Applies a permutation matrix to a general distributed matrix, resulting in row or column pivoting.
call pslapiv(direc, rowcol, pivroc, m, n, a, ia, ja, desca, ipiv, ip, jp, descip, iwork)
call pdlapiv(direc, rowcol, pivroc, m, n, a, ia, ja, desca, ipiv, ip, jp, descip, iwork)
call pclapiv(direc, rowcol, pivroc, m, n, a, ia, ja, desca, ipiv, ip, jp, descip, iwork)
call pzlapiv(direc, rowcol, pivroc, m, n, a, ia, ja, desca, ipiv, ip, jp, descip, iwork)
The p?lapiv routine applies either P (permutation matrix indicated by ipiv) or inv(P) to a general m-by-n distributed matrix sub(A) = A(ia:ia+m-1, ja:ja+n-1), resulting in row or column pivoting. The pivot vector may be distributed across a process row or a column. The pivot vector should be aligned with the distributed matrix A. This routine will transpose the pivot vector, if necessary.
For example, if the row pivots should be applied to the columns of sub(A), pass rowcol='C' and pivroc='C'.
(global) CHARACTER*1.
Specifies in which order the permutation is applied:
= 'F' (Forward). Applies pivots forward from top of matrix. Computes P*sub(A).
= 'B' (Backward). Applies pivots backward from bottom of matrix. Computes inv(P)*sub(A).
(global) CHARACTER*1.
Specifies if the rows or columns are to be permuted:
= 'R' Rows will be permuted,
= 'C' Columns will be permuted.
(global) CHARACTER*1.
Specifies whether ipiv is distributed over a process row or column:
= 'R'ipiv is distributed over a process row,
= 'C'ipiv is distributed over a process column.
(global) INTEGER.
The number of rows to be operated on, that is, the number of rows of the distributed submatrix sub(A). When m = 0, p?lapiv is set to zero. m ≥ 0.
(global) INTEGER.
The number of columns to be operated on, that is, the number of columns of the distributed submatrix sub(A). When n = 0, p?lapiv is set to zero. n ≥ 0.
(local).
Real for pslapiv
DOUBLE PRECISION for pdlapiv
COMPLEX for pclapiv
COMPLEX*16 for pzlapiv.
Pointer into the local memory to an array of DIMENSION(lld_a, LOCc(ja+n-1)) containing the local pieces of the distributed matrix sub(A).
(global) INTEGER.
The row and column indices in the global array A indicating the first row and the first column of the submatrix sub(A), respectively.
(global and local) INTEGER array, DIMENSION (dlen_). The array descriptor for the distributed matrix A.
(local). INTEGER.
Array, DIMENSION (lipiv) ;
when rowcol='R' or 'r':
lipiv ≥ LOCr(ia+m-1) + mb_a if pivroc='C' or 'c',
lipiv ≥ LOCc(m + mod(jp-1, nb_p)) if pivroc='R' or 'r', and,
when rowcol='C' or 'c':
lipiv ≥ LOCr(n + mod(ip-1, mb_p)) if pivroc='C' or 'c',
lipiv ≥ LOCc(ja+n-1) + nb_a if pivroc='R' or 'r'.
This array contains the pivoting information. ipiv(i) is the global row (column), local row (column) i was swapped with. When rowcol='R' or 'r' and pivroc='C' or 'c', or rowcol='C' or 'c' and pivroc='R' or 'r', the last piece of this array of size mb_a (resp. nb_a) is used as workspace. In those cases, this array is tied to the distributed matrix A.
(global) INTEGER. The row and column indices in the global array P indicating the first row and the first column of the submatrix sub(P), respectively.
(global and local) INTEGER array, DIMENSION (dlen_). The array descriptor for the distributed vector ipiv.
(local). INTEGER.
Array, DIMENSION (ldw), where ldw is equal to the workspace necessary for transposition, and the storage of the transposed ipiv :
Let lcm be the least common multiple of nprow and npcol. If( rowcol.eq.'r' .and. pivroc. eq.'r') then If( nprow.eq. npcol) thenldw = LOCr( n_p + mod(jp-1, nb_p) ) + nb_p elseldw = LOCr( n_p + mod(jp-1, nb_p) )+nb_p * ceil( ceil(LOCc(n_p)/nb_p) / (lcm/npcol) ) end if else if( rowcol.eq.'c' .and. pivroc.eq.'c') then if( nprow.eq.npcol ) thenldw = LOCc( m_p + mod(ip-1, mb_p) ) + mb_p elseldw = LOCc( m_p + mod(ip-1, mb_p) ) +mb_p *ceil(ceil(LOCr(m_p)/mb_p) / (lcm/nprow) ) end if elseiwork is not referenced. end if.
(local).
On exit, the local pieces of the permuted distributed submatrix.