NAG Library Manual, Mark 30
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NAG FL Interface Introduction
Example description
!   F11DUF Example Program Text
!   Mark 30.0 Release. NAG Copyright 2024.

    Program f11dufe

!     .. Use Statements ..
      Use nag_library, Only: f11dtf, f11duf, nag_wp
!     .. Implicit None Statement ..
      Implicit None
!     .. Parameters ..
      Integer, Parameter               :: nin = 5, nout = 6
!     .. Local Scalars ..
      Real (Kind=nag_wp)               :: dtolg, rnorm, tol
      Integer                          :: i, ifail, itn, k, la, lfillg, lindb, &
                                          liwork, lwork, m, maxitn, mb, n, nb, &
                                          nnz, nnzc, nover
      Character (8)                    :: method
      Character (1)                    :: milug, pstrag
!     .. Local Arrays ..
      Complex (Kind=nag_wp), Allocatable :: a(:), b(:), work(:), x(:)
      Real (Kind=nag_wp), Allocatable  :: dtol(:)
      Integer, Allocatable             :: icol(:), idiag(:), indb(:),          &
                                          ipivp(:), ipivq(:), irow(:),         &
                                          istb(:), istr(:), iwork(:),          &
                                          lfill(:), npivm(:)
      Character (1), Allocatable       :: milu(:), pstrat(:)
!     .. Executable Statements ..

!     Print example header
      Write (nout,*) 'F11DUF Example Program Results'
      Write (nout,*)

!     Skip heading in data file
      Read (nin,*)

!     Get the square matrix size
      Read (nin,*) n

!     Allocate arrays with lengths based on mesh.
      liwork = 9*n + 3
      Allocate (b(n),x(n),iwork(liwork))

!     Get the number of non zero (nnz) matrix entries
      Read (nin,*) nnz
      la = 20*nnz
      Allocate (a(la),irow(la),icol(la))

      lindb = 3*n
      Allocate (idiag(lindb),indb(lindb),ipivp(lindb),ipivq(lindb),            &
        istr(lindb+1))

!     Read in matrix A
      Read (nin,*)(a(i),irow(i),icol(i),i=1,nnz)

!     Read in RHS
      Read (nin,*) b(1:n)

!     Read algorithmic parameters
      Read (nin,*) method
      Read (nin,*) lfillg, dtolg
      Read (nin,*) pstrag
      Read (nin,*) milug
      Read (nin,*) m, tol, maxitn
      Read (nin,*) nb, nover

!     Allocate arrays with length based on number of blocks.
      Allocate (dtol(nb),istb(nb+1),lfill(nb),npivm(nb),milu(nb),pstrat(nb))

!     Set up initial approximate solution x
      x(1:n) = (0.0_nag_wp,0.0_nag_wp)

!     Define diagonal block indices.
!     In this example use blocks of MB consecutive rows and initialize
!     assuming no overlap.
      mb = (n+nb-1)/nb
      Do k = 1, nb
        istb(k) = (k-1)*mb + 1
      End Do
      istb(nb+1) = n + 1
      Do i = 1, n
        indb(i) = i
      End Do

!     Modify INDB and ISTB to account for overlap.
      Call f11dufe_overlap(n,nnz,la,irow,icol,nb,istb,indb,lindb,nover,iwork)
      If (iwork(1)==-999) Then
        Write (nout,*) '** LINDB too small, LINDB = ', lindb, '.'
        Go To 100
      End If

!     Set algorithmic parameters for each block from global values
      lfill(1:nb) = lfillg
      dtol(1:nb) = dtolg
      pstrat(1:nb) = pstrag
      milu(1:nb) = milug

!     Set size of real workspace
      lwork = 6*n + m*(m+n+5) + 121
      Allocate (work(lwork))

!     Calculate factorization
      ifail = 0
      Call f11dtf(n,nnz,a,la,irow,icol,nb,istb,indb,lindb,lfill,dtol,pstrat,   &
        milu,ipivp,ipivq,istr,idiag,nnzc,npivm,iwork,liwork,ifail)

!     Solve Ax = b using F11DUF
      ifail = 0
      Call f11duf(method,n,nnz,a,la,irow,icol,nb,istb,indb,lindb,ipivp,ipivq,  &
        istr,idiag,b,m,tol,maxitn,x,rnorm,itn,work,lwork,ifail)

      Write (nout,99999) itn
      Write (nout,99998) rnorm
      Write (nout,*)

!     Output x
      Write (nout,*) 'Solution vector   X'
      Write (nout,*) '-------------------'
      Write (nout,99997) x(1:n)

100   Continue

99999 Format (1X,' Converged in',I10,' iterations')
99998 Format (1X,' Final residual norm =',1P,D16.3)
99997 Format (1X,'(',F8.4,',',F8.4,')')

    Contains
      Subroutine f11dufe_overlap(n,nnz,la,irow,icol,nb,istb,indb,lindb,nover,  &
        iwork)

!       Purpose
!       =======
!       This routine takes a set of row indices INDB defining the diagonal
!       blocks to be used in F11DTF to define a block Jacobi or additive
!       Schwarz preconditioner, and expands them to allow for NOVER levels of
!       overlap.
!       The pointer array ISTB is also updated accordingly, so that the
!       returned values of ISTB and INDB can be passed to F11DTF to define
!       overlapping diagonal blocks.
!       ----------------------------------------------------------------------

!       .. Implicit None Statement ..
        Implicit None
!       .. Scalar Arguments ..
        Integer, Intent (In)           :: la, lindb, n, nb, nnz, nover
!       .. Array Arguments ..
        Integer, Intent (In)           :: icol(la), irow(la)
        Integer, Intent (Inout)        :: indb(lindb), istb(nb+1)
        Integer, Intent (Out)          :: iwork(3*n+1)
!       .. Local Scalars ..
        Integer                        :: i, ik, ind, iover, k, l, n21, nadd,  &
                                          row
!       .. Executable Statements ..

!       Find the number of nonzero elements in each row of the matrix A, and
!       and start address of each row. Store the start addresses in
!       IWORK(N+1,...,2*N+1).

        iwork(1:n) = 0
        Do k = 1, nnz
          iwork(irow(k)) = iwork(irow(k)) + 1
        End Do
        iwork(n+1) = 1
        Do i = 1, n
          iwork(n+i+1) = iwork(n+i) + iwork(i)
        End Do

!       Loop over blocks.
blocks: Do k = 1, nb

!         Initialize marker array.
          iwork(1:n) = 0

!         Mark the rows already in block K in the workspace array.
          Do l = istb(k), istb(k+1) - 1
            iwork(indb(l)) = 1
          End Do

!         Loop over levels of overlap.
          Do iover = 1, nover

!           Initialize counter of new row indices to be added.
            ind = 0

!           Loop over the rows currently in the diagonal block.
            Do l = istb(k), istb(k+1) - 1
              row = indb(l)

!             Loop over nonzero elements in row ROW.
              Do i = iwork(n+row), iwork(n+row+1) - 1

!               If the column index of the nonzero element is not in the
!               existing set for this block, store it to be added later, and
!               mark it in the marker array.
                If (iwork(icol(i))==0) Then
                  iwork(icol(i)) = 1
                  ind = ind + 1
                  iwork(2*n+1+ind) = icol(i)
                End If
              End Do
            End Do

!           Shift the indices in INDB and add the new entries for block K.
!           Change ISTB accordingly.
            nadd = ind
            If (istb(nb+1)+nadd-1>lindb) Then
              iwork(1) = -999
              Exit blocks
            End If

            Do i = istb(nb+1) - 1, istb(k+1), -1
              indb(i+nadd) = indb(i)
            End Do
            n21 = 2*n + 1
            ik = istb(k+1) - 1
            indb(ik+1:ik+nadd) = iwork(n21+1:n21+nadd)
            istb(k+1:nb+1) = istb(k+1:nb+1) + nadd
          End Do
        End Do blocks

        Return

      End Subroutine f11dufe_overlap
    End Program f11dufe