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626 lines
18 KiB
Fortran
626 lines
18 KiB
Fortran
!
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! Parallel Sparse BLAS version 3.5
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! (C) Copyright 2006-2018
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! Salvatore Filippone
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! Alfredo Buttari
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!
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! Redistribution and use in source and binary forms, with or without
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! modification, are permitted provided that the following conditions
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! are met:
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! 1. Redistributions of source code must retain the above copyright
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! notice, this list of conditions and the following disclaimer.
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! 2. Redistributions in binary form must reproduce the above copyright
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! notice, this list of conditions, and the following disclaimer in the
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! documentation and/or other materials provided with the distribution.
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! 3. The name of the PSBLAS group or the names of its contributors may
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! not be used to endorse or promote products derived from this
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! software without specific written permission.
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!
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! THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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! ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
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! TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
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! PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE PSBLAS GROUP OR ITS CONTRIBUTORS
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! BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
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! CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
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! SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
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! INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
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! CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
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! ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
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! POSSIBILITY OF SUCH DAMAGE.
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!
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!
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!
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! Purpose:
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! Provide functions to handle a distribution of a general
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! rectangular 2/3/n-dimensional domain onto
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! a rectangular 2/3/n-dimensional grid of processes
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!
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! See test/pargen/psb_X_pdeNd for examples of usage
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!
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module psb_partidx_mod
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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interface idx2ijk
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module procedure idx2ijk3d, idx2ijkv, idx2ijk2d
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end interface idx2ijk
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interface ijk2idx
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module procedure ijk2idx3d, ijk2idxv, ijk2idx2d
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end interface ijk2idx
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interface idx2ijk
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module procedure lidx2ijk3d, lidx2ijkv, lidx2ijk2d,&
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& lidx2lijk3d, lidx2lijkv, lidx2lijk2d
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end interface idx2ijk
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interface ijk2idx
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module procedure ijk2lidx3d, ijk2lidxv, ijk2lidx2d,&
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& lijk2lidx3d, lijk2lidxv, lijk2lidx2d
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end interface ijk2idx
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logical, private, save :: col_major=.true.
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contains
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subroutine psb_pidx_set_col_major(val)
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implicit none
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logical, intent(in), optional :: val
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logical :: val_
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val_ =.true.
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if (present(val)) val_ = val
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col_major = val_
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end subroutine psb_pidx_set_col_major
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subroutine psb_pidx_set_row_major()
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implicit none
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call psb_pidx_set_col_major(.false.)
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end subroutine psb_pidx_set_row_major
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function psb_pidx_get_col_major() result(val)
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implicit none
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logical :: val
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val = col_major
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end function psb_pidx_get_col_major
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!
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! Given a global index IDX and the domain size (NX,NY,NZ)
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! compute the point coordinates (I,J,K)
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! Optional argument: base 0 or 1, default 1
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!
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! This mapping is equivalent to a loop nesting:
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! idx = base
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! do i=1,nx
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! do j=1,ny
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! do k=1,nz
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! ijk2idx(i,j,k) = idx
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! idx = idx + 1
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pure subroutine idx2ijk3d(i,j,k,idx,nx,ny,nz,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_mpk_), intent(out) :: i,j,k
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integer(psb_mpk_), intent(in) :: idx,nx,ny,nz
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_mpk_) :: coords(3)
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call idx2ijk(coords,idx,[nx,ny,nz],base)
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k = coords(3)
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j = coords(2)
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i = coords(1)
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end subroutine idx2ijk3d
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pure subroutine idx2ijk2d(i,j,idx,nx,ny,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_mpk_), intent(out) :: i,j
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integer(psb_mpk_), intent(in) :: idx,nx,ny
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_mpk_) :: coords(2)
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call idx2ijk(coords,idx,[nx,ny],base)
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j = coords(2)
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i = coords(1)
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end subroutine idx2ijk2d
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!
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! Given a global index IDX and the domain size (NX,NY,NZ)
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! compute the point coordinates (I,J,K)
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! Optional argument: base 0 or 1, default 1
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!
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! This mapping is equivalent to a loop nesting:
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! idx = base
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! do i=1,nx
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! do j=1,ny
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! do k=1,nz
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! ijk2idx(i,j,k) = idx
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! idx = idx + 1
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pure subroutine idx2ijkv(coords,idx,dims,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_mpk_), intent(out) :: coords(:)
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integer(psb_mpk_), intent(in) :: idx,dims(:)
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_mpk_) :: base_, idx_, i, sz
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if (present(base)) then
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base_ = base
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else
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base_ = 1
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end if
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idx_ = idx - base_
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if (size(coords) < size(dims)) then
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!write(0,*) 'Error: size mismatch ',size(coords),size(dims)
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coords = 0
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return
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end if
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!
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! This code is equivalent to (3D case)
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! k = mod(idx_,nz) + base_
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! j = mod(idx_/nz,ny) + base_
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! i = mod(idx_/(nx*ny),nx) + base_
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!
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if (col_major) then
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do i=1,size(dims)
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coords(i) = mod(idx_,dims(i)) + base_
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idx_ = idx_ / dims(i)
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end do
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else
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do i=size(dims),1,-1
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coords(i) = mod(idx_,dims(i)) + base_
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idx_ = idx_ / dims(i)
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end do
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end if
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end subroutine idx2ijkv
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pure subroutine lidx2ijk3d(i,j,k,idx,nx,ny,nz,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_mpk_), intent(out) :: i,j,k
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integer(psb_epk_), intent(in) :: idx
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integer(psb_mpk_), intent(in) :: nx,ny,nz
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_mpk_) :: coords(3)
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call idx2ijk(coords,idx,[nx,ny,nz],base)
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k = coords(3)
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j = coords(2)
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i = coords(1)
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end subroutine lidx2ijk3d
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pure subroutine lidx2ijk2d(i,j,idx,nx,ny,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_mpk_), intent(out) :: i,j
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integer(psb_epk_), intent(in) :: idx
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integer(psb_mpk_), intent(in) :: nx,ny
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_mpk_) :: coords(2)
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call idx2ijk(coords,idx,[nx,ny],base)
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j = coords(2)
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i = coords(1)
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end subroutine lidx2ijk2d
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!
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! Given a global index IDX and the domain size (NX,NY,NZ)
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! compute the point coordinates (I,J,K)
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! Optional argument: base 0 or 1, default 1
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!
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! This mapping is equivalent to a loop nesting:
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! idx = base
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! do i=1,nx
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! do j=1,ny
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! do k=1,nz
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! ijk2idx(i,j,k) = idx
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! idx = idx + 1
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pure subroutine lidx2ijkv(coords,idx,dims,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_mpk_), intent(out) :: coords(:)
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integer(psb_epk_), intent(in) :: idx
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integer(psb_mpk_), intent(in) :: dims(:)
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_epk_) :: base_, idx_
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integer(psb_mpk_) :: i, sz
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if (present(base)) then
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base_ = base
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else
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base_ = 1
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end if
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idx_ = idx - base_
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if (size(coords) < size(dims)) then
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!write(0,*) 'Error: size mismatch ',size(coords),size(dims)
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coords = 0
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return
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end if
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!
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! This code is equivalent to (3D case)
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! k = mod(idx_,nz) + base_
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! j = mod(idx_/nz,ny) + base_
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! i = mod(idx_/(nx*ny),nx) + base_
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!
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if (col_major) then
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do i=1,size(dims)
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coords(i) = mod(idx_,dims(i)) + base_
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idx_ = idx_ / dims(i)
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end do
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else
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do i=size(dims),1,-1
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coords(i) = mod(idx_,dims(i)) + base_
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idx_ = idx_ / dims(i)
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end do
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end if
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end subroutine lidx2ijkv
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pure subroutine lidx2lijk3d(i,j,k,idx,nx,ny,nz,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_epk_), intent(out) :: i,j,k
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integer(psb_epk_), intent(in) :: idx
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integer(psb_epk_), intent(in) :: nx,ny,nz
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_epk_) :: coords(3)
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call idx2ijk(coords,idx,[nx,ny,nz],base)
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k = coords(3)
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j = coords(2)
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i = coords(1)
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end subroutine lidx2lijk3d
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pure subroutine lidx2lijk2d(i,j,idx,nx,ny,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_epk_), intent(out) :: i,j
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integer(psb_epk_), intent(in) :: idx
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integer(psb_epk_), intent(in) :: nx,ny
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_epk_) :: coords(2)
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call idx2ijk(coords,idx,[nx,ny],base)
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j = coords(2)
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i = coords(1)
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end subroutine lidx2lijk2d
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!
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! Given a global index IDX and the domain size (NX,NY,NZ)
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! compute the point coordinates (I,J,K)
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! Optional argument: base 0 or 1, default 1
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!
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! This mapping is equivalent to a loop nesting:
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! idx = base
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! do i=1,nx
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! do j=1,ny
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! do k=1,nz
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! ijk2idx(i,j,k) = idx
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! idx = idx + 1
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pure subroutine lidx2lijkv(coords,idx,dims,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_epk_), intent(out) :: coords(:)
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integer(psb_epk_), intent(in) :: idx
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integer(psb_epk_), intent(in) :: dims(:)
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_epk_) :: base_, idx_
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integer(psb_epk_) :: i, sz
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if (present(base)) then
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base_ = base
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else
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base_ = 1
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end if
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idx_ = idx - base_
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if (size(coords) < size(dims)) then
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!write(0,*) 'Error: size mismatch ',size(coords),size(dims)
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coords = 0
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return
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end if
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!
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! This code is equivalent to (3D case)
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! k = mod(idx_,nz) + base_
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! j = mod(idx_/nz,ny) + base_
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! i = mod(idx_/(nx*ny),nx) + base_
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!
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if (col_major) then
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do i=1,size(dims)
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coords(i) = mod(idx_,dims(i)) + base_
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idx_ = idx_ / dims(i)
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end do
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else
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do i=size(dims),1,-1
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coords(i) = mod(idx_,dims(i)) + base_
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idx_ = idx_ / dims(i)
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end do
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end if
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end subroutine lidx2lijkv
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!
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! Given a triple (I,J,K) and the domain size (NX,NY,NZ)
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! compute the global index IDX
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! Optional argument: base 0 or 1, default 1
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!
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! This mapping is equivalent to a loop nesting:
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! idx = base
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! do i=1,nx
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! do j=1,ny
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! do k=1,nz
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! ijk2idx(i,j,k) = idx
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! idx = idx + 1
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pure subroutine ijk2idxv(idx,coords,dims,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_mpk_), intent(in) :: coords(:),dims(:)
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integer(psb_mpk_), intent(out) :: idx
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_mpk_) :: base_, i, sz
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if (present(base)) then
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base_ = base
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else
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base_ = 1
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end if
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sz = size(coords)
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if (sz /= size(dims)) then
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!write(0,*) 'Error: size mismatch ',size(coords),size(dims)
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idx = 0
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return
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end if
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if (col_major) then
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idx = coords(sz) - base_
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do i=sz-1,1,-1
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idx = (idx * dims(i)) + coords(i) - base_
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end do
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idx = idx + base_
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else
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idx = coords(1) - base_
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do i=2,sz
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idx = (idx * dims(i)) + coords(i) - base_
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end do
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idx = idx + base_
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end if
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end subroutine ijk2idxv
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!
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! Given a triple (I,J,K) and the domain size (NX,NY,NZ)
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! compute the global index IDX
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! Optional argument: base 0 or 1, default 1
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!
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! This mapping is equivalent to a loop nesting:
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! idx = base
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! do i=1,nx
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! do j=1,ny
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! do k=1,nz
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! ijk2idx(i,j,k) = idx
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! idx = idx + 1
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pure subroutine ijk2idx3d(idx,i,j,k,nx,ny,nz,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_mpk_), intent(out) :: idx
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integer(psb_mpk_), intent(in) :: i,j,k,nx,ny,nz
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integer(psb_mpk_), intent(in), optional :: base
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! idx = ((i-base_)*nz*ny + (j-base_)*nz + k - base_) + base_
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call ijk2idx(idx,[i,j,k],[nx,ny,nz],base)
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end subroutine ijk2idx3d
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pure subroutine ijk2idx2d(idx,i,j,nx,ny,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_mpk_), intent(out) :: idx
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integer(psb_mpk_), intent(in) :: i,j,nx,ny
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integer(psb_mpk_), intent(in), optional :: base
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! idx = ((i-base_)*ny + (j-base_) + base_
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call ijk2idx(idx,[i,j],[nx,ny],base)
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end subroutine ijk2idx2d
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pure subroutine ijk2lidxv(idx,coords,dims,base)
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use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
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implicit none
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integer(psb_mpk_), intent(in) :: coords(:),dims(:)
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integer(psb_epk_), intent(out) :: idx
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integer(psb_mpk_), intent(in), optional :: base
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integer(psb_mpk_) :: base_, i, sz
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if (present(base)) then
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base_ = base
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else
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base_ = 1
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end if
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sz = size(coords)
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if (sz /= size(dims)) then
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!write(0,*) 'Error: size mismatch ',size(coords),size(dims)
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idx = 0
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return
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end if
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if (col_major) then
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idx = coords(sz) - base_
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do i=sz-1,1,-1
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idx = (idx * dims(i)) + coords(i) - base_
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end do
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idx = idx + base_
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else
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idx = coords(1) - base_
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do i=2,sz
|
|
idx = (idx * dims(i)) + coords(i) - base_
|
|
end do
|
|
idx = idx + base_
|
|
end if
|
|
|
|
end subroutine ijk2lidxv
|
|
!
|
|
! Given a triple (I,J,K) and the domain size (NX,NY,NZ)
|
|
! compute the global index IDX
|
|
! Optional argument: base 0 or 1, default 1
|
|
!
|
|
! This mapping is equivalent to a loop nesting:
|
|
! idx = base
|
|
! do i=1,nx
|
|
! do j=1,ny
|
|
! do k=1,nz
|
|
! ijk2idx(i,j,k) = idx
|
|
! idx = idx + 1
|
|
pure subroutine ijk2lidx3d(idx,i,j,k,nx,ny,nz,base)
|
|
use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
|
|
implicit none
|
|
integer(psb_epk_), intent(out) :: idx
|
|
integer(psb_mpk_), intent(in) :: i,j,k,nx,ny,nz
|
|
integer(psb_mpk_), intent(in), optional :: base
|
|
|
|
! idx = ((i-base_)*nz*ny + (j-base_)*nz + k - base_) + base_
|
|
call ijk2idx(idx,[i,j,k],[nx,ny,nz],base)
|
|
end subroutine ijk2lidx3d
|
|
|
|
pure subroutine ijk2lidx2d(idx,i,j,nx,ny,base)
|
|
use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
|
|
implicit none
|
|
integer(psb_epk_), intent(out) :: idx
|
|
integer(psb_mpk_), intent(in) :: i,j,nx,ny
|
|
integer(psb_mpk_), intent(in), optional :: base
|
|
|
|
! idx = ((i-base_)*ny + (j-base_) + base_
|
|
call ijk2idx(idx,[i,j],[nx,ny],base)
|
|
end subroutine ijk2lidx2d
|
|
|
|
|
|
pure subroutine lijk2lidxv(idx,coords,dims,base)
|
|
use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
|
|
implicit none
|
|
integer(psb_epk_), intent(in) :: coords(:),dims(:)
|
|
integer(psb_epk_), intent(out) :: idx
|
|
integer(psb_mpk_), intent(in), optional :: base
|
|
|
|
integer(psb_epk_) :: base_, i, sz
|
|
if (present(base)) then
|
|
base_ = base
|
|
else
|
|
base_ = 1
|
|
end if
|
|
sz = size(coords)
|
|
if (sz /= size(dims)) then
|
|
!write(0,*) 'Error: size mismatch ',size(coords),size(dims)
|
|
idx = 0
|
|
return
|
|
end if
|
|
|
|
if (col_major) then
|
|
idx = coords(sz) - base_
|
|
do i=sz-1,1,-1
|
|
idx = (idx * dims(i)) + coords(i) - base_
|
|
end do
|
|
idx = idx + base_
|
|
else
|
|
idx = coords(1) - base_
|
|
do i=2,sz
|
|
idx = (idx * dims(i)) + coords(i) - base_
|
|
end do
|
|
idx = idx + base_
|
|
end if
|
|
|
|
end subroutine lijk2lidxv
|
|
!
|
|
! Given a triple (I,J,K) and the domain size (NX,NY,NZ)
|
|
! compute the global index IDX
|
|
! Optional argument: base 0 or 1, default 1
|
|
!
|
|
! This mapping is equivalent to a loop nesting:
|
|
! idx = base
|
|
! do i=1,nx
|
|
! do j=1,ny
|
|
! do k=1,nz
|
|
! ijk2idx(i,j,k) = idx
|
|
! idx = idx + 1
|
|
pure subroutine lijk2lidx3d(idx,i,j,k,nx,ny,nz,base)
|
|
use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
|
|
implicit none
|
|
integer(psb_epk_), intent(out) :: idx
|
|
integer(psb_epk_), intent(in) :: i,j,k,nx,ny,nz
|
|
integer(psb_mpk_), intent(in), optional :: base
|
|
|
|
! idx = ((i-base_)*nz*ny + (j-base_)*nz + k - base_) + base_
|
|
call ijk2idx(idx,[i,j,k],[nx,ny,nz],base)
|
|
end subroutine lijk2lidx3d
|
|
|
|
pure subroutine lijk2lidx2d(idx,i,j,nx,ny,base)
|
|
use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
|
|
implicit none
|
|
integer(psb_epk_), intent(out) :: idx
|
|
integer(psb_epk_), intent(in) :: i,j,nx,ny
|
|
integer(psb_mpk_), intent(in), optional :: base
|
|
|
|
! idx = ((i-base_)*ny + (j-base_) + base_
|
|
call ijk2idx(idx,[i,j],[nx,ny],base)
|
|
end subroutine lijk2lidx2d
|
|
|
|
!
|
|
! dist1Didx
|
|
! Given an index space [base : N-(1-base)] and
|
|
! a set of NP processes, split the index base as
|
|
! evenly as possible, i.e. difference in size
|
|
! between any two processes is either 0 or 1,
|
|
! then return the boundaries in a vector
|
|
! such that
|
|
! V(P) : first index owned by process P
|
|
! V(P+1) : first index owned by process P+1
|
|
!
|
|
subroutine dist1Didx(v,n,np,base)
|
|
use psb_base_mod, only : psb_ipk_, psb_lpk_, psb_mpk_, psb_epk_
|
|
implicit none
|
|
integer(psb_ipk_), intent(out) :: v(:)
|
|
integer(psb_ipk_), intent(in) :: n, np
|
|
integer(psb_ipk_), intent(in), optional :: base
|
|
!
|
|
integer(psb_ipk_) :: base_, nb, i
|
|
|
|
if (present(base)) then
|
|
base_ = base
|
|
else
|
|
base_ = 1
|
|
end if
|
|
|
|
nb = n/np
|
|
do i=1,mod(n,np)
|
|
v(i) = nb + 1
|
|
end do
|
|
do i=mod(n,np)+1,np
|
|
v(i) = nb
|
|
end do
|
|
v(2:np+1) = v(1:np)
|
|
v(1) = base_
|
|
do i=2,np+1
|
|
v(i) = v(i) + v(i-1)
|
|
end do
|
|
end subroutine dist1Didx
|
|
|
|
end module psb_partidx_mod
|
|
|