UseTheForce/DarkSide/simulation.F90

!!
!! Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
!!
!! The University of Notre Dame grants you ("Licensee") a
!! non-exclusive, royalty free, license to use, modify and
!! redistribute this software in source and binary code form, provided
!! that the following conditions are met:
!!
!! 1. Acknowledgement of the program authors must be made in any
!!    publication of scientific results based in part on use of the
!!    program.  An acceptable form of acknowledgement is citation of
!!    the article in which the program was described (Matthew
!!    A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
!!    J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
!!    Parallel Simulation Engine for Molecular Dynamics,"
!!    J. Comput. Chem. 26, pp. 252-271 (2005))
!!
!! 2. Redistributions of source code must retain the above copyright
!!    notice, this list of conditions and the following disclaimer.
!!
!! 3. Redistributions in binary form must reproduce the above copyright
!!    notice, this list of conditions and the following disclaimer in the
!!    documentation and/or other materials provided with the
!!    distribution.
!!
!! This software is provided "AS IS," without a warranty of any
!! kind. All express or implied conditions, representations and
!! warranties, including any implied warranty of merchantability,
!! fitness for a particular purpose or non-infringement, are hereby
!! excluded.  The University of Notre Dame and its licensors shall not
!! be liable for any damages suffered by licensee as a result of
!! using, modifying or distributing the software or its
!! derivatives. In no event will the University of Notre Dame or its
!! licensors be liable for any lost revenue, profit or data, or for
!! direct, indirect, special, consequential, incidental or punitive
!! damages, however caused and regardless of the theory of liability,
!! arising out of the use of or inability to use software, even if the
!! University of Notre Dame has been advised of the possibility of
!! such damages.
!!

!! Fortran interface to C entry plug.

module simulation
  use definitions
  use neighborLists
  use force_globals
  use vector_class
  use atype_module
  use switcheroo
#ifdef IS_MPI
  use mpiSimulation
#endif

  implicit none
  PRIVATE

#define __FORTRAN90
#include "brains/fSimulation.h"
#include "UseTheForce/fSwitchingFunction.h"

  type (simtype), public, save :: thisSim

  logical, save :: simulation_setup_complete = .false.

  integer, public, save :: nLocal, nGlobal
  integer, public, save :: nGroups, nGroupGlobal
  integer, public, save :: nExcludes_Global = 0
  integer, public, save :: nExcludes_Local = 0
  integer, allocatable, dimension(:,:), public :: excludesLocal
  integer, allocatable, dimension(:),   public :: excludesGlobal
  integer, allocatable, dimension(:),   public :: molMembershipList
  integer, allocatable, dimension(:),   public :: groupListRow
  integer, allocatable, dimension(:),   public :: groupStartRow
  integer, allocatable, dimension(:),   public :: groupListCol
  integer, allocatable, dimension(:),   public :: groupStartCol
  integer, allocatable, dimension(:),   public :: groupListLocal
  integer, allocatable, dimension(:),   public :: groupStartLocal
  integer, allocatable, dimension(:),   public :: nSkipsForAtom
  integer, allocatable, dimension(:,:), public :: skipsForAtom
  real(kind=dp), allocatable, dimension(:), public :: mfactRow
  real(kind=dp), allocatable, dimension(:), public :: mfactCol
  real(kind=dp), allocatable, dimension(:), public :: mfactLocal

  real(kind=dp), public, dimension(3,3), save :: Hmat, HmatInv
  logical, public, save :: boxIsOrthorhombic
  
  public :: SimulationSetup
  public :: getNlocal
  public :: setBox
  public :: getDielect
  public :: SimUsesPBC

  public :: SimUsesDirectionalAtoms
  public :: SimUsesLennardJones
  public :: SimUsesElectrostatics
  public :: SimUsesCharges
  public :: SimUsesDipoles
  public :: SimUsesSticky
  public :: SimUsesGayBerne
  public :: SimUsesEAM
  public :: SimUsesShapes
  public :: SimUsesFLARB
  public :: SimUsesRF
  public :: SimRequiresPrepairCalc
  public :: SimRequiresPostpairCalc

  
contains
  
  subroutine SimulationSetup(setThisSim, CnGlobal, CnLocal, c_idents, &
       CnLocalExcludes, CexcludesLocal, CnGlobalExcludes, CexcludesGlobal, &
       CmolMembership, Cmfact, CnGroups, CglobalGroupMembership, &
       status)    

    type (simtype) :: setThisSim
    integer, intent(inout) :: CnGlobal, CnLocal
    integer, dimension(CnLocal),intent(inout) :: c_idents

    integer :: CnLocalExcludes
    integer, dimension(2,CnLocalExcludes), intent(in) :: CexcludesLocal
    integer :: CnGlobalExcludes
    integer, dimension(CnGlobalExcludes), intent(in) :: CexcludesGlobal
    integer, dimension(CnGlobal),intent(in) :: CmolMembership 
    !!  Result status, success = 0, status = -1
    integer, intent(out) :: status
    integer :: i, j, me, thisStat, alloc_stat, myNode, id1, id2
    integer :: ia

    !! mass factors used for molecular cutoffs
    real ( kind = dp ), dimension(CnLocal) :: Cmfact
    integer, intent(in):: CnGroups
    integer, dimension(CnGlobal), intent(in):: CglobalGroupMembership
    integer :: maxSkipsForAtom, glPointer

#ifdef IS_MPI
    integer, allocatable, dimension(:) :: c_idents_Row
    integer, allocatable, dimension(:) :: c_idents_Col
    integer :: nAtomsInRow, nGroupsInRow, aid
    integer :: nAtomsInCol, nGroupsInCol, gid
#endif  

    simulation_setup_complete = .false.
    status = 0

    ! copy C struct into fortran type

    nLocal = CnLocal
    nGlobal = CnGlobal
    nGroups = CnGroups

    thisSim = setThisSim

    nExcludes_Global = CnGlobalExcludes
    nExcludes_Local = CnLocalExcludes

    call InitializeForceGlobals(nLocal, thisStat)
    if (thisStat /= 0) then
       write(default_error,*) "SimSetup: InitializeForceGlobals error"
       status = -1
       return
    endif

    call InitializeSimGlobals(thisStat)
    if (thisStat /= 0) then
       write(default_error,*) "SimSetup: InitializeSimGlobals error"
       status = -1
       return
    endif

#ifdef IS_MPI
    ! We can only set up forces if mpiSimulation has been setup.
    if (.not. isMPISimSet()) then
       write(default_error,*) "MPI is not set"
       status = -1
       return
    endif
    nAtomsInRow = getNatomsInRow(plan_atom_row)
    nAtomsInCol = getNatomsInCol(plan_atom_col)
    nGroupsInRow = getNgroupsInRow(plan_group_row)
    nGroupsInCol = getNgroupsInCol(plan_group_col)
    mynode = getMyNode()
    
    allocate(c_idents_Row(nAtomsInRow),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif

    allocate(c_idents_Col(nAtomsInCol),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif

    call gather(c_idents, c_idents_Row, plan_atom_row)
    call gather(c_idents, c_idents_Col, plan_atom_col)

    do i = 1, nAtomsInRow
       me = getFirstMatchingElement(atypes, "c_ident", c_idents_Row(i))
       atid_Row(i) = me
    enddo

    do i = 1, nAtomsInCol
       me = getFirstMatchingElement(atypes, "c_ident", c_idents_Col(i))
       atid_Col(i) = me
    enddo

    !! free temporary ident arrays
    if (allocated(c_idents_Col)) then
       deallocate(c_idents_Col)
    end if
    if (allocated(c_idents_Row)) then
       deallocate(c_idents_Row)
    endif
   
#endif

#ifdef IS_MPI
    allocate(groupStartRow(nGroupsInRow+1),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(groupStartCol(nGroupsInCol+1),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(groupListRow(nAtomsInRow),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(groupListCol(nAtomsInCol),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(mfactRow(nAtomsInRow),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(mfactCol(nAtomsInCol),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(mfactLocal(nLocal),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    
    glPointer = 1

    do i = 1, nGroupsInRow 

       gid = GroupRowToGlobal(i)
       groupStartRow(i) = glPointer       

       do j = 1, nAtomsInRow
          aid = AtomRowToGlobal(j)
          if (CglobalGroupMembership(aid) .eq. gid) then
             groupListRow(glPointer) = j
             glPointer = glPointer + 1
          endif
       enddo
    enddo
    groupStartRow(nGroupsInRow+1) = nAtomsInRow + 1

    glPointer = 1

    do i = 1, nGroupsInCol

       gid = GroupColToGlobal(i)
       groupStartCol(i) = glPointer       

       do j = 1, nAtomsInCol
          aid = AtomColToGlobal(j)
          if (CglobalGroupMembership(aid) .eq. gid) then
             groupListCol(glPointer) = j
             glPointer = glPointer + 1
          endif
       enddo
    enddo
    groupStartCol(nGroupsInCol+1) = nAtomsInCol + 1

    mfactLocal = Cmfact        

    call gather(mfactLocal,      mfactRow,      plan_atom_row)
    call gather(mfactLocal,      mfactCol,      plan_atom_col)
    
    if (allocated(mfactLocal)) then
       deallocate(mfactLocal)
    end if
#else
    allocate(groupStartRow(nGroups+1),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(groupStartCol(nGroups+1),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(groupListRow(nLocal),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(groupListCol(nLocal),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(mfactRow(nLocal),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(mfactCol(nLocal),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif
    allocate(mfactLocal(nLocal),stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       status = -1
       return
    endif

    glPointer = 1
    do i = 1, nGroups
       groupStartRow(i) = glPointer       
       groupStartCol(i) = glPointer
       do j = 1, nLocal
          if (CglobalGroupMembership(j) .eq. i) then
             groupListRow(glPointer) = j
             groupListCol(glPointer) = j
             glPointer = glPointer + 1
          endif
       enddo
    enddo
    groupStartRow(nGroups+1) = nLocal + 1
    groupStartCol(nGroups+1) = nLocal + 1

    do i = 1, nLocal
       mfactRow(i) = Cmfact(i)
       mfactCol(i) = Cmfact(i)
    end do
    
#endif


! We build the local atid's for both mpi and nonmpi
    do i = 1, nLocal
       
       me = getFirstMatchingElement(atypes, "c_ident", c_idents(i))
       atid(i) = me
  
    enddo

    do i = 1, nExcludes_Local
       excludesLocal(1,i) = CexcludesLocal(1,i)
       excludesLocal(2,i) = CexcludesLocal(2,i)
    enddo

#ifdef IS_MPI
    allocate(nSkipsForAtom(nAtomsInRow), stat=alloc_stat)
#else
    allocate(nSkipsForAtom(nLocal), stat=alloc_stat)
#endif
    if (alloc_stat /= 0 ) then
       thisStat = -1
       write(*,*) 'Could not allocate nSkipsForAtom array'
       return
    endif

    maxSkipsForAtom = 0
#ifdef IS_MPI
    do j = 1, nAtomsInRow
#else
    do j = 1, nLocal
#endif
       nSkipsForAtom(j) = 0
#ifdef IS_MPI
       id1 = AtomRowToGlobal(j)
#else 
       id1 = j
#endif
       do i = 1, nExcludes_Local
          if (excludesLocal(1,i) .eq. id1 ) then
             nSkipsForAtom(j) = nSkipsForAtom(j) + 1

             if (nSkipsForAtom(j) .gt. maxSkipsForAtom) then
                maxSkipsForAtom = nSkipsForAtom(j)
             endif
          endif
          if (excludesLocal(2,i) .eq. id1 ) then
             nSkipsForAtom(j) = nSkipsForAtom(j) + 1

             if (nSkipsForAtom(j) .gt. maxSkipsForAtom) then
                maxSkipsForAtom = nSkipsForAtom(j)
             endif
          endif
       end do
    enddo

#ifdef IS_MPI
    allocate(skipsForAtom(nAtomsInRow, maxSkipsForAtom), stat=alloc_stat)
#else
    allocate(skipsForAtom(nLocal, maxSkipsForAtom), stat=alloc_stat)
#endif
    if (alloc_stat /= 0 ) then
       write(*,*) 'Could not allocate skipsForAtom array'
       return
    endif

#ifdef IS_MPI
    do j = 1, nAtomsInRow
#else
    do j = 1, nLocal
#endif
       nSkipsForAtom(j) = 0
#ifdef IS_MPI
       id1 = AtomRowToGlobal(j)
#else 
       id1 = j
#endif
       do i = 1, nExcludes_Local
          if (excludesLocal(1,i) .eq. id1 ) then
             nSkipsForAtom(j) = nSkipsForAtom(j) + 1
             ! exclude lists have global ID's so this line is 
             ! the same in MPI and non-MPI
             id2 = excludesLocal(2,i)
             skipsForAtom(j, nSkipsForAtom(j)) = id2
          endif
          if (excludesLocal(2, i) .eq. id1 ) then
             nSkipsForAtom(j) = nSkipsForAtom(j) + 1
             ! exclude lists have global ID's so this line is 
             ! the same in MPI and non-MPI
             id2 = excludesLocal(1,i)
             skipsForAtom(j, nSkipsForAtom(j)) = id2
          endif
       end do
    enddo
    
    do i = 1, nExcludes_Global
       excludesGlobal(i) = CexcludesGlobal(i)
    enddo

    do i = 1, nGlobal
       molMemberShipList(i) = CmolMembership(i)
    enddo
    
    if (status == 0) simulation_setup_complete = .true.
    
  end subroutine SimulationSetup
  
  subroutine setBox(cHmat, cHmatInv, cBoxIsOrthorhombic)
    real(kind=dp), dimension(3,3) :: cHmat, cHmatInv
    integer :: cBoxIsOrthorhombic
    integer :: smallest, status, i
    
    Hmat = cHmat
    HmatInv = cHmatInv
    if (cBoxIsOrthorhombic .eq. 0 ) then
       boxIsOrthorhombic = .false.
    else 
       boxIsOrthorhombic = .true.
    endif
    
    return     
  end subroutine setBox

  function getDielect() result(dielect)
    real( kind = dp ) :: dielect
    dielect = thisSim%dielect
  end function getDielect
       
  function SimUsesPBC() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_PBC
  end function SimUsesPBC

  function SimUsesDirectionalAtoms() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_dipoles .or. thisSim%SIM_uses_sticky .or. &
         thisSim%SIM_uses_GayBerne .or. thisSim%SIM_uses_Shapes
  end function SimUsesDirectionalAtoms

  function SimUsesLennardJones() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_LennardJones
  end function SimUsesLennardJones

  function SimUsesElectrostatics() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_Electrostatics
  end function SimUsesElectrostatics

  function SimUsesCharges() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_Charges
  end function SimUsesCharges

  function SimUsesDipoles() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_Dipoles
  end function SimUsesDipoles

  function SimUsesSticky() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_Sticky
  end function SimUsesSticky

  function SimUsesGayBerne() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_GayBerne
  end function SimUsesGayBerne
  
  function SimUsesEAM() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_EAM
  end function SimUsesEAM

  function SimUsesShapes() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_Shapes
  end function SimUsesShapes

  function SimUsesFLARB() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_FLARB
  end function SimUsesFLARB

  function SimUsesRF() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_RF
  end function SimUsesRF

  function SimRequiresPrepairCalc() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_EAM
  end function SimRequiresPrepairCalc

  function SimRequiresPostpairCalc() result(doesit)
    logical :: doesit
    doesit = thisSim%SIM_uses_RF
  end function SimRequiresPostpairCalc
  
  subroutine InitializeSimGlobals(thisStat)
    integer, intent(out) :: thisStat
    integer :: alloc_stat
    
    thisStat = 0
    
    call FreeSimGlobals()    
    
    allocate(excludesLocal(2,nExcludes_Local), stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       thisStat = -1
       return
    endif
    
    allocate(excludesGlobal(nExcludes_Global), stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       thisStat = -1
       return
    endif

    allocate(molMembershipList(nGlobal), stat=alloc_stat)
    if (alloc_stat /= 0 ) then
       thisStat = -1
       return
    endif
    
  end subroutine InitializeSimGlobals
  
  subroutine FreeSimGlobals()
    
    !We free in the opposite order in which we allocate in.

    if (allocated(skipsForAtom)) deallocate(skipsForAtom)
    if (allocated(nSkipsForAtom)) deallocate(nSkipsForAtom)
    if (allocated(mfactLocal)) deallocate(mfactLocal)
    if (allocated(mfactCol)) deallocate(mfactCol)
    if (allocated(mfactRow)) deallocate(mfactRow)
    if (allocated(groupListCol)) deallocate(groupListCol)     
    if (allocated(groupListRow)) deallocate(groupListRow)    
    if (allocated(groupStartCol)) deallocate(groupStartCol)
    if (allocated(groupStartRow)) deallocate(groupStartRow)     
    if (allocated(molMembershipList)) deallocate(molMembershipList)     
    if (allocated(excludesGlobal)) deallocate(excludesGlobal)
    if (allocated(excludesLocal)) deallocate(excludesLocal)
    
  end subroutine FreeSimGlobals
  
  pure function getNlocal() result(n)
    integer :: n
    n = nLocal
  end function getNlocal
  
end module simulation
Revision:	264
Committed:	Fri Jan 14 20:31:16 2005 UTC (20 years, 4 months ago) by gezelter
File size:	17783 byte(s)
Log Message:	separating modules and C/Fortran interface subroutines
#	User	Rev	Content
1	gezelter	246	!!
2			!! Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
3			!!
4			!! The University of Notre Dame grants you ("Licensee") a
5			!! non-exclusive, royalty free, license to use, modify and
6			!! redistribute this software in source and binary code form, provided
7			!! that the following conditions are met:
8			!!
9			!! 1. Acknowledgement of the program authors must be made in any
10			!! publication of scientific results based in part on use of the
11			!! program. An acceptable form of acknowledgement is citation of
12			!! the article in which the program was described (Matthew
13			!! A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
14			!! J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
15			!! Parallel Simulation Engine for Molecular Dynamics,"
16			!! J. Comput. Chem. 26, pp. 252-271 (2005))
17			!!
18			!! 2. Redistributions of source code must retain the above copyright
19			!! notice, this list of conditions and the following disclaimer.
20			!!
21			!! 3. Redistributions in binary form must reproduce the above copyright
22			!! notice, this list of conditions and the following disclaimer in the
23			!! documentation and/or other materials provided with the
24			!! distribution.
25			!!
26			!! This software is provided "AS IS," without a warranty of any
27			!! kind. All express or implied conditions, representations and
28			!! warranties, including any implied warranty of merchantability,
29			!! fitness for a particular purpose or non-infringement, are hereby
30			!! excluded. The University of Notre Dame and its licensors shall not
31			!! be liable for any damages suffered by licensee as a result of
32			!! using, modifying or distributing the software or its
33			!! derivatives. In no event will the University of Notre Dame or its
34			!! licensors be liable for any lost revenue, profit or data, or for
35			!! direct, indirect, special, consequential, incidental or punitive
36			!! damages, however caused and regardless of the theory of liability,
37			!! arising out of the use of or inability to use software, even if the
38			!! University of Notre Dame has been advised of the possibility of
39			!! such damages.
40			!!
41
42	gezelter	115	!! Fortran interface to C entry plug.
43
44			module simulation
45			use definitions
46			use neighborLists
47			use force_globals
48			use vector_class
49			use atype_module
50			use switcheroo
51			#ifdef IS_MPI
52			use mpiSimulation
53			#endif
54
55			implicit none
56			PRIVATE
57
58			#define __FORTRAN90
59			#include "brains/fSimulation.h"
60			#include "UseTheForce/fSwitchingFunction.h"
61
62			type (simtype), public, save :: thisSim
63
64			logical, save :: simulation_setup_complete = .false.
65
66			integer, public, save :: nLocal, nGlobal
67			integer, public, save :: nGroups, nGroupGlobal
68			integer, public, save :: nExcludes_Global = 0
69			integer, public, save :: nExcludes_Local = 0
70			integer, allocatable, dimension(:,:), public :: excludesLocal
71			integer, allocatable, dimension(:), public :: excludesGlobal
72			integer, allocatable, dimension(:), public :: molMembershipList
73			integer, allocatable, dimension(:), public :: groupListRow
74			integer, allocatable, dimension(:), public :: groupStartRow
75			integer, allocatable, dimension(:), public :: groupListCol
76			integer, allocatable, dimension(:), public :: groupStartCol
77			integer, allocatable, dimension(:), public :: groupListLocal
78			integer, allocatable, dimension(:), public :: groupStartLocal
79			integer, allocatable, dimension(:), public :: nSkipsForAtom
80			integer, allocatable, dimension(:,:), public :: skipsForAtom
81			real(kind=dp), allocatable, dimension(:), public :: mfactRow
82			real(kind=dp), allocatable, dimension(:), public :: mfactCol
83			real(kind=dp), allocatable, dimension(:), public :: mfactLocal
84
85			real(kind=dp), public, dimension(3,3), save :: Hmat, HmatInv
86			logical, public, save :: boxIsOrthorhombic
87
88			public :: SimulationSetup
89			public :: getNlocal
90			public :: setBox
91			public :: getDielect
92			public :: SimUsesPBC
93	gezelter	140
94			public :: SimUsesDirectionalAtoms
95			public :: SimUsesLennardJones
96			public :: SimUsesElectrostatics
97	gezelter	115	public :: SimUsesCharges
98			public :: SimUsesDipoles
99			public :: SimUsesSticky
100	gezelter	140	public :: SimUsesGayBerne
101			public :: SimUsesEAM
102			public :: SimUsesShapes
103			public :: SimUsesFLARB
104	gezelter	115	public :: SimUsesRF
105			public :: SimRequiresPrepairCalc
106			public :: SimRequiresPostpairCalc
107	gezelter	140
108	gezelter	115
109			contains
110
111			subroutine SimulationSetup(setThisSim, CnGlobal, CnLocal, c_idents, &
112			CnLocalExcludes, CexcludesLocal, CnGlobalExcludes, CexcludesGlobal, &
113			CmolMembership, Cmfact, CnGroups, CglobalGroupMembership, &
114			status)
115
116			type (simtype) :: setThisSim
117			integer, intent(inout) :: CnGlobal, CnLocal
118			integer, dimension(CnLocal),intent(inout) :: c_idents
119
120			integer :: CnLocalExcludes
121			integer, dimension(2,CnLocalExcludes), intent(in) :: CexcludesLocal
122			integer :: CnGlobalExcludes
123			integer, dimension(CnGlobalExcludes), intent(in) :: CexcludesGlobal
124			integer, dimension(CnGlobal),intent(in) :: CmolMembership
125			!! Result status, success = 0, status = -1
126			integer, intent(out) :: status
127			integer :: i, j, me, thisStat, alloc_stat, myNode, id1, id2
128			integer :: ia
129
130			!! mass factors used for molecular cutoffs
131			real ( kind = dp ), dimension(CnLocal) :: Cmfact
132			integer, intent(in):: CnGroups
133			integer, dimension(CnGlobal), intent(in):: CglobalGroupMembership
134			integer :: maxSkipsForAtom, glPointer
135
136			#ifdef IS_MPI
137			integer, allocatable, dimension(:) :: c_idents_Row
138			integer, allocatable, dimension(:) :: c_idents_Col
139			integer :: nAtomsInRow, nGroupsInRow, aid
140			integer :: nAtomsInCol, nGroupsInCol, gid
141			#endif
142
143			simulation_setup_complete = .false.
144			status = 0
145
146			! copy C struct into fortran type
147
148			nLocal = CnLocal
149			nGlobal = CnGlobal
150			nGroups = CnGroups
151
152			thisSim = setThisSim
153
154			nExcludes_Global = CnGlobalExcludes
155			nExcludes_Local = CnLocalExcludes
156
157			call InitializeForceGlobals(nLocal, thisStat)
158			if (thisStat /= 0) then
159			write(default_error,*) "SimSetup: InitializeForceGlobals error"
160			status = -1
161			return
162			endif
163
164			call InitializeSimGlobals(thisStat)
165			if (thisStat /= 0) then
166			write(default_error,*) "SimSetup: InitializeSimGlobals error"
167			status = -1
168			return
169			endif
170
171			#ifdef IS_MPI
172			! We can only set up forces if mpiSimulation has been setup.
173			if (.not. isMPISimSet()) then
174			write(default_error,*) "MPI is not set"
175			status = -1
176			return
177			endif
178			nAtomsInRow = getNatomsInRow(plan_atom_row)
179			nAtomsInCol = getNatomsInCol(plan_atom_col)
180			nGroupsInRow = getNgroupsInRow(plan_group_row)
181			nGroupsInCol = getNgroupsInCol(plan_group_col)
182			mynode = getMyNode()
183
184			allocate(c_idents_Row(nAtomsInRow),stat=alloc_stat)
185			if (alloc_stat /= 0 ) then
186			status = -1
187			return
188			endif
189
190			allocate(c_idents_Col(nAtomsInCol),stat=alloc_stat)
191			if (alloc_stat /= 0 ) then
192			status = -1
193			return
194			endif
195
196			call gather(c_idents, c_idents_Row, plan_atom_row)
197			call gather(c_idents, c_idents_Col, plan_atom_col)
198
199			do i = 1, nAtomsInRow
200			me = getFirstMatchingElement(atypes, "c_ident", c_idents_Row(i))
201			atid_Row(i) = me
202			enddo
203
204			do i = 1, nAtomsInCol
205			me = getFirstMatchingElement(atypes, "c_ident", c_idents_Col(i))
206			atid_Col(i) = me
207			enddo
208
209			!! free temporary ident arrays
210			if (allocated(c_idents_Col)) then
211			deallocate(c_idents_Col)
212			end if
213			if (allocated(c_idents_Row)) then
214			deallocate(c_idents_Row)
215			endif
216
217			#endif
218
219			#ifdef IS_MPI
220			allocate(groupStartRow(nGroupsInRow+1),stat=alloc_stat)
221			if (alloc_stat /= 0 ) then
222			status = -1
223			return
224			endif
225			allocate(groupStartCol(nGroupsInCol+1),stat=alloc_stat)
226			if (alloc_stat /= 0 ) then
227			status = -1
228			return
229			endif
230			allocate(groupListRow(nAtomsInRow),stat=alloc_stat)
231			if (alloc_stat /= 0 ) then
232			status = -1
233			return
234			endif
235			allocate(groupListCol(nAtomsInCol),stat=alloc_stat)
236			if (alloc_stat /= 0 ) then
237			status = -1
238			return
239			endif
240			allocate(mfactRow(nAtomsInRow),stat=alloc_stat)
241			if (alloc_stat /= 0 ) then
242			status = -1
243			return
244			endif
245			allocate(mfactCol(nAtomsInCol),stat=alloc_stat)
246			if (alloc_stat /= 0 ) then
247			status = -1
248			return
249			endif
250			allocate(mfactLocal(nLocal),stat=alloc_stat)
251			if (alloc_stat /= 0 ) then
252			status = -1
253			return
254			endif
255
256			glPointer = 1
257
258			do i = 1, nGroupsInRow
259
260			gid = GroupRowToGlobal(i)
261			groupStartRow(i) = glPointer
262
263			do j = 1, nAtomsInRow
264			aid = AtomRowToGlobal(j)
265			if (CglobalGroupMembership(aid) .eq. gid) then
266			groupListRow(glPointer) = j
267			glPointer = glPointer + 1
268			endif
269			enddo
270			enddo
271			groupStartRow(nGroupsInRow+1) = nAtomsInRow + 1
272
273			glPointer = 1
274
275			do i = 1, nGroupsInCol
276
277			gid = GroupColToGlobal(i)
278			groupStartCol(i) = glPointer
279
280			do j = 1, nAtomsInCol
281			aid = AtomColToGlobal(j)
282			if (CglobalGroupMembership(aid) .eq. gid) then
283			groupListCol(glPointer) = j
284			glPointer = glPointer + 1
285			endif
286			enddo
287			enddo
288			groupStartCol(nGroupsInCol+1) = nAtomsInCol + 1
289
290			mfactLocal = Cmfact
291
292			call gather(mfactLocal, mfactRow, plan_atom_row)
293			call gather(mfactLocal, mfactCol, plan_atom_col)
294
295			if (allocated(mfactLocal)) then
296			deallocate(mfactLocal)
297			end if
298			#else
299			allocate(groupStartRow(nGroups+1),stat=alloc_stat)
300			if (alloc_stat /= 0 ) then
301			status = -1
302			return
303			endif
304			allocate(groupStartCol(nGroups+1),stat=alloc_stat)
305			if (alloc_stat /= 0 ) then
306			status = -1
307			return
308			endif
309			allocate(groupListRow(nLocal),stat=alloc_stat)
310			if (alloc_stat /= 0 ) then
311			status = -1
312			return
313			endif
314			allocate(groupListCol(nLocal),stat=alloc_stat)
315			if (alloc_stat /= 0 ) then
316			status = -1
317			return
318			endif
319			allocate(mfactRow(nLocal),stat=alloc_stat)
320			if (alloc_stat /= 0 ) then
321			status = -1
322			return
323			endif
324			allocate(mfactCol(nLocal),stat=alloc_stat)
325			if (alloc_stat /= 0 ) then
326			status = -1
327			return
328			endif
329			allocate(mfactLocal(nLocal),stat=alloc_stat)
330			if (alloc_stat /= 0 ) then
331			status = -1
332			return
333			endif
334
335			glPointer = 1
336			do i = 1, nGroups
337			groupStartRow(i) = glPointer
338			groupStartCol(i) = glPointer
339			do j = 1, nLocal
340			if (CglobalGroupMembership(j) .eq. i) then
341			groupListRow(glPointer) = j
342			groupListCol(glPointer) = j
343			glPointer = glPointer + 1
344			endif
345			enddo
346			enddo
347			groupStartRow(nGroups+1) = nLocal + 1
348			groupStartCol(nGroups+1) = nLocal + 1
349
350			do i = 1, nLocal
351			mfactRow(i) = Cmfact(i)
352			mfactCol(i) = Cmfact(i)
353			end do
354
355			#endif
356
357
358			! We build the local atid's for both mpi and nonmpi
359			do i = 1, nLocal
360
361			me = getFirstMatchingElement(atypes, "c_ident", c_idents(i))
362			atid(i) = me
363
364			enddo
365
366			do i = 1, nExcludes_Local
367			excludesLocal(1,i) = CexcludesLocal(1,i)
368			excludesLocal(2,i) = CexcludesLocal(2,i)
369			enddo
370
371			#ifdef IS_MPI
372			allocate(nSkipsForAtom(nAtomsInRow), stat=alloc_stat)
373			#else
374			allocate(nSkipsForAtom(nLocal), stat=alloc_stat)
375			#endif
376			if (alloc_stat /= 0 ) then
377			thisStat = -1
378			write(,) 'Could not allocate nSkipsForAtom array'
379			return
380			endif
381
382			maxSkipsForAtom = 0
383			#ifdef IS_MPI
384			do j = 1, nAtomsInRow
385			#else
386			do j = 1, nLocal
387			#endif
388			nSkipsForAtom(j) = 0
389			#ifdef IS_MPI
390			id1 = AtomRowToGlobal(j)
391			#else
392			id1 = j
393			#endif
394			do i = 1, nExcludes_Local
395			if (excludesLocal(1,i) .eq. id1 ) then
396			nSkipsForAtom(j) = nSkipsForAtom(j) + 1
397
398			if (nSkipsForAtom(j) .gt. maxSkipsForAtom) then
399			maxSkipsForAtom = nSkipsForAtom(j)
400			endif
401			endif
402			if (excludesLocal(2,i) .eq. id1 ) then
403			nSkipsForAtom(j) = nSkipsForAtom(j) + 1
404
405			if (nSkipsForAtom(j) .gt. maxSkipsForAtom) then
406			maxSkipsForAtom = nSkipsForAtom(j)
407			endif
408			endif
409			end do
410			enddo
411
412			#ifdef IS_MPI
413			allocate(skipsForAtom(nAtomsInRow, maxSkipsForAtom), stat=alloc_stat)
414			#else
415			allocate(skipsForAtom(nLocal, maxSkipsForAtom), stat=alloc_stat)
416			#endif
417			if (alloc_stat /= 0 ) then
418			write(,) 'Could not allocate skipsForAtom array'
419			return
420			endif
421
422			#ifdef IS_MPI
423			do j = 1, nAtomsInRow
424			#else
425			do j = 1, nLocal
426			#endif
427			nSkipsForAtom(j) = 0
428			#ifdef IS_MPI
429			id1 = AtomRowToGlobal(j)
430			#else
431			id1 = j
432			#endif
433			do i = 1, nExcludes_Local
434			if (excludesLocal(1,i) .eq. id1 ) then
435			nSkipsForAtom(j) = nSkipsForAtom(j) + 1
436			! exclude lists have global ID's so this line is
437			! the same in MPI and non-MPI
438			id2 = excludesLocal(2,i)
439			skipsForAtom(j, nSkipsForAtom(j)) = id2
440			endif
441			if (excludesLocal(2, i) .eq. id1 ) then
442			nSkipsForAtom(j) = nSkipsForAtom(j) + 1
443			! exclude lists have global ID's so this line is
444			! the same in MPI and non-MPI
445			id2 = excludesLocal(1,i)
446			skipsForAtom(j, nSkipsForAtom(j)) = id2
447			endif
448			end do
449			enddo
450
451			do i = 1, nExcludes_Global
452			excludesGlobal(i) = CexcludesGlobal(i)
453			enddo
454
455			do i = 1, nGlobal
456			molMemberShipList(i) = CmolMembership(i)
457			enddo
458
459			if (status == 0) simulation_setup_complete = .true.
460
461			end subroutine SimulationSetup
462
463			subroutine setBox(cHmat, cHmatInv, cBoxIsOrthorhombic)
464			real(kind=dp), dimension(3,3) :: cHmat, cHmatInv
465			integer :: cBoxIsOrthorhombic
466			integer :: smallest, status, i
467
468			Hmat = cHmat
469			HmatInv = cHmatInv
470			if (cBoxIsOrthorhombic .eq. 0 ) then
471			boxIsOrthorhombic = .false.
472			else
473			boxIsOrthorhombic = .true.
474			endif
475
476			return
477			end subroutine setBox
478
479			function getDielect() result(dielect)
480			real( kind = dp ) :: dielect
481			dielect = thisSim%dielect
482			end function getDielect
483
484			function SimUsesPBC() result(doesit)
485			logical :: doesit
486			doesit = thisSim%SIM_uses_PBC
487			end function SimUsesPBC
488
489	gezelter	140	function SimUsesDirectionalAtoms() result(doesit)
490	gezelter	115	logical :: doesit
491	gezelter	140	doesit = thisSim%SIM_uses_dipoles .or. thisSim%SIM_uses_sticky .or. &
492			thisSim%SIM_uses_GayBerne .or. thisSim%SIM_uses_Shapes
493			end function SimUsesDirectionalAtoms
494	gezelter	115
495	gezelter	140	function SimUsesLennardJones() result(doesit)
496	gezelter	115	logical :: doesit
497	gezelter	140	doesit = thisSim%SIM_uses_LennardJones
498			end function SimUsesLennardJones
499	gezelter	115
500	gezelter	140	function SimUsesElectrostatics() result(doesit)
501			logical :: doesit
502			doesit = thisSim%SIM_uses_Electrostatics
503			end function SimUsesElectrostatics
504
505	gezelter	115	function SimUsesCharges() result(doesit)
506			logical :: doesit
507	gezelter	140	doesit = thisSim%SIM_uses_Charges
508	gezelter	115	end function SimUsesCharges
509
510			function SimUsesDipoles() result(doesit)
511			logical :: doesit
512	gezelter	140	doesit = thisSim%SIM_uses_Dipoles
513	gezelter	115	end function SimUsesDipoles
514
515	gezelter	140	function SimUsesSticky() result(doesit)
516	gezelter	115	logical :: doesit
517	gezelter	140	doesit = thisSim%SIM_uses_Sticky
518			end function SimUsesSticky
519	gezelter	115
520	gezelter	140	function SimUsesGayBerne() result(doesit)
521	gezelter	115	logical :: doesit
522	gezelter	140	doesit = thisSim%SIM_uses_GayBerne
523			end function SimUsesGayBerne
524
525	gezelter	115	function SimUsesEAM() result(doesit)
526			logical :: doesit
527			doesit = thisSim%SIM_uses_EAM
528			end function SimUsesEAM
529
530	gezelter	140	function SimUsesShapes() result(doesit)
531	gezelter	115	logical :: doesit
532	gezelter	140	doesit = thisSim%SIM_uses_Shapes
533			end function SimUsesShapes
534	gezelter	115
535	gezelter	140	function SimUsesFLARB() result(doesit)
536			logical :: doesit
537			doesit = thisSim%SIM_uses_FLARB
538			end function SimUsesFLARB
539
540			function SimUsesRF() result(doesit)
541			logical :: doesit
542			doesit = thisSim%SIM_uses_RF
543			end function SimUsesRF
544
545	gezelter	115	function SimRequiresPrepairCalc() result(doesit)
546			logical :: doesit
547			doesit = thisSim%SIM_uses_EAM
548			end function SimRequiresPrepairCalc
549
550			function SimRequiresPostpairCalc() result(doesit)
551			logical :: doesit
552			doesit = thisSim%SIM_uses_RF
553			end function SimRequiresPostpairCalc
554
555			subroutine InitializeSimGlobals(thisStat)
556			integer, intent(out) :: thisStat
557			integer :: alloc_stat
558
559			thisStat = 0
560
561			call FreeSimGlobals()
562
563			allocate(excludesLocal(2,nExcludes_Local), stat=alloc_stat)
564			if (alloc_stat /= 0 ) then
565			thisStat = -1
566			return
567			endif
568
569			allocate(excludesGlobal(nExcludes_Global), stat=alloc_stat)
570			if (alloc_stat /= 0 ) then
571			thisStat = -1
572			return
573			endif
574
575			allocate(molMembershipList(nGlobal), stat=alloc_stat)
576			if (alloc_stat /= 0 ) then
577			thisStat = -1
578			return
579			endif
580
581			end subroutine InitializeSimGlobals
582
583			subroutine FreeSimGlobals()
584
585			!We free in the opposite order in which we allocate in.
586
587			if (allocated(skipsForAtom)) deallocate(skipsForAtom)
588			if (allocated(nSkipsForAtom)) deallocate(nSkipsForAtom)
589			if (allocated(mfactLocal)) deallocate(mfactLocal)
590			if (allocated(mfactCol)) deallocate(mfactCol)
591			if (allocated(mfactRow)) deallocate(mfactRow)
592			if (allocated(groupListCol)) deallocate(groupListCol)
593			if (allocated(groupListRow)) deallocate(groupListRow)
594			if (allocated(groupStartCol)) deallocate(groupStartCol)
595			if (allocated(groupStartRow)) deallocate(groupStartRow)
596			if (allocated(molMembershipList)) deallocate(molMembershipList)
597			if (allocated(excludesGlobal)) deallocate(excludesGlobal)
598			if (allocated(excludesLocal)) deallocate(excludesLocal)
599
600			end subroutine FreeSimGlobals
601
602			pure function getNlocal() result(n)
603			integer :: n
604			n = nLocal
605			end function getNlocal
606
607			end module simulation