subroutine test_regridMeshToGrid(rc)
integer, intent(out) :: rc
logical :: correct
integer :: localrc
type(ESMF_Mesh) :: srcMesh
type(ESMF_Grid) :: dstGrid
type(ESMF_Field) :: srcField
type(ESMF_Field) :: dstField
type(ESMF_Array) :: dstArray
type(ESMF_Array) :: lonArrayA
type(ESMF_Array) :: srcArrayA
type(ESMF_RouteHandle) :: routeHandle
type(ESMF_ArraySpec) :: arrayspec
type(ESMF_VM) :: vm
real(ESMF_KIND_R8), pointer :: farrayPtrXC(:,:), farrayPtr1D(:)
real(ESMF_KIND_R8), pointer :: farrayPtrYC(:,:)
real(ESMF_KIND_R8), pointer :: farrayPtr(:,:),farrayPtr2(:,:)
integer :: clbnd(2),cubnd(2)
integer :: fclbnd(2),fcubnd(2)
integer :: i1,i2,i3, index(2)
integer :: lDE, localDECount
real(ESMF_KIND_R8) :: coord(2)
character(len=ESMF_MAXSTR) :: string
integer dst_nx, dst_ny
integer num_arrays
real(ESMF_KIND_R8) :: dx,dy
real(ESMF_KIND_R8) :: dst_minx,dst_miny
real(ESMF_KIND_R8) :: dst_maxx,dst_maxy
real(ESMF_KIND_R8) :: x,y
integer :: spherical_grid
integer, pointer :: larrayList(:)
integer :: localPet, petCount
integer, pointer :: nodeIds(:),nodeOwners(:)
real(ESMF_KIND_R8), pointer :: nodeCoords(:)
integer, pointer :: elemIds(:),elemTypes(:),elemConn(:)
integer :: numNodes, numElems
integer :: numQuadElems,numTriElems, numTotElems
! result code
integer :: finalrc
! init success flag
correct=.true.
rc=ESMF_SUCCESS
! get pet info
call ESMF_VMGetGlobal(vm, rc=localrc)
if (ESMF_LogFoundError(localrc, &
ESMF_ERR_PASSTHRU, &
ESMF_CONTEXT, rcToReturn=rc)) return
call ESMF_VMGet(vm, petCount=petCount, localPet=localpet, rc=localrc)
if (ESMF_LogFoundError(localrc, &
ESMF_ERR_PASSTHRU, &
ESMF_CONTEXT, rcToReturn=rc)) return
! If we don't have 1 or 4 PETS then exit successfully
if ((petCount .ne. 1) .and. (petCount .ne. 4)) then
print*,'ERROR: test must be run using exactly 1 or 4 PETS - detected ',petCount
rc=ESMF_FAILURE
return
endif
! Establish the resolution of the grids
dst_nx = 10
dst_ny = 10
! Establish the coordinates of the grids
dst_minx = 0.1
dst_miny = 0.1
dst_maxx = 1.9
dst_maxy = 1.9
! setup source Mesh
if (petCount .eq. 1) then
! Set number of nodes
numNodes=9
! Allocate and fill the node id array.
allocate(nodeIds(numNodes))
nodeIds=(/1,2,3,4,5,6,7,8,9/)
! Allocate and fill node coordinate array.
! Since this is a 2D Mesh the size is 2x the
! number of nodes.
allocate(nodeCoords(2*numNodes))
nodeCoords=(/0.0,0.0, & ! node id 1
1.0,0.0, & ! node id 2
2.0,0.0, & ! node id 3
0.0,1.0, & ! node id 4
1.0,1.0, & ! node id 5
2.0,1.0, & ! node id 6
0.0,2.0, & ! node id 7
1.0,2.0, & ! node id 8
2.0,2.0 /) ! node id 9
! Allocate and fill the node owner array.
! Since this Mesh is all on PET 0, it's just set to all 0.
allocate(nodeOwners(numNodes))
nodeOwners=0 ! everything on PET 0
! Set the number of each type of element, plus the total number.
numQuadElems=3
numTriElems=2
numTotElems=numQuadElems+numTriElems
! Allocate and fill the element id array.
allocate(elemIds(numTotElems))
elemIds=(/1,2,3,4,5/)
! Allocate and fill the element topology type array.
allocate(elemTypes(numTotElems))
elemTypes=(/ESMF_MESHELEMTYPE_QUAD, & ! elem id 1
ESMF_MESHELEMTYPE_TRI, & ! elem id 2
ESMF_MESHELEMTYPE_TRI, & ! elem id 3
ESMF_MESHELEMTYPE_QUAD, & ! elem id 4
ESMF_MESHELEMTYPE_QUAD/) ! elem id 5
! Allocate and fill the element connection type array.
! Note that entries in this array refer to the
! positions in the nodeIds, etc. arrays and that
! the order and number of entries for each element
! reflects that given in the Mesh options
! section for the corresponding entry
! in the elemTypes array.
allocate(elemConn(4*numQuadElems+3*numTriElems))
elemConn=(/1,2,5,4, & ! elem id 1
2,3,5, & ! elem id 2
3,6,5, & ! elem id 3
4,5,8,7, & ! elem id 4
5,6,9,8/) ! elem id 5
else if (petCount .eq. 4) then
! Setup mesh data depending on PET
if (localPET .eq. 0) then !!! This part only for PET 0
! Set number of nodes
numNodes=4
! Allocate and fill the node id array.
allocate(nodeIds(numNodes))
nodeIds=(/1,2,4,5/)
! Allocate and fill node coordinate array.
! Since this is a 2D Mesh the size is 2x the
! number of nodes.
allocate(nodeCoords(2*numNodes))
nodeCoords=(/0.0,0.0, & ! node id 1
1.0,0.0, & ! node id 2
0.0,1.0, & ! node id 4
1.0,1.0 /) ! node id 5
! Allocate and fill the node owner array.
allocate(nodeOwners(numNodes))
nodeOwners=(/0, & ! node id 1
0, & ! node id 2
0, & ! node id 4
0/) ! node id 5
! Set the number of each type of element, plus the total number.
numQuadElems=1
numTriElems=0
numTotElems=numQuadElems+numTriElems
! Allocate and fill the element id array.
allocate(elemIds(numTotElems))
elemIds=(/1/)
! Allocate and fill the element topology type array.
allocate(elemTypes(numTotElems))
elemTypes=(/ESMF_MESHELEMTYPE_QUAD/) ! elem id 1
! Allocate and fill the element connection type array.
! Note that entry are local indices
allocate(elemConn(4*numQuadElems+3*numTriElems))
elemConn=(/1,2,4,3/) ! elem id 1
else if (localPET .eq. 1) then !!! This part only for PET 1
! Set number of nodes
numNodes=4
! Allocate and fill the node id array.
allocate(nodeIds(numNodes))
nodeIds=(/2,3,5,6/)
! Allocate and fill node coordinate array.
! Since this is a 2D Mesh the size is 2x the
! number of nodes.
allocate(nodeCoords(2*numNodes))
nodeCoords=(/1.0,0.0, & ! node id 2
2.0,0.0, & ! node id 3
1.0,1.0, & ! node id 5
2.0,1.0 /) ! node id 6
! Allocate and fill the node owner array.
allocate(nodeOwners(numNodes))
nodeOwners=(/0, & ! node id 2
1, & ! node id 3
0, & ! node id 5
1/) ! node id 6
! Set the number of each type of element, plus the total number.
numQuadElems=0
numTriElems=2
numTotElems=numQuadElems+numTriElems
! Allocate and fill the element id array.
allocate(elemIds(numTotElems))
elemIds=(/2,3/)
! Allocate and fill the element topology type array.
allocate(elemTypes(numTotElems))
elemTypes=(/ESMF_MESHELEMTYPE_TRI, & ! elem id 2
ESMF_MESHELEMTYPE_TRI/) ! elem id 3
! Allocate and fill the element connection type array.
allocate(elemConn(4*numQuadElems+3*numTriElems))
elemConn=(/1,2,3, & ! elem id 2
2,4,3/) ! elem id 3
else if (localPET .eq. 2) then !!! This part only for PET 2
! Set number of nodes
numNodes=4
! Allocate and fill the node id array.
allocate(nodeIds(numNodes))
nodeIds=(/4,5,7,8/)
! Allocate and fill node coordinate array.
! Since this is a 2D Mesh the size is 2x the
! number of nodes.
allocate(nodeCoords(2*numNodes))
nodeCoords=(/0.0,1.0, & ! node id 4
1.0,1.0, & ! node id 5
0.0,2.0, & ! node id 7
1.0,2.0 /) ! node id 8
! Allocate and fill the node owner array.
! Since this Mesh is all on PET 0, it's just set to all 0.
allocate(nodeOwners(numNodes))
nodeOwners=(/0, & ! node id 4
0, & ! node id 5
2, & ! node id 7
2/) ! node id 8
! Set the number of each type of element, plus the total number.
numQuadElems=1
numTriElems=0
numTotElems=numQuadElems+numTriElems
! Allocate and fill the element id array.
allocate(elemIds(numTotElems))
elemIds=(/4/)
! Allocate and fill the element topology type array.
allocate(elemTypes(numTotElems))
elemTypes=(/ESMF_MESHELEMTYPE_QUAD/) ! elem id 4
! Allocate and fill the element connection type array.
allocate(elemConn(4*numQuadElems+3*numTriElems))
elemConn=(/1,2,4,3/) ! elem id 4
else if (localPET .eq. 3) then !!! This part only for PET 3
! Set number of nodes
numNodes=4
! Allocate and fill the node id array.
allocate(nodeIds(numNodes))
nodeIds=(/5,6,8,9/)
! Allocate and fill node coordinate array.
! Since this is a 2D Mesh the size is 2x the
! number of nodes.
allocate(nodeCoords(2*numNodes))
nodeCoords=(/1.0,1.0, & ! node id 5
2.0,1.0, & ! node id 6
1.0,2.0, & ! node id 8
2.0,2.0 /) ! node id 9
! Allocate and fill the node owner array.
allocate(nodeOwners(numNodes))
nodeOwners=(/0, & ! node id 5
1, & ! node id 6
2, & ! node id 8
3/) ! node id 9
! Set the number of each type of element, plus the total number.
numQuadElems=1
numTriElems=0
numTotElems=numQuadElems+numTriElems
! Allocate and fill the element id array.
allocate(elemIds(numTotElems))
elemIds=(/5/)
! Allocate and fill the element topology type array.
allocate(elemTypes(numTotElems))
elemTypes=(/ESMF_MESHELEMTYPE_QUAD/) ! elem id 5
! Allocate and fill the element connection type array.
allocate(elemConn(4*numQuadElems+3*numTriElems))
elemConn=(/1,2,4,3/) ! elem id 5
endif
endif
! Create Mesh structure in 1 step
srcMesh=ESMF_MeshCreate(parametricDim=2,spatialDim=2, &
coordSys=ESMF_COORDSYS_CART, &
nodeIds=nodeIds, nodeCoords=nodeCoords, &
nodeOwners=nodeOwners, elementIds=elemIds,&
elementTypes=elemTypes, elementConn=elemConn, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! Create source field
call ESMF_ArraySpecSet(arrayspec, 1, ESMF_TYPEKIND_R8, rc=rc)
srcField = ESMF_FieldCreate(srcMesh, arrayspec, &
name="source", rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! Load test data into the source Field
! Should only be 1 localDE
call ESMF_FieldGet(srcField, 0, farrayPtr1D, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! set interpolated function
i2=1
do i1=1,numNodes
if (nodeOwners(i1) .eq. localPet) then
! Get coordinates
x=nodeCoords(2*i1-1)
y=nodeCoords(2*i1)
! Set source function
farrayPtr1D(i2) = 20.0+x+y
! Advance to next owner
i2=i2+1
endif
enddo
! deallocate node data
deallocate(nodeIds)
deallocate(nodeCoords)
deallocate(nodeOwners)
! deallocate elem data
deallocate(elemIds)
deallocate(elemTypes)
deallocate(elemConn)
! setup dest. grid
dstGrid=ESMF_GridCreateNoPeriDim(minIndex=(/1,1/),maxIndex=(/dst_nx,dst_ny/),regDecomp=(/2,2/), &
coordSys=ESMF_COORDSYS_CART,indexflag=ESMF_INDEX_GLOBAL, &
rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! Create source/destination fields
call ESMF_ArraySpecSet(arrayspec, 2, ESMF_TYPEKIND_R8, rc=rc)
dstField = ESMF_FieldCreate(dstGrid, arrayspec, &
staggerloc=ESMF_STAGGERLOC_CENTER, name="dest", rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
call ESMF_GridAddCoord(dstGrid, staggerloc=ESMF_STAGGERLOC_CENTER, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! Get number of local DEs
call ESMF_GridGet(dstGrid, localDECount=localDECount, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! Get arrays
! dstArray
call ESMF_FieldGet(dstField, array=dstArray, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! srcArrayA
call ESMF_FieldGet(srcField, array=srcArrayA, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
! Destination grid
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
! Get memory and set coords for dst
do lDE=0,localDECount-1
!! get coords
call ESMF_GridGetCoord(dstGrid, localDE=lDE, staggerLoc=ESMF_STAGGERLOC_CENTER, coordDim=1, &
computationalLBound=clbnd, computationalUBound=cubnd, farrayPtr=farrayPtrXC, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
call ESMF_GridGetCoord(dstGrid, localDE=lDE, staggerLoc=ESMF_STAGGERLOC_CENTER, coordDim=2, &
computationalLBound=clbnd, computationalUBound=cubnd, farrayPtr=farrayPtrYC, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
call ESMF_FieldGet(dstField, lDE, farrayPtr, computationalLBound=fclbnd, &
computationalUBound=fcubnd, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
!! set coords
do i1=clbnd(1),cubnd(1)
do i2=clbnd(2),cubnd(2)
! Set source coordinates
farrayPtrXC(i1,i2) = ((dst_maxx-dst_minx)*REAL(i1-1)/REAL(dst_nx-1))+dst_minx
farrayPtrYC(i1,i2) = ((dst_maxy-dst_miny)*REAL(i2-1)/REAL(dst_ny-1))+dst_miny
! initialize destination field
farrayPtr(i1,i2)=0.0
enddo
enddo
enddo ! lDE
!!! Regrid forward from the A grid to the B grid
! Regrid store
call ESMF_FieldRegridStore( &
srcField, &
dstField=dstField, &
routeHandle=routeHandle, &
regridmethod=ESMF_REGRIDMETHOD_BILINEAR, &
rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! Do regrid
call ESMF_FieldRegrid(srcField, dstField, routeHandle, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
call ESMF_FieldRegridRelease(routeHandle, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! Check error
do lDE=0,localDECount-1
!! get coords
call ESMF_GridGetCoord(dstGrid, localDE=lDE, staggerLoc=ESMF_STAGGERLOC_CENTER, coordDim=1, &
farrayPtr=farrayPtrXC, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
call ESMF_GridGetCoord(dstGrid, localDE=lDE, staggerLoc=ESMF_STAGGERLOC_CENTER, coordDim=2, &
farrayPtr=farrayPtrYC, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
call ESMF_FieldGet(dstField, lDE, farrayPtr, computationalLBound=clbnd, &
computationalUBound=cubnd, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
!! check error
do i1=clbnd(1),cubnd(1)
do i2=clbnd(2),cubnd(2)
!! if error is too big report an error
if (abs(farrayPtr(i1,i2)-(20.0+farrayPtrXC(i1,i2)+farrayPtrYC(i1,i2))) > 0.0001) then
correct=.false.
endif
enddo
enddo
enddo ! lDE
! Uncomment these calls to see some actual regrid results
#if 0
spherical_grid = 0
call ESMF_MeshIO(vm, srcMesh, ESMF_STAGGERLOC_EDGE1, &
"srcmesh", srcArrayA, rc=localrc, &
spherical=spherical_grid)
call ESMF_MeshIO(vm, dstGrid, ESMF_STAGGERLOC_CENTER, &
"dstmesh", dstArray, rc=localrc, &
spherical=spherical_grid)
#endif
! Destroy the Fields
call ESMF_FieldDestroy(srcField, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
call ESMF_FieldDestroy(dstField, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! Free the grids
call ESMF_MeshDestroy(srcMesh, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
call ESMF_GridDestroy(dstGrid, rc=localrc)
if (localrc /=ESMF_SUCCESS) then
rc=ESMF_FAILURE
return
endif
! return answer based on correct flag
if (correct) then
rc=ESMF_SUCCESS
else
rc=ESMF_FAILURE
endif
end subroutine test_regridMeshToGrid