UseTheForce/DarkSide/eam.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.
!!

module eam
  use simulation
  use force_globals
  use status
  use atype_module
  use vector_class
  use interpolation
#ifdef IS_MPI
  use mpiSimulation
#endif
  implicit none
  PRIVATE
#define __FORTRAN90
#include "UseTheForce/DarkSide/fInteractionMap.h"

  INTEGER, PARAMETER :: DP = selected_real_kind(15)

  logical, save :: EAM_FF_initialized = .false.
  integer, save :: EAM_Mixing_Policy
  real(kind = dp), save :: EAM_rcut
  logical, save :: haveRcut = .false.

  character(len = statusMsgSize) :: errMesg
  integer :: eam_err

  character(len = 200) :: errMsg
  character(len=*), parameter :: RoutineName =  "EAM MODULE"
  !! Logical that determines if eam arrays should be zeroed
  logical :: cleanme = .true.

  type, private :: EAMtype
     integer           :: eam_atype       
     real( kind = DP ) :: eam_lattice        
     real( kind = DP ) :: eam_rcut     
     integer           :: eam_atype_map
     type(cubicSpline) :: rho 
     type(cubicSpline) :: Z
     type(cubicSpline) :: F
     type(cubicSpline) :: phi
  end type EAMtype

  !! Arrays for derivatives used in force calculation
  real( kind = dp), dimension(:), allocatable :: frho
  real( kind = dp), dimension(:), allocatable :: rho
  real( kind = dp), dimension(:), allocatable :: dfrhodrho

  !! Arrays for MPI storage
#ifdef IS_MPI
  real( kind = dp),save, dimension(:), allocatable :: dfrhodrho_col
  real( kind = dp),save, dimension(:), allocatable :: dfrhodrho_row
  real( kind = dp),save, dimension(:), allocatable :: frho_row
  real( kind = dp),save, dimension(:), allocatable :: frho_col
  real( kind = dp),save, dimension(:), allocatable :: rho_row
  real( kind = dp),save, dimension(:), allocatable :: rho_col
  real( kind = dp),save, dimension(:), allocatable :: rho_tmp
#endif

  type, private :: EAMTypeList
     integer           :: n_eam_types = 0
     integer           :: currentAddition = 0

     type (EAMtype), pointer  :: EAMParams(:) => null()
     integer, pointer         :: atidToEAMType(:) => null()
  end type EAMTypeList

  type (eamTypeList), save :: EAMList

  !! standard eam stuff  


  public :: init_EAM_FF
  public :: setCutoffEAM
  public :: do_eam_pair
  public :: newEAMtype
  public :: calc_eam_prepair_rho
  public :: calc_eam_preforce_Frho
  public :: clean_EAM
  public :: destroyEAMTypes
  public :: getEAMCut

contains

  subroutine newEAMtype(lattice_constant,eam_nrho,eam_drho,eam_nr,&
       eam_dr,rcut,eam_Z_r,eam_rho_r,eam_F_rho, c_ident, status)
    real (kind = dp )                      :: lattice_constant
    integer                                :: eam_nrho
    real (kind = dp )                      :: eam_drho
    integer                                :: eam_nr
    real (kind = dp )                      :: eam_dr
    real (kind = dp )                      :: rcut
    real (kind = dp ), dimension(eam_nr)   :: eam_Z_r, rvals
    real (kind = dp ), dimension(eam_nr)   :: eam_rho_r, eam_phi_r
    real (kind = dp ), dimension(eam_nrho) :: eam_F_rho, rhovals
    integer                                :: c_ident
    integer                                :: status

    integer                                :: nAtypes,nEAMTypes,myATID
    integer                                :: maxVals
    integer                                :: alloc_stat
    integer                                :: current, j
    integer,pointer                        :: Matchlist(:) => null()

    status = 0

    !! Assume that atypes has already been set and get the total number of types in atypes
    !! Also assume that every member of atypes is a EAM model.

    ! check to see if this is the first time into 
    if (.not.associated(EAMList%EAMParams)) then
       call getMatchingElementList(atypes, "is_EAM", .true., nEAMtypes, MatchList)
       EAMList%n_eam_types = nEAMtypes
       allocate(EAMList%EAMParams(nEAMTypes))
       nAtypes = getSize(atypes)
       allocate(EAMList%atidToEAMType(nAtypes))
    end if

    EAMList%currentAddition = EAMList%currentAddition + 1
    current = EAMList%currentAddition

    myATID =  getFirstMatchingElement(atypes, "c_ident", c_ident)
    EAMList%atidToEAMType(myATID) = current

    EAMList%EAMParams(current)%eam_atype    = c_ident
    EAMList%EAMParams(current)%eam_lattice  = lattice_constant
    EAMList%EAMParams(current)%eam_rcut     = rcut

    ! Build array of r values
    do j = 1, eam_nr
       rvals(j) = real(j-1,kind=dp) * eam_dr
    end do
    
    ! Build array of rho values
    do j = 1, eam_nrho
       rhovals(j) = real(j-1,kind=dp) * eam_drho
    end do

    ! convert from eV to kcal / mol:
    do j = 1, eam_nrho
       eam_F_rho(j) = eam_F_rho(j) * 23.06054E0_DP
    end do
    
    ! precompute the pair potential and get it into kcal / mol:
    eam_phi_r(1) = 0.0E0_DP
    do j = 2, eam_nr
       eam_phi_r(j) = 331.999296E0_DP * (eam_Z_r(j)**2) / rvals(j)
    enddo

    call newSpline(EAMList%EAMParams(current)%rho, rvals, rhovals, &
         0.0d0, 0.0d0, .true.)
    call newSpline(EAMList%EAMParams(current)%Z,   rvals, eam_Z_r, &
         0.0d0, 0.0d0, .true.)
    call newSpline(EAMList%EAMParams(current)%F, rhovals, eam_F_rho, &
         0.0d0, 0.0d0, .true.)
    call newSpline(EAMList%EAMParams(current)%phi, rvals, eam_phi_r, &
         0.0d0, 0.0d0, .true.)
  end subroutine newEAMtype


  ! kills all eam types entered and sets simulation to uninitalized
  subroutine destroyEAMtypes()
    integer :: i
    type(EAMType), pointer :: tempEAMType=>null()

    do i = 1, EAMList%n_eam_types
       tempEAMType => eamList%EAMParams(i)
       call deallocate_EAMType(tempEAMType)
    end do
    if(associated( eamList%EAMParams)) deallocate( eamList%EAMParams)
    eamList%EAMParams => null()

    eamList%n_eam_types = 0
    eamList%currentAddition = 0
  end subroutine destroyEAMtypes

  function getEAMCut(atomID) result(cutValue)
    integer, intent(in) :: atomID
    integer :: eamID
    real(kind=dp) :: cutValue
    
    eamID = EAMList%atidToEAMType(atomID)
    cutValue = EAMList%EAMParams(eamID)%eam_rcut
  end function getEAMCut

  subroutine init_EAM_FF(status)
    integer :: status
    integer :: i,j
    real(kind=dp) :: current_rcut_max
#ifdef IS_MPI
    integer :: nAtomsInRow
    integer :: nAtomsInCol
#endif
    integer :: alloc_stat
    integer :: number_r, number_rho

    status = 0
    if (EAMList%currentAddition == 0) then
       call handleError("init_EAM_FF","No members in EAMList")
       status = -1
       return
    end if
    
    !! Allocate arrays for force calculation
    
#ifdef IS_MPI
    nAtomsInRow = getNatomsInRow(plan_atom_row)
    nAtomsInCol = getNatomsInCol(plan_atom_col)
#endif

    if (allocated(frho)) deallocate(frho)
    allocate(frho(nlocal),stat=alloc_stat)
    if (alloc_stat /= 0) then 
       status = -1
       return
    end if

    if (allocated(rho)) deallocate(rho)
    allocate(rho(nlocal),stat=alloc_stat)
    if (alloc_stat /= 0) then 
       status = -1
       return
    end if

    if (allocated(dfrhodrho)) deallocate(dfrhodrho)
    allocate(dfrhodrho(nlocal),stat=alloc_stat)
    if (alloc_stat /= 0) then 
       status = -1
       return
    end if

#ifdef IS_MPI

    if (allocated(rho_tmp)) deallocate(rho_tmp)
    allocate(rho_tmp(nlocal),stat=alloc_stat)
    if (alloc_stat /= 0) then 
       status = -1
       return
    end if

    if (allocated(frho_row)) deallocate(frho_row)
    allocate(frho_row(nAtomsInRow),stat=alloc_stat)
    if (alloc_stat /= 0) then 
       status = -1
       return
    end if
    if (allocated(rho_row)) deallocate(rho_row)
    allocate(rho_row(nAtomsInRow),stat=alloc_stat)
    if (alloc_stat /= 0) then 
       status = -1
       return
    end if
    if (allocated(dfrhodrho_row)) deallocate(dfrhodrho_row)
    allocate(dfrhodrho_row(nAtomsInRow),stat=alloc_stat)
    if (alloc_stat /= 0) then 
       status = -1
       return
    end if

    ! Now do column arrays

    if (allocated(frho_col)) deallocate(frho_col)
    allocate(frho_col(nAtomsInCol),stat=alloc_stat)
    if (alloc_stat /= 0) then 
       status = -1
       return
    end if
    if (allocated(rho_col)) deallocate(rho_col)
    allocate(rho_col(nAtomsInCol),stat=alloc_stat)
    if (alloc_stat /= 0) then 
       status = -1
       return
    end if
    if (allocated(dfrhodrho_col)) deallocate(dfrhodrho_col)
    allocate(dfrhodrho_col(nAtomsInCol),stat=alloc_stat)
    if (alloc_stat /= 0) then 
       status = -1
       return
    end if

#endif

  end subroutine init_EAM_FF

  subroutine setCutoffEAM(rcut)
    real(kind=dp) :: rcut
    EAM_rcut = rcut
  end subroutine setCutoffEAM

  subroutine clean_EAM()

    ! clean non-IS_MPI first
    frho = 0.0_dp
    rho  = 0.0_dp
    dfrhodrho = 0.0_dp
    ! clean MPI if needed
#ifdef IS_MPI
    frho_row = 0.0_dp
    frho_col = 0.0_dp
    rho_row  = 0.0_dp
    rho_col  = 0.0_dp
    rho_tmp  = 0.0_dp
    dfrhodrho_row = 0.0_dp
    dfrhodrho_col = 0.0_dp
#endif
  end subroutine clean_EAM

  subroutine deallocate_EAMType(thisEAMType)
    type (EAMtype), pointer :: thisEAMType

    call deleteSpline(thisEAMType%F)
    call deleteSpline(thisEAMType%rho)
    call deleteSpline(thisEAMType%phi)
    call deleteSpline(thisEAMType%Z)

  end subroutine deallocate_EAMType

  !! Calculates rho_r
  subroutine calc_eam_prepair_rho(atom1,atom2,d,r,rijsq)
    integer :: atom1, atom2
    real(kind = dp), dimension(3) :: d
    real(kind = dp), intent(inout)               :: r
    real(kind = dp), intent(inout)               :: rijsq
    ! value of electron density rho do to atom i at atom j
    real(kind = dp) :: rho_i_at_j
    ! value of electron density rho do to atom j at atom i
    real(kind = dp) :: rho_j_at_i
    integer :: eam_err
    
    integer :: atid1, atid2 ! Global atid    
    integer :: myid_atom1 ! EAM atid
    integer :: myid_atom2 

    ! check to see if we need to be cleaned at the start of a force loop

#ifdef IS_MPI
    Atid1 = Atid_row(Atom1)
    Atid2 = Atid_col(Atom2)
#else
    Atid1 = Atid(Atom1)
    Atid2 = Atid(Atom2)
#endif

    Myid_atom1 = Eamlist%atidtoeamtype(Atid1)
    Myid_atom2 = Eamlist%atidtoeamtype(Atid2)

    if (r.lt.EAMList%EAMParams(myid_atom1)%eam_rcut) then

       call lookupUniformSpline(EAMList%EAMParams(myid_atom1)%rho, r, &
            rho_i_at_j)

#ifdef  IS_MPI
       rho_col(atom2) = rho_col(atom2) + rho_i_at_j
#else
       rho(atom2) = rho(atom2) + rho_i_at_j
#endif
    endif

    if (r.lt.EAMList%EAMParams(myid_atom2)%eam_rcut) then

       call lookupUniformSpline(EAMList%EAMParams(myid_atom2)%rho, r, &
            rho_j_at_i)

#ifdef  IS_MPI
       rho_row(atom1) = rho_row(atom1) + rho_j_at_i
#else
       rho(atom1) = rho(atom1) + rho_j_at_i
#endif
    endif

  end subroutine calc_eam_prepair_rho


  !! Calculate the functional F(rho) for all local atoms
  subroutine calc_eam_preforce_Frho(nlocal, pot)
    integer :: nlocal
    real(kind=dp) :: pot
    integer :: i, j
    integer :: atom
    real(kind=dp) :: U,U1
    integer :: atype1
    integer :: me, atid1

    cleanme = .true.
    !! Scatter the electron density from  pre-pair calculation back to 
    !! local atoms
#ifdef IS_MPI
    call scatter(rho_row,rho,plan_atom_row,eam_err)
    if (eam_err /= 0 ) then
       write(errMsg,*) " Error scattering rho_row into rho"
       call handleError(RoutineName,errMesg)
    endif
    call scatter(rho_col,rho_tmp,plan_atom_col,eam_err)
    if (eam_err /= 0 ) then
       write(errMsg,*) " Error scattering rho_col into rho"
       call handleError(RoutineName,errMesg)
    endif

    rho(1:nlocal) = rho(1:nlocal) + rho_tmp(1:nlocal)
#endif

    !! Calculate F(rho) and derivative 
    do atom = 1, nlocal
       atid1 = atid(atom)
       me = eamList%atidToEAMtype(atid1)

       call lookupUniformSpline1d(EAMList%EAMParams(me)%F, rho(atom), &
            u, u1)
       
       frho(atom) = u
       dfrhodrho(atom) = u1
       pot = pot + u
    enddo

#ifdef IS_MPI
    !! communicate f(rho) and derivatives back into row and column arrays
    call gather(frho,frho_row,plan_atom_row, eam_err)
    if (eam_err /=  0) then
       call handleError("cal_eam_forces()","MPI gather frho_row failure")
    endif
    call gather(dfrhodrho,dfrhodrho_row,plan_atom_row, eam_err)
    if (eam_err /=  0) then
       call handleError("cal_eam_forces()","MPI gather dfrhodrho_row failure")
    endif
    call gather(frho,frho_col,plan_atom_col, eam_err)
    if (eam_err /=  0) then
       call handleError("cal_eam_forces()","MPI gather frho_col failure")
    endif
    call gather(dfrhodrho,dfrhodrho_col,plan_atom_col, eam_err)
    if (eam_err /=  0) then
       call handleError("cal_eam_forces()","MPI gather dfrhodrho_col failure")
    endif
#endif


  end subroutine calc_eam_preforce_Frho
  
  !! Does EAM pairwise Force calculation.  
  subroutine do_eam_pair(atom1, atom2, d, rij, r2, sw, vpair, fpair, &
       pot, f, do_pot)
    !Arguments    
    integer, intent(in) ::  atom1, atom2
    real( kind = dp ), intent(in) :: rij, r2
    real( kind = dp ) :: pot, sw, vpair
    real( kind = dp ), dimension(3,nLocal) :: f
    real( kind = dp ), intent(in), dimension(3) :: d
    real( kind = dp ), intent(inout), dimension(3) :: fpair

    logical, intent(in) :: do_pot

    real( kind = dp ) :: drdx, drdy, drdz
    real( kind = dp ) :: phab, pha, dvpdr
    real( kind = dp ) :: rha, drha, dpha
    real( kind = dp ) :: rhb, drhb, dphb
    real( kind = dp ) :: dudr
    real( kind = dp ) :: rci, rcj
    real( kind = dp ) :: drhoidr, drhojdr
    real( kind = dp ) :: Fx, Fy, Fz
    real( kind = dp ) :: r, phb

    integer :: id1, id2
    integer  :: mytype_atom1
    integer  :: mytype_atom2
    integer  :: atid1, atid2

    phab = 0.0E0_DP
    dvpdr = 0.0E0_DP

    if (rij .lt. EAM_rcut) then

#ifdef IS_MPI
       atid1 = atid_row(atom1)
       atid2 = atid_col(atom2)
#else
       atid1 = atid(atom1)
       atid2 = atid(atom2)
#endif

       mytype_atom1 = EAMList%atidToEAMType(atid1)
       mytype_atom2 = EAMList%atidTOEAMType(atid2)


       ! get cutoff for atom 1
       rci = EAMList%EAMParams(mytype_atom1)%eam_rcut
       ! get type specific cutoff for atom 2
       rcj = EAMList%EAMParams(mytype_atom2)%eam_rcut

       drdx = d(1)/rij
       drdy = d(2)/rij
       drdz = d(3)/rij

       if (rij.lt.rci) then

          ! Calculate rho and drho for atom1

          call lookupUniformSpline1d(EAMList%EAMParams(mytype_atom1)%rho, &
               rij, rha, drha)
          
          ! Calculate Phi(r) for atom1.
          
          call lookupUniformSpline1d(EAMList%EAMParams(mytype_atom1)%phi, &
               rij, pha, dpha)

       endif

       if (rij.lt.rcj) then      

          ! Calculate rho and drho for atom2

          call lookupUniformSpline1d(EAMList%EAMParams(mytype_atom2)%rho, &
               rij, rhb, drhb)

          ! Calculate Phi(r) for atom2.

          call lookupUniformSpline1d(EAMList%EAMParams(mytype_atom2)%phi, &
               rij, phb, dphb)

       endif

       if (rij.lt.rci) then 
          phab = phab + 0.5E0_DP*(rhb/rha)*pha
          dvpdr = dvpdr + 0.5E0_DP*((rhb/rha)*dpha + &
               pha*((drhb/rha) - (rhb*drha/rha/rha)))
       endif

       if (rij.lt.rcj) then
          phab = phab + 0.5E0_DP*(rha/rhb)*phb
          dvpdr = dvpdr + 0.5E0_DP*((rha/rhb)*dphb + &
               phb*((drha/rhb) - (rha*drhb/rhb/rhb)))
       endif

       drhoidr = drha
       drhojdr = drhb

#ifdef IS_MPI
       dudr = drhojdr*dfrhodrho_row(atom1)+drhoidr*dfrhodrho_col(atom2) &
            + dvpdr

#else
       dudr = drhojdr*dfrhodrho(atom1)+drhoidr*dfrhodrho(atom2) &
            + dvpdr
#endif

       fx = dudr * drdx
       fy = dudr * drdy
       fz = dudr * drdz


#ifdef IS_MPI
       if (do_pot) then
          pot_Row(METALLIC_POT,atom1) = pot_Row(METALLIC_POT,atom1) + phab*0.5
          pot_Col(METALLIC_POT,atom2) = pot_Col(METALLIC_POT,atom2) + phab*0.5
       end if

       f_Row(1,atom1) = f_Row(1,atom1) + fx
       f_Row(2,atom1) = f_Row(2,atom1) + fy
       f_Row(3,atom1) = f_Row(3,atom1) + fz

       f_Col(1,atom2) = f_Col(1,atom2) - fx
       f_Col(2,atom2) = f_Col(2,atom2) - fy
       f_Col(3,atom2) = f_Col(3,atom2) - fz
#else

       if(do_pot) then
          pot = pot + phab
       end if

       f(1,atom1) = f(1,atom1) + fx
       f(2,atom1) = f(2,atom1) + fy
       f(3,atom1) = f(3,atom1) + fz

       f(1,atom2) = f(1,atom2) - fx
       f(2,atom2) = f(2,atom2) - fy
       f(3,atom2) = f(3,atom2) - fz
#endif

       vpair = vpair + phab

#ifdef IS_MPI
       id1 = AtomRowToGlobal(atom1)
       id2 = AtomColToGlobal(atom2)
#else
       id1 = atom1
       id2 = atom2
#endif

       if (molMembershipList(id1) .ne. molMembershipList(id2)) then

          fpair(1) = fpair(1) + fx
          fpair(2) = fpair(2) + fy
          fpair(3) = fpair(3) + fz

       endif
    endif
  end subroutine do_eam_pair

end module eam
Revision:	2717
Committed:	Mon Apr 17 21:49:12 2006 UTC (20 years, 1 month ago) by gezelter
File size:	18933 byte(s)
Log Message:	Many performance improvements
#	Content
1	!!
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	module eam
43	use simulation
44	use force_globals
45	use status
46	use atype_module
47	use vector_class
48	use interpolation
49	#ifdef IS_MPI
50	use mpiSimulation
51	#endif
52	implicit none
53	PRIVATE
54	#define __FORTRAN90
55	#include "UseTheForce/DarkSide/fInteractionMap.h"
56
57	INTEGER, PARAMETER :: DP = selected_real_kind(15)
58
59	logical, save :: EAM_FF_initialized = .false.
60	integer, save :: EAM_Mixing_Policy
61	real(kind = dp), save :: EAM_rcut
62	logical, save :: haveRcut = .false.
63
64	character(len = statusMsgSize) :: errMesg
65	integer :: eam_err
66
67	character(len = 200) :: errMsg
68	character(len=*), parameter :: RoutineName = "EAM MODULE"
69	!! Logical that determines if eam arrays should be zeroed
70	logical :: cleanme = .true.
71
72	type, private :: EAMtype
73	integer :: eam_atype
74	real( kind = DP ) :: eam_lattice
75	real( kind = DP ) :: eam_rcut
76	integer :: eam_atype_map
77	type(cubicSpline) :: rho
78	type(cubicSpline) :: Z
79	type(cubicSpline) :: F
80	type(cubicSpline) :: phi
81	end type EAMtype
82
83	!! Arrays for derivatives used in force calculation
84	real( kind = dp), dimension(:), allocatable :: frho
85	real( kind = dp), dimension(:), allocatable :: rho
86	real( kind = dp), dimension(:), allocatable :: dfrhodrho
87
88	!! Arrays for MPI storage
89	#ifdef IS_MPI
90	real( kind = dp),save, dimension(:), allocatable :: dfrhodrho_col
91	real( kind = dp),save, dimension(:), allocatable :: dfrhodrho_row
92	real( kind = dp),save, dimension(:), allocatable :: frho_row
93	real( kind = dp),save, dimension(:), allocatable :: frho_col
94	real( kind = dp),save, dimension(:), allocatable :: rho_row
95	real( kind = dp),save, dimension(:), allocatable :: rho_col
96	real( kind = dp),save, dimension(:), allocatable :: rho_tmp
97	#endif
98
99	type, private :: EAMTypeList
100	integer :: n_eam_types = 0
101	integer :: currentAddition = 0
102
103	type (EAMtype), pointer :: EAMParams(:) => null()
104	integer, pointer :: atidToEAMType(:) => null()
105	end type EAMTypeList
106
107	type (eamTypeList), save :: EAMList
108
109	!! standard eam stuff
110
111
112	public :: init_EAM_FF
113	public :: setCutoffEAM
114	public :: do_eam_pair
115	public :: newEAMtype
116	public :: calc_eam_prepair_rho
117	public :: calc_eam_preforce_Frho
118	public :: clean_EAM
119	public :: destroyEAMTypes
120	public :: getEAMCut
121
122	contains
123
124	subroutine newEAMtype(lattice_constant,eam_nrho,eam_drho,eam_nr,&
125	eam_dr,rcut,eam_Z_r,eam_rho_r,eam_F_rho, c_ident, status)
126	real (kind = dp ) :: lattice_constant
127	integer :: eam_nrho
128	real (kind = dp ) :: eam_drho
129	integer :: eam_nr
130	real (kind = dp ) :: eam_dr
131	real (kind = dp ) :: rcut
132	real (kind = dp ), dimension(eam_nr) :: eam_Z_r, rvals
133	real (kind = dp ), dimension(eam_nr) :: eam_rho_r, eam_phi_r
134	real (kind = dp ), dimension(eam_nrho) :: eam_F_rho, rhovals
135	integer :: c_ident
136	integer :: status
137
138	integer :: nAtypes,nEAMTypes,myATID
139	integer :: maxVals
140	integer :: alloc_stat
141	integer :: current, j
142	integer,pointer :: Matchlist(:) => null()
143
144	status = 0
145
146	!! Assume that atypes has already been set and get the total number of types in atypes
147	!! Also assume that every member of atypes is a EAM model.
148
149	! check to see if this is the first time into
150	if (.not.associated(EAMList%EAMParams)) then
151	call getMatchingElementList(atypes, "is_EAM", .true., nEAMtypes, MatchList)
152	EAMList%n_eam_types = nEAMtypes
153	allocate(EAMList%EAMParams(nEAMTypes))
154	nAtypes = getSize(atypes)
155	allocate(EAMList%atidToEAMType(nAtypes))
156	end if
157
158	EAMList%currentAddition = EAMList%currentAddition + 1
159	current = EAMList%currentAddition
160
161	myATID = getFirstMatchingElement(atypes, "c_ident", c_ident)
162	EAMList%atidToEAMType(myATID) = current
163
164	EAMList%EAMParams(current)%eam_atype = c_ident
165	EAMList%EAMParams(current)%eam_lattice = lattice_constant
166	EAMList%EAMParams(current)%eam_rcut = rcut
167
168	! Build array of r values
169	do j = 1, eam_nr
170	rvals(j) = real(j-1,kind=dp) * eam_dr
171	end do
172
173	! Build array of rho values
174	do j = 1, eam_nrho
175	rhovals(j) = real(j-1,kind=dp) * eam_drho
176	end do
177
178	! convert from eV to kcal / mol:
179	do j = 1, eam_nrho
180	eam_F_rho(j) = eam_F_rho(j) * 23.06054E0_DP
181	end do
182
183	! precompute the pair potential and get it into kcal / mol:
184	eam_phi_r(1) = 0.0E0_DP
185	do j = 2, eam_nr
186	eam_phi_r(j) = 331.999296E0_DP * (eam_Z_r(j)**2) / rvals(j)
187	enddo
188
189	call newSpline(EAMList%EAMParams(current)%rho, rvals, rhovals, &
190	0.0d0, 0.0d0, .true.)
191	call newSpline(EAMList%EAMParams(current)%Z, rvals, eam_Z_r, &
192	0.0d0, 0.0d0, .true.)
193	call newSpline(EAMList%EAMParams(current)%F, rhovals, eam_F_rho, &
194	0.0d0, 0.0d0, .true.)
195	call newSpline(EAMList%EAMParams(current)%phi, rvals, eam_phi_r, &
196	0.0d0, 0.0d0, .true.)
197	end subroutine newEAMtype
198
199
200	! kills all eam types entered and sets simulation to uninitalized
201	subroutine destroyEAMtypes()
202	integer :: i
203	type(EAMType), pointer :: tempEAMType=>null()
204
205	do i = 1, EAMList%n_eam_types
206	tempEAMType => eamList%EAMParams(i)
207	call deallocate_EAMType(tempEAMType)
208	end do
209	if(associated( eamList%EAMParams)) deallocate( eamList%EAMParams)
210	eamList%EAMParams => null()
211
212	eamList%n_eam_types = 0
213	eamList%currentAddition = 0
214	end subroutine destroyEAMtypes
215
216	function getEAMCut(atomID) result(cutValue)
217	integer, intent(in) :: atomID
218	integer :: eamID
219	real(kind=dp) :: cutValue
220
221	eamID = EAMList%atidToEAMType(atomID)
222	cutValue = EAMList%EAMParams(eamID)%eam_rcut
223	end function getEAMCut
224
225	subroutine init_EAM_FF(status)
226	integer :: status
227	integer :: i,j
228	real(kind=dp) :: current_rcut_max
229	#ifdef IS_MPI
230	integer :: nAtomsInRow
231	integer :: nAtomsInCol
232	#endif
233	integer :: alloc_stat
234	integer :: number_r, number_rho
235
236	status = 0
237	if (EAMList%currentAddition == 0) then
238	call handleError("init_EAM_FF","No members in EAMList")
239	status = -1
240	return
241	end if
242
243	!! Allocate arrays for force calculation
244
245	#ifdef IS_MPI
246	nAtomsInRow = getNatomsInRow(plan_atom_row)
247	nAtomsInCol = getNatomsInCol(plan_atom_col)
248	#endif
249
250	if (allocated(frho)) deallocate(frho)
251	allocate(frho(nlocal),stat=alloc_stat)
252	if (alloc_stat /= 0) then
253	status = -1
254	return
255	end if
256
257	if (allocated(rho)) deallocate(rho)
258	allocate(rho(nlocal),stat=alloc_stat)
259	if (alloc_stat /= 0) then
260	status = -1
261	return
262	end if
263
264	if (allocated(dfrhodrho)) deallocate(dfrhodrho)
265	allocate(dfrhodrho(nlocal),stat=alloc_stat)
266	if (alloc_stat /= 0) then
267	status = -1
268	return
269	end if
270
271	#ifdef IS_MPI
272
273	if (allocated(rho_tmp)) deallocate(rho_tmp)
274	allocate(rho_tmp(nlocal),stat=alloc_stat)
275	if (alloc_stat /= 0) then
276	status = -1
277	return
278	end if
279
280	if (allocated(frho_row)) deallocate(frho_row)
281	allocate(frho_row(nAtomsInRow),stat=alloc_stat)
282	if (alloc_stat /= 0) then
283	status = -1
284	return
285	end if
286	if (allocated(rho_row)) deallocate(rho_row)
287	allocate(rho_row(nAtomsInRow),stat=alloc_stat)
288	if (alloc_stat /= 0) then
289	status = -1
290	return
291	end if
292	if (allocated(dfrhodrho_row)) deallocate(dfrhodrho_row)
293	allocate(dfrhodrho_row(nAtomsInRow),stat=alloc_stat)
294	if (alloc_stat /= 0) then
295	status = -1
296	return
297	end if
298
299	! Now do column arrays
300
301	if (allocated(frho_col)) deallocate(frho_col)
302	allocate(frho_col(nAtomsInCol),stat=alloc_stat)
303	if (alloc_stat /= 0) then
304	status = -1
305	return
306	end if
307	if (allocated(rho_col)) deallocate(rho_col)
308	allocate(rho_col(nAtomsInCol),stat=alloc_stat)
309	if (alloc_stat /= 0) then
310	status = -1
311	return
312	end if
313	if (allocated(dfrhodrho_col)) deallocate(dfrhodrho_col)
314	allocate(dfrhodrho_col(nAtomsInCol),stat=alloc_stat)
315	if (alloc_stat /= 0) then
316	status = -1
317	return
318	end if
319
320	#endif
321
322	end subroutine init_EAM_FF
323
324	subroutine setCutoffEAM(rcut)
325	real(kind=dp) :: rcut
326	EAM_rcut = rcut
327	end subroutine setCutoffEAM
328
329	subroutine clean_EAM()
330
331	! clean non-IS_MPI first
332	frho = 0.0_dp
333	rho = 0.0_dp
334	dfrhodrho = 0.0_dp
335	! clean MPI if needed
336	#ifdef IS_MPI
337	frho_row = 0.0_dp
338	frho_col = 0.0_dp
339	rho_row = 0.0_dp
340	rho_col = 0.0_dp
341	rho_tmp = 0.0_dp
342	dfrhodrho_row = 0.0_dp
343	dfrhodrho_col = 0.0_dp
344	#endif
345	end subroutine clean_EAM
346
347	subroutine deallocate_EAMType(thisEAMType)
348	type (EAMtype), pointer :: thisEAMType
349
350	call deleteSpline(thisEAMType%F)
351	call deleteSpline(thisEAMType%rho)
352	call deleteSpline(thisEAMType%phi)
353	call deleteSpline(thisEAMType%Z)
354
355	end subroutine deallocate_EAMType
356
357	!! Calculates rho_r
358	subroutine calc_eam_prepair_rho(atom1,atom2,d,r,rijsq)
359	integer :: atom1, atom2
360	real(kind = dp), dimension(3) :: d
361	real(kind = dp), intent(inout) :: r
362	real(kind = dp), intent(inout) :: rijsq
363	! value of electron density rho do to atom i at atom j
364	real(kind = dp) :: rho_i_at_j
365	! value of electron density rho do to atom j at atom i
366	real(kind = dp) :: rho_j_at_i
367	integer :: eam_err
368
369	integer :: atid1, atid2 ! Global atid
370	integer :: myid_atom1 ! EAM atid
371	integer :: myid_atom2
372
373	! check to see if we need to be cleaned at the start of a force loop
374
375	#ifdef IS_MPI
376	Atid1 = Atid_row(Atom1)
377	Atid2 = Atid_col(Atom2)
378	#else
379	Atid1 = Atid(Atom1)
380	Atid2 = Atid(Atom2)
381	#endif
382
383	Myid_atom1 = Eamlist%atidtoeamtype(Atid1)
384	Myid_atom2 = Eamlist%atidtoeamtype(Atid2)
385
386	if (r.lt.EAMList%EAMParams(myid_atom1)%eam_rcut) then
387
388	call lookupUniformSpline(EAMList%EAMParams(myid_atom1)%rho, r, &
389	rho_i_at_j)
390
391	#ifdef IS_MPI
392	rho_col(atom2) = rho_col(atom2) + rho_i_at_j
393	#else
394	rho(atom2) = rho(atom2) + rho_i_at_j
395	#endif
396	endif
397
398	if (r.lt.EAMList%EAMParams(myid_atom2)%eam_rcut) then
399
400	call lookupUniformSpline(EAMList%EAMParams(myid_atom2)%rho, r, &
401	rho_j_at_i)
402
403	#ifdef IS_MPI
404	rho_row(atom1) = rho_row(atom1) + rho_j_at_i
405	#else
406	rho(atom1) = rho(atom1) + rho_j_at_i
407	#endif
408	endif
409
410	end subroutine calc_eam_prepair_rho
411
412
413	!! Calculate the functional F(rho) for all local atoms
414	subroutine calc_eam_preforce_Frho(nlocal, pot)
415	integer :: nlocal
416	real(kind=dp) :: pot
417	integer :: i, j
418	integer :: atom
419	real(kind=dp) :: U,U1
420	integer :: atype1
421	integer :: me, atid1
422
423	cleanme = .true.
424	!! Scatter the electron density from pre-pair calculation back to
425	!! local atoms
426	#ifdef IS_MPI
427	call scatter(rho_row,rho,plan_atom_row,eam_err)
428	if (eam_err /= 0 ) then
429	write(errMsg,*) " Error scattering rho_row into rho"
430	call handleError(RoutineName,errMesg)
431	endif
432	call scatter(rho_col,rho_tmp,plan_atom_col,eam_err)
433	if (eam_err /= 0 ) then
434	write(errMsg,*) " Error scattering rho_col into rho"
435	call handleError(RoutineName,errMesg)
436	endif
437
438	rho(1:nlocal) = rho(1:nlocal) + rho_tmp(1:nlocal)
439	#endif
440
441	!! Calculate F(rho) and derivative
442	do atom = 1, nlocal
443	atid1 = atid(atom)
444	me = eamList%atidToEAMtype(atid1)
445
446	call lookupUniformSpline1d(EAMList%EAMParams(me)%F, rho(atom), &
447	u, u1)
448
449	frho(atom) = u
450	dfrhodrho(atom) = u1
451	pot = pot + u
452	enddo
453
454	#ifdef IS_MPI
455	!! communicate f(rho) and derivatives back into row and column arrays
456	call gather(frho,frho_row,plan_atom_row, eam_err)
457	if (eam_err /= 0) then
458	call handleError("cal_eam_forces()","MPI gather frho_row failure")
459	endif
460	call gather(dfrhodrho,dfrhodrho_row,plan_atom_row, eam_err)
461	if (eam_err /= 0) then
462	call handleError("cal_eam_forces()","MPI gather dfrhodrho_row failure")
463	endif
464	call gather(frho,frho_col,plan_atom_col, eam_err)
465	if (eam_err /= 0) then
466	call handleError("cal_eam_forces()","MPI gather frho_col failure")
467	endif
468	call gather(dfrhodrho,dfrhodrho_col,plan_atom_col, eam_err)
469	if (eam_err /= 0) then
470	call handleError("cal_eam_forces()","MPI gather dfrhodrho_col failure")
471	endif
472	#endif
473
474
475	end subroutine calc_eam_preforce_Frho
476
477	!! Does EAM pairwise Force calculation.
478	subroutine do_eam_pair(atom1, atom2, d, rij, r2, sw, vpair, fpair, &
479	pot, f, do_pot)
480	!Arguments
481	integer, intent(in) :: atom1, atom2
482	real( kind = dp ), intent(in) :: rij, r2
483	real( kind = dp ) :: pot, sw, vpair
484	real( kind = dp ), dimension(3,nLocal) :: f
485	real( kind = dp ), intent(in), dimension(3) :: d
486	real( kind = dp ), intent(inout), dimension(3) :: fpair
487
488	logical, intent(in) :: do_pot
489
490	real( kind = dp ) :: drdx, drdy, drdz
491	real( kind = dp ) :: phab, pha, dvpdr
492	real( kind = dp ) :: rha, drha, dpha
493	real( kind = dp ) :: rhb, drhb, dphb
494	real( kind = dp ) :: dudr
495	real( kind = dp ) :: rci, rcj
496	real( kind = dp ) :: drhoidr, drhojdr
497	real( kind = dp ) :: Fx, Fy, Fz
498	real( kind = dp ) :: r, phb
499
500	integer :: id1, id2
501	integer :: mytype_atom1
502	integer :: mytype_atom2
503	integer :: atid1, atid2
504
505	phab = 0.0E0_DP
506	dvpdr = 0.0E0_DP
507
508	if (rij .lt. EAM_rcut) then
509
510	#ifdef IS_MPI
511	atid1 = atid_row(atom1)
512	atid2 = atid_col(atom2)
513	#else
514	atid1 = atid(atom1)
515	atid2 = atid(atom2)
516	#endif
517
518	mytype_atom1 = EAMList%atidToEAMType(atid1)
519	mytype_atom2 = EAMList%atidTOEAMType(atid2)
520
521
522	! get cutoff for atom 1
523	rci = EAMList%EAMParams(mytype_atom1)%eam_rcut
524	! get type specific cutoff for atom 2
525	rcj = EAMList%EAMParams(mytype_atom2)%eam_rcut
526
527	drdx = d(1)/rij
528	drdy = d(2)/rij
529	drdz = d(3)/rij
530
531	if (rij.lt.rci) then
532
533	! Calculate rho and drho for atom1
534
535	call lookupUniformSpline1d(EAMList%EAMParams(mytype_atom1)%rho, &
536	rij, rha, drha)
537
538	! Calculate Phi(r) for atom1.
539
540	call lookupUniformSpline1d(EAMList%EAMParams(mytype_atom1)%phi, &
541	rij, pha, dpha)
542
543	endif
544
545	if (rij.lt.rcj) then
546
547	! Calculate rho and drho for atom2
548
549	call lookupUniformSpline1d(EAMList%EAMParams(mytype_atom2)%rho, &
550	rij, rhb, drhb)
551
552	! Calculate Phi(r) for atom2.
553
554	call lookupUniformSpline1d(EAMList%EAMParams(mytype_atom2)%phi, &
555	rij, phb, dphb)
556
557	endif
558
559	if (rij.lt.rci) then
560	phab = phab + 0.5E0_DP(rhb/rha)pha
561	dvpdr = dvpdr + 0.5E0_DP((rhb/rha)dpha + &
562	pha((drhb/rha) - (rhbdrha/rha/rha)))
563	endif
564
565	if (rij.lt.rcj) then
566	phab = phab + 0.5E0_DP(rha/rhb)phb
567	dvpdr = dvpdr + 0.5E0_DP((rha/rhb)dphb + &
568	phb((drha/rhb) - (rhadrhb/rhb/rhb)))
569	endif
570
571	drhoidr = drha
572	drhojdr = drhb
573
574	#ifdef IS_MPI
575	dudr = drhojdrdfrhodrho_row(atom1)+drhoidrdfrhodrho_col(atom2) &
576	+ dvpdr
577
578	#else
579	dudr = drhojdrdfrhodrho(atom1)+drhoidrdfrhodrho(atom2) &
580	+ dvpdr
581	#endif
582
583	fx = dudr * drdx
584	fy = dudr * drdy
585	fz = dudr * drdz
586
587
588	#ifdef IS_MPI
589	if (do_pot) then
590	pot_Row(METALLIC_POT,atom1) = pot_Row(METALLIC_POT,atom1) + phab*0.5
591	pot_Col(METALLIC_POT,atom2) = pot_Col(METALLIC_POT,atom2) + phab*0.5
592	end if
593
594	f_Row(1,atom1) = f_Row(1,atom1) + fx
595	f_Row(2,atom1) = f_Row(2,atom1) + fy
596	f_Row(3,atom1) = f_Row(3,atom1) + fz
597
598	f_Col(1,atom2) = f_Col(1,atom2) - fx
599	f_Col(2,atom2) = f_Col(2,atom2) - fy
600	f_Col(3,atom2) = f_Col(3,atom2) - fz
601	#else
602
603	if(do_pot) then
604	pot = pot + phab
605	end if
606
607	f(1,atom1) = f(1,atom1) + fx
608	f(2,atom1) = f(2,atom1) + fy
609	f(3,atom1) = f(3,atom1) + fz
610
611	f(1,atom2) = f(1,atom2) - fx
612	f(2,atom2) = f(2,atom2) - fy
613	f(3,atom2) = f(3,atom2) - fz
614	#endif
615
616	vpair = vpair + phab
617
618	#ifdef IS_MPI
619	id1 = AtomRowToGlobal(atom1)
620	id2 = AtomColToGlobal(atom2)
621	#else
622	id1 = atom1
623	id2 = atom2
624	#endif
625
626	if (molMembershipList(id1) .ne. molMembershipList(id2)) then
627
628	fpair(1) = fpair(1) + fx
629	fpair(2) = fpair(2) + fy
630	fpair(3) = fpair(3) + fz
631
632	endif
633	endif
634	end subroutine do_eam_pair
635
636	end module eam