ?br ?bc ?b ?ar ?ac a computes the reciprocal of the elements in the m by n (sub-)matrix of the matrix a starting in row ar and column ac. If b is given, the result will be stored in there using offsets br and bc, otherwise a fresh matrix will be used. The resulting matrix is returned.
val copy_diag :
?n:int ->
?ofsy:int ->
?incy:int ->
?y:Lacaml_complex64.vec ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.veccopy_diag ?n ?ofsy ?incy ?y ?ar ?ac a
val trace : Lacaml_complex64.mat -> Lacaml_complex64.num_typetrace m
val scal :
?m:int ->
?n:int ->
Lacaml_complex64.num_type ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
unitscal ?m ?n alpha ?ar ?ac a BLAS scal function for (sub-)matrices.
val scal_cols :
?m:int ->
?n:int ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
?ofs:int ->
Lacaml_complex64.vec ->
unitscal_cols ?m ?n ?ar ?ac a ?ofs alphas column-wise scal function for matrices.
val scal_rows :
?m:int ->
?n:int ->
?ofs:int ->
Lacaml_complex64.vec ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
unitscal_rows ?m ?n ?ofs alphas ?ar ?ac a row-wise scal function for matrices.
val syrk_trace :
?n:int ->
?k:int ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.num_typesyrk_trace ?n ?k ?ar ?ac a computes the trace of either a' * a or a * a', whichever is more efficient (results are identical), of the (sub-)matrix a multiplied by its own transpose. This is the same as the square of the Frobenius norm of a matrix. n is the number of rows to consider in a, and k the number of columns to consider.
val syrk_diag :
?n:int ->
?k:int ->
?beta:Lacaml_complex64.num_type ->
?ofsy:int ->
?y:Lacaml_complex64.vec ->
?trans:Lacaml_common.trans2 ->
?alpha:Lacaml_complex64.num_type ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.vecsyrk_diag ?n ?k ?beta ?ofsy ?y ?trans ?alpha ?ar ?ac a computes the diagonal of the symmetric rank-k product of the (sub-)matrix a, multiplying it with alpha and adding beta times y, storing the result in y starting at the specified offset. n elements of the diagonal will be computed, and k elements of the matrix will be part of the dot product associated with each diagonal element.
Operations on two matrices
val add : Lacaml_complex64.Types.Mat.binopadd ?m ?n ?cr ?cc ?c ?ar ?ac a ?br ?bc b computes the sum of the m by n sub-matrix of the matrix a starting in row ar and column ac with the corresponding sub-matrix of the matrix b starting in row br and column bc. If c is given, the result will be stored in there starting in row cr and column cc, otherwise a fresh matrix will be used. The resulting matrix is returned.
val sub : Lacaml_complex64.Types.Mat.binopsub ?m ?n ?cr ?cc ?c ?ar ?ac a ?br ?bc b computes the difference of the m by n sub-matrix of the matrix a starting in row ar and column ac with the corresponding sub-matrix of the matrix b starting in row br and column bc. If c is given, the result will be stored in there starting in row cr and column cc, otherwise a fresh matrix will be used. The resulting matrix is returned.
val mul : Lacaml_complex64.Types.Mat.binopmul ?m ?n ?cr ?cc ?c ?ar ?ac a ?br ?bc b computes the element-wise product of the m by n sub-matrix of the matrix a starting in row ar and column ac with the corresponding sub-matrix of the matrix b starting in row br and column bc. If c is given, the result will be stored in there starting in row cr and column cc, otherwise a fresh matrix will be used. The resulting matrix is returned.
NOTE: please do not confuse this function with matrix multiplication! The LAPACK-function for matrix multiplication is called gemm, e.g. Lacaml.D.gemm.
val div : Lacaml_complex64.Types.Mat.binopdiv ?m ?n ?cr ?cc ?c ?ar ?ac a ?br ?bc b computes the division of the m by n sub-matrix of the matrix a starting in row ar and column ac with the corresponding sub-matrix of the matrix b starting in row br and column bc. If c is given, the result will be stored in there starting in row cr and column cc, otherwise a fresh matrix will be used. The resulting matrix is returned.
val axpy :
?alpha:Lacaml_complex64.num_type ->
?m:int ->
?n:int ->
?xr:int ->
?xc:int ->
Lacaml_complex64.mat ->
?yr:int ->
?yc:int ->
Lacaml_complex64.mat ->
unitaxpy ?alpha ?m ?n ?xr ?xc x ?yr ?yc y BLAS axpy function for matrices.
val gemm_diag :
?n:int ->
?k:int ->
?beta:Lacaml_complex64.num_type ->
?ofsy:int ->
?y:Lacaml_complex64.vec ->
?transa:Lacaml_complex64.trans3 ->
?alpha:Lacaml_complex64.num_type ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
?transb:Lacaml_complex64.trans3 ->
?br:int ->
?bc:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.vecgemm_diag ?n ?k ?beta ?ofsy ?y ?transa ?transb ?alpha ?ar ?ac a ?br ?bc b computes the diagonal of the product of the (sub-)matrices a and b (taking into account potential transposing), multiplying it with alpha and adding beta times y, storing the result in y starting at the specified offset. n elements of the diagonal will be computed, and k elements of the matrices will be part of the dot product associated with each diagonal element.
val gemm_trace :
?n:int ->
?k:int ->
?transa:Lacaml_complex64.trans3 ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
?transb:Lacaml_complex64.trans3 ->
?br:int ->
?bc:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.num_typegemm_trace ?n ?k ?transa ?ar ?ac a ?transb ?br ?bc b computes the trace of the product of the (sub-)matrices a and b (taking into account potential transposing). When transposing a, this yields the so-called Frobenius product of a and b. n is the number of rows (columns) to consider in a and the number of columns (rows) in b. k is the inner dimension to use for the product.
val symm2_trace :
?n:int ->
?upa:bool ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
?upb:bool ->
?br:int ->
?bc:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.num_typesymm2_trace ?n ?upa ?ar ?ac a ?upb ?br ?bc b computes the trace of the product of the symmetric (sub-)matrices a and b. n is the number of rows and columns to consider in a and b.
val ssqr_diff :
?m:int ->
?n:int ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
?br:int ->
?bc:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.num_typessqr_diff ?m ?n ?ar ?ac a ?br ?bc b
Iterators over matrices
val map :
(Lacaml_complex64.num_type -> Lacaml_complex64.num_type) ->
?m:int ->
?n:int ->
?br:int ->
?bc:int ->
?b:Lacaml_complex64.mat ->
?ar:int ->
?ac:int ->
Lacaml_complex64.mat ->
Lacaml_complex64.matmap f ?m ?n ?br ?bc ?b ?ar ?ac a
val fold_cols :
('a -> Lacaml_complex64.vec -> 'a) ->
?n:int ->
?ac:int ->
'a ->
Lacaml_complex64.mat ->
'afold_cols f ?n ?ac acc a