atom_utils.F

!--------------------------------------------------------------------------------------------------!
!   CP2K: A general program to perform molecular dynamics simulations                              !
!   Copyright 2000-2024 CP2K developers group <https://cp2k.org>                                   !
!                                                                                                  !
!   SPDX-License-Identifier: GPL-2.0-or-later                                                      !
!--------------------------------------------------------------------------------------------------!

! **************************************************************************************************
!> \brief   Some basic routines for atomic calculations
!> \author  jgh
!> \date    01.04.2008
!> \version 1.0
!>
! **************************************************************************************************
MODULE atom_utils
   USE ai_onecenter,                    ONLY: sg_overlap,&
                                              sto_overlap
   USE ai_overlap,                      ONLY: overlap_ab_s,&
                                              overlap_ab_sp
   USE ao_util,                         ONLY: exp_radius
   USE atom_types,                      ONLY: &
        CGTO_BASIS, GTO_BASIS, NUM_BASIS, STO_BASIS, atom_basis_type, atom_gthpot_type, &
        atom_hfx_type, atom_potential_type, atom_state, atom_type, ecp_pseudo, eri, gth_pseudo, &
        lmat, no_pseudo, sgp_pseudo, upf_pseudo
   USE basis_set_types,                 ONLY: srules
   USE cp_files,                        ONLY: close_file,&
                                              get_unit_number,&
                                              open_file
   USE input_constants,                 ONLY: do_rhf_atom,&
                                              do_rks_atom,&
                                              do_rohf_atom,&
                                              do_uhf_atom,&
                                              do_uks_atom
   USE kahan_sum,                       ONLY: accurate_dot_product
   USE kinds,                           ONLY: default_string_length,&
                                              dp
   USE lapack,                          ONLY: lapack_ssyev
   USE mathconstants,                   ONLY: dfac,&
                                              fac,&
                                              fourpi,&
                                              maxfac,&
                                              pi,&
                                              rootpi
   USE mathlib,                         ONLY: binomial_gen,&
                                              invmat_symm
   USE orbital_pointers,                ONLY: deallocate_orbital_pointers,&
                                              init_orbital_pointers
   USE orbital_transformation_matrices, ONLY: deallocate_spherical_harmonics,&
                                              init_spherical_harmonics
   USE periodic_table,                  ONLY: nelem,&
                                              ptable
   USE physcon,                         ONLY: bohr
   USE qs_grid_atom,                    ONLY: grid_atom_type
   USE splines,                         ONLY: spline3ders
   USE string_utilities,                ONLY: uppercase
#include "./base/base_uses.f90"

   IMPLICIT NONE

   PRIVATE

   CHARACTER(len=*), PARAMETER, PRIVATE :: moduleN = 'atom_utils'

   PUBLIC :: atom_condnumber, atom_completeness, atom_basis_condnum
   PUBLIC :: atom_set_occupation, get_maxl_occ, get_maxn_occ
   PUBLIC :: atom_denmat, atom_density, atom_core_density
   PUBLIC :: integrate_grid, atom_trace, atom_solve
   PUBLIC :: coulomb_potential_numeric, coulomb_potential_analytic
   PUBLIC :: exchange_numeric, exchange_semi_analytic
   PUBLIC :: numpot_matrix, ceri_contract, eeri_contract, err_matrix
   PUBLIC :: slater_density, wigner_slater_functional, atom_local_potential
   PUBLIC :: atom_orbital_charge, atom_orbital_nodes, atom_consistent_method
   PUBLIC :: atom_orbital_max, atom_wfnr0, get_rho0
   PUBLIC :: contract2, contract4, contract2add
! ZMP added public subroutines
   PUBLIC :: atom_read_external_density
   PUBLIC :: atom_read_external_vxc
   PUBLIC :: atom_read_zmp_restart
   PUBLIC :: atom_write_zmp_restart

!-----------------------------------------------------------------------------!

   INTERFACE integrate_grid
      MODULE PROCEDURE integrate_grid_function1, &
         integrate_grid_function2, &
         integrate_grid_function3
   END INTERFACE

! **************************************************************************************************

CONTAINS

! **************************************************************************************************
!> \brief Set occupation of atomic orbitals.
!> \param ostring       list of electronic states
!> \param occupation ...
!> \param wfnocc ...
!> \param multiplicity ...
!> \par History
!>    * 11.2009 unrestricted KS and HF methods [Juerg Hutter]
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE atom_set_occupation(ostring, occupation, wfnocc, multiplicity)
      CHARACTER(LEN=default_string_length), &
         DIMENSION(:), POINTER                           :: ostring
      REAL(Kind=dp), DIMENSION(0:lmat, 10)               :: occupation, wfnocc
      INTEGER, INTENT(OUT), OPTIONAL                     :: multiplicity

      CHARACTER(len=2)                                   :: elem
      CHARACTER(LEN=default_string_length)               :: pstring
      INTEGER                                            :: i, i1, i2, ielem, is, jd, jf, jp, js, k, &
                                                            l, mult, n, no
      REAL(Kind=dp)                                      :: e0, el, oo

      occupation = 0._dp

      CPASSERT(ASSOCIATED(ostring))
      CPASSERT(SIZE(ostring) > 0)

      no = SIZE(ostring)

      is = 1
      ! look for multiplicity
      mult = -1 !not specified
      IF (is <= no) THEN
         IF (INDEX(ostring(is), "(") /= 0) THEN
            i1 = INDEX(ostring(is), "(")
            i2 = INDEX(ostring(is), ")")
            CPASSERT((i2 - i1 - 1 > 0) .AND. (i2 - i1 - 1 < 3))
            elem = ostring(is) (i1 + 1:i2 - 1)
            IF (INDEX(elem, "HS") /= 0) THEN
               mult = -2 !High spin
            ELSE IF (INDEX(elem, "LS") /= 0) THEN
               mult = -3 !Low spin
            ELSE
               READ (elem, *) mult
            END IF
            is = is + 1
         END IF
      END IF

      IF (is <= no) THEN
         IF (INDEX(ostring(is), "CORE") /= 0) is = is + 1 !Pseudopotential detected
      END IF
      IF (is <= no) THEN
         IF (INDEX(ostring(is), "none") /= 0) is = is + 1 !no electrons, used with CORE
      END IF
      IF (is <= no) THEN
         IF (INDEX(ostring(is), "[") /= 0) THEN
            ! core occupation from element [XX]
            i1 = INDEX(ostring(is), "[")
            i2 = INDEX(ostring(is), "]")
            CPASSERT((i2 - i1 - 1 > 0) .AND. (i2 - i1 - 1 < 3))
            elem = ostring(is) (i1 + 1:i2 - 1)
            ielem = 0
            DO k = 1, nelem
               IF (elem == ptable(k)%symbol) THEN
                  ielem = k
                  EXIT
               END IF
            END DO
            CPASSERT(ielem /= 0)
            DO l = 0, MIN(lmat, UBOUND(ptable(ielem)%e_conv, 1))
               el = 2._dp*(2._dp*REAL(l, dp) + 1._dp)
               e0 = ptable(ielem)%e_conv(l)
               DO k = 1, 10
                  occupation(l, k) = MIN(el, e0)
                  e0 = e0 - el
                  IF (e0 <= 0._dp) EXIT
               END DO
            END DO
            is = is + 1
         END IF

      END IF

      DO i = is, no
         pstring = ostring(i)
         CALL uppercase(pstring)
         js = INDEX(pstring, "S")
         jp = INDEX(pstring, "P")
         jd = INDEX(pstring, "D")
         jf = INDEX(pstring, "F")
         CPASSERT(js + jp + jd + jf > 0)
         IF (js > 0) THEN
            CPASSERT(jp + jd + jf == 0)
            READ (pstring(1:js - 1), *) n
            READ (pstring(js + 1:), *) oo
            CPASSERT(n > 0)
            CPASSERT(oo >= 0._dp)
            CPASSERT(occupation(0, n) == 0)
            occupation(0, n) = oo
         END IF
         IF (jp > 0) THEN
            CPASSERT(js + jd + jf == 0)
            READ (pstring(1:jp - 1), *) n
            READ (pstring(jp + 1:), *) oo
            CPASSERT(n > 1)
            CPASSERT(oo >= 0._dp)
            CPASSERT(occupation(1, n - 1) == 0)
            occupation(1, n - 1) = oo
         END IF
         IF (jd > 0) THEN
            CPASSERT(js + jp + jf == 0)
            READ (pstring(1:jd - 1), *) n
            READ (pstring(jd + 1:), *) oo
            CPASSERT(n > 2)
            CPASSERT(oo >= 0._dp)
            CPASSERT(occupation(2, n - 2) == 0)
            occupation(2, n - 2) = oo
         END IF
         IF (jf > 0) THEN
            CPASSERT(js + jp + jd == 0)
            READ (pstring(1:jf - 1), *) n
            READ (pstring(jf + 1:), *) oo
            CPASSERT(n > 3)
            CPASSERT(oo >= 0._dp)
            CPASSERT(occupation(3, n - 3) == 0)
            occupation(3, n - 3) = oo
         END IF

      END DO

      wfnocc = 0._dp
      DO l = 0, lmat
         k = 0
         DO i = 1, 10
            IF (occupation(l, i) /= 0._dp) THEN
               k = k + 1
               wfnocc(l, k) = occupation(l, i)
            END IF
         END DO
      END DO

      !Check for consistency with multiplicity
      IF (mult /= -1) THEN
         ! count open shells
         js = 0
         DO l = 0, lmat
            k = 2*(2*l + 1)
            DO i = 1, 10
               IF (wfnocc(l, i) /= 0._dp .AND. wfnocc(l, i) /= REAL(k, dp)) THEN
                  js = js + 1
                  i1 = l
                  i2 = i
               END IF
            END DO
         END DO

         IF (js == 0 .AND. mult == -2) mult = 1
         IF (js == 0 .AND. mult == -3) mult = 1
         IF (js == 0) THEN
            CPASSERT(mult == 1)
         END IF
         IF (js == 1) THEN
            l = i1
            i = i2
            k = NINT(wfnocc(l, i))
            IF (k > (2*l + 1)) k = 2*(2*l + 1) - k
            IF (mult == -2) mult = k + 1
            IF (mult == -3) mult = MOD(k, 2) + 1
            CPASSERT(MOD(k + 1 - mult, 2) == 0)
         END IF
         IF (js > 1 .AND. mult /= -2) THEN
            CPASSERT(mult == -2)
         END IF

      END IF

      IF (PRESENT(multiplicity)) multiplicity = mult

   END SUBROUTINE atom_set_occupation

! **************************************************************************************************
!> \brief Return the maximum orbital quantum number of occupied orbitals.
!> \param occupation ...
!> \return ...
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   PURE FUNCTION get_maxl_occ(occupation) RESULT(maxl)
      REAL(Kind=dp), DIMENSION(0:lmat, 10), INTENT(IN)   :: occupation
      INTEGER                                            :: maxl

      INTEGER                                            :: l

      maxl = 0
      DO l = 0, lmat
         IF (SUM(occupation(l, :)) /= 0._dp) maxl = l
      END DO

   END FUNCTION get_maxl_occ

! **************************************************************************************************
!> \brief Return the maximum principal quantum number of occupied orbitals.
!> \param occupation ...
!> \return ...
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   PURE FUNCTION get_maxn_occ(occupation) RESULT(maxn)
      REAL(Kind=dp), DIMENSION(0:lmat, 10), INTENT(IN)   :: occupation
      INTEGER, DIMENSION(0:lmat)                         :: maxn

      INTEGER                                            :: k, l

      maxn = 0
      DO l = 0, lmat
         DO k = 1, 10
            IF (occupation(l, k) /= 0._dp) maxn(l) = maxn(l) + 1
         END DO
      END DO

   END FUNCTION get_maxn_occ

! **************************************************************************************************
!> \brief Calculate a density matrix using atomic orbitals.
!> \param pmat  electron density matrix
!> \param wfn   atomic wavefunctions
!> \param nbas  number of basis functions
!> \param occ   occupation numbers
!> \param maxl  maximum angular momentum to consider
!> \param maxn  maximum principal quantum number for each angular momentum
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   PURE SUBROUTINE atom_denmat(pmat, wfn, nbas, occ, maxl, maxn)
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(INOUT)  :: pmat
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(IN)     :: wfn
      INTEGER, DIMENSION(0:lmat), INTENT(IN)             :: nbas
      REAL(KIND=dp), DIMENSION(0:, :), INTENT(IN)        :: occ
      INTEGER, INTENT(IN)                                :: maxl
      INTEGER, DIMENSION(0:lmat), INTENT(IN)             :: maxn

      INTEGER                                            :: i, j, k, l, n

      pmat = 0._dp
      n = SIZE(wfn, 2)
      DO l = 0, maxl
         DO i = 1, MIN(n, maxn(l))
            DO k = 1, nbas(l)
               DO j = 1, nbas(l)
                  pmat(j, k, l) = pmat(j, k, l) + occ(l, i)*wfn(j, i, l)*wfn(k, i, l)
               END DO
            END DO
         END DO
      END DO

   END SUBROUTINE atom_denmat

! **************************************************************************************************
!> \brief Map the electron density on an atomic radial grid.
!> \param density  computed electron density
!> \param pmat     electron density matrix
!> \param basis    atomic basis set
!> \param maxl     maximum angular momentum to consider
!> \param typ      type of the matrix to map:
!>                 RHO -- density matrix;
!>                 DER -- first derivatives of the electron density;
!>                 KIN -- kinetic energy density;
!>                 LAP -- second derivatives of the electron density.
!> \param rr       abscissa on the radial grid (required for typ == 'KIN')
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE atom_density(density, pmat, basis, maxl, typ, rr)
      REAL(KIND=dp), DIMENSION(:), INTENT(OUT)           :: density
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(IN)     :: pmat
      TYPE(atom_basis_type), INTENT(IN)                  :: basis
      INTEGER, INTENT(IN)                                :: maxl
      CHARACTER(LEN=*), OPTIONAL                         :: typ
      REAL(KIND=dp), DIMENSION(:), INTENT(IN), OPTIONAL  :: rr

      CHARACTER(LEN=3)                                   :: my_typ
      INTEGER                                            :: i, j, l, n
      REAL(KIND=dp)                                      :: ff

      my_typ = "RHO"
      IF (PRESENT(typ)) my_typ = typ(1:3)
      IF (my_typ == "KIN") THEN
         CPASSERT(PRESENT(rr))
      END IF

      density = 0._dp
      DO l = 0, maxl
         n = basis%nbas(l)
         DO i = 1, n
            DO j = i, n
               ff = pmat(i, j, l)
               IF (i /= j) ff = 2._dp*pmat(i, j, l)
               IF (my_typ == "RHO") THEN
                  density(:) = density(:) + ff*basis%bf(:, i, l)*basis%bf(:, j, l)
               ELSE IF (my_typ == "DER") THEN
                  density(:) = density(:) + ff*basis%dbf(:, i, l)*basis%bf(:, j, l) &
                               + ff*basis%bf(:, i, l)*basis%dbf(:, j, l)
               ELSE IF (my_typ == "KIN") THEN
                  density(:) = density(:) + 0.5_dp*ff*( &
                               basis%dbf(:, i, l)*basis%dbf(:, j, l) + &
                               REAL(l*(l + 1), dp)*basis%bf(:, i, l)*basis%bf(:, j, l)/rr(:))
               ELSE IF (my_typ == "LAP") THEN
                  density(:) = density(:) + ff*basis%ddbf(:, i, l)*basis%bf(:, j, l) &
                               + ff*basis%bf(:, i, l)*basis%ddbf(:, j, l) &
                               + 2._dp*ff*basis%dbf(:, i, l)*basis%bf(:, j, l)/rr(:) &
                               + 2._dp*ff*basis%bf(:, i, l)*basis%dbf(:, j, l)/rr(:)
               ELSE
                  CPABORT("")
               END IF
            END DO
         END DO
      END DO
      ! this factor from the product of two spherical harmonics
      density = density/fourpi

   END SUBROUTINE atom_density

! **************************************************************************************************
!> \brief ZMP subroutine to write external restart file.
!> \param atom  information about the atomic kind
!> \date    07.10.2013
!> \author  D. Varsano [daniele.varsano@nano.cnr.it]
!> \version 1.0
! **************************************************************************************************
   SUBROUTINE atom_write_zmp_restart(atom)
      TYPE(atom_type), INTENT(IN)                        :: atom

      INTEGER                                            :: extunit, i, k, l, n

      extunit = get_unit_number()
      CALL open_file(file_name=atom%zmp_restart_file, file_status="UNKNOWN", &
                     file_form="FORMATTED", file_action="WRITE", &
                     unit_number=extunit)

      n = SIZE(atom%orbitals%wfn, 2)
      WRITE (extunit, *) atom%basis%nbas
      DO l = 0, atom%state%maxl_occ
         DO i = 1, MIN(n, atom%state%maxn_occ(l))
            DO k = 1, atom%basis%nbas(l)
               WRITE (extunit, *) atom%orbitals%wfn(k, i, l)
            END DO
         END DO
      END DO

      CALL close_file(unit_number=extunit)

   END SUBROUTINE atom_write_zmp_restart

! **************************************************************************************************
!> \brief ZMP subroutine to read external restart file.
!> \param atom     information about the atomic kind
!> \param doguess  flag that indicates that the restart file has not been read,
!>                 so the initial guess is required
!> \param iw       output file unit
!> \date    07.10.2013
!> \author  D. Varsano [daniele.varsano@nano.cnr.it]
!> \version 1.0
! **************************************************************************************************
   SUBROUTINE atom_read_zmp_restart(atom, doguess, iw)
      TYPE(atom_type), INTENT(INOUT)                     :: atom
      LOGICAL, INTENT(INOUT)                             :: doguess
      INTEGER, INTENT(IN)                                :: iw

      INTEGER                                            :: er, extunit, i, k, l, maxl, n
      INTEGER, DIMENSION(0:lmat)                         :: maxn, nbas

      INQUIRE (file=atom%zmp_restart_file, exist=atom%doread)

      IF (atom%doread) THEN
         WRITE (iw, fmt="(' ZMP       | Restart file found')")
         extunit = get_unit_number()
         CALL open_file(file_name=atom%zmp_restart_file, file_status="OLD", &
                        file_form="FORMATTED", file_action="READ", &
                        unit_number=extunit)

         READ (extunit, *, IOSTAT=er) nbas

         IF (er .NE. 0) THEN
            WRITE (iw, fmt="(' ZMP       | ERROR! Restart file unreadable')")
            WRITE (iw, fmt="(' ZMP       | ERROR! Starting ZMP calculation form initial atomic guess')")
            doguess = .TRUE.
            atom%doread = .FALSE.
         ELSE IF (nbas(1) .NE. atom%basis%nbas(1)) THEN
            WRITE (iw, fmt="(' ZMP       | ERROR! Restart file contains a different basis set')")
            WRITE (iw, fmt="(' ZMP       | ERROR! Starting ZMP calculation form initial atomic guess')")
            doguess = .TRUE.
            atom%doread = .FALSE.
         ELSE
            nbas = atom%basis%nbas
            maxl = atom%state%maxl_occ
            maxn = atom%state%maxn_occ
            n = SIZE(atom%orbitals%wfn, 2)
            DO l = 0, atom%state%maxl_occ
               DO i = 1, MIN(n, atom%state%maxn_occ(l))
                  DO k = 1, atom%basis%nbas(l)
                     READ (extunit, *) atom%orbitals%wfn(k, i, l)
                  END DO
               END DO
            END DO
            doguess = .FALSE.
         END IF
         CALL close_file(unit_number=extunit)
      ELSE
         WRITE (iw, fmt="(' ZMP       | WARNING! Restart file not found')")
         WRITE (iw, fmt="(' ZMP       | WARNING! Starting ZMP calculation form initial atomic guess')")
      END IF
   END SUBROUTINE atom_read_zmp_restart

! **************************************************************************************************
!> \brief ZMP subroutine to read external density from linear grid of density matrix.
!> \param density  external density
!> \param atom     information about the atomic kind
!> \param iw       output file unit
!> \date    07.10.2013
!> \author  D. Varsano [daniele.varsano@nano.cnr.it]
!> \version 1.0
! **************************************************************************************************
   SUBROUTINE atom_read_external_density(density, atom, iw)
      REAL(KIND=dp), DIMENSION(:), INTENT(OUT)           :: density
      TYPE(atom_type), INTENT(INOUT)                     :: atom
      INTEGER, INTENT(IN)                                :: iw

      CHARACTER(LEN=default_string_length)               :: filename
      INTEGER                                            :: extunit, ir, j, k, l, maxl_occ, maxnbas, &
                                                            nbas, nr
      LOGICAL                                            :: ldm
      REAL(KIND=dp)                                      :: rr
      REAL(KIND=dp), ALLOCATABLE                         :: pmatread(:, :, :)

      filename = atom%ext_file
      ldm = atom%dm
      extunit = get_unit_number()

      CALL open_file(file_name=filename, file_status="OLD", &
                     file_form="FORMATTED", file_action="READ", &
                     unit_number=extunit)

      IF (.NOT. ldm) THEN
         READ (extunit, *) nr

         IF (nr .NE. atom%basis%grid%nr) THEN
            IF (iw > 0) WRITE (iw, fmt="(' ZMP       | ERROR! External grid dimension ',I4,' differs from internal grid ',I4)") &
               nr, atom%basis%grid%nr
            IF (iw > 0) WRITE (iw, fmt="(' ZMP       | ERROR! Stopping ZMP calculation')")
            CPABORT("")
         END IF

         DO ir = 1, nr
            READ (extunit, *) rr, density(ir)
            IF (ABS(rr - atom%basis%grid%rad(ir)) .GT. atom%zmpgrid_tol) THEN
               IF (iw > 0) WRITE (iw, fmt="(' ZMP       | ERROR! Grid points do not coincide: ')")
               IF (iw > 0) WRITE (iw, fmt='(" ZMP       |",T20,"R_out[bohr]",T36,"R_in[bohr]",T61,"R_diff[bohr]")')
               IF (iw > 0) WRITE (iw, fmt='(" ZMP       |",T14,E24.15,T39,E24.15,T64,E24.15)') &
                  rr, atom%basis%grid%rad(ir), ABS(rr - atom%basis%grid%rad(ir))
               CPABORT("")
            END IF
         END DO
         CALL close_file(unit_number=extunit)
      ELSE
         READ (extunit, *) maxl_occ
         maxnbas = MAXVAL(atom%basis%nbas)
         ALLOCATE (pmatread(maxnbas, maxnbas, 0:maxl_occ))
         pmatread = 0.0
         DO l = 0, maxl_occ
            nbas = atom%basis%nbas(l)
            READ (extunit, *) ! Read empty line
            DO k = 1, nbas
               READ (extunit, *) (pmatread(j, k, l), j=1, k)
               DO j = 1, k
                  pmatread(k, j, l) = pmatread(j, k, l)
               END DO
            END DO
         END DO

         CALL close_file(unit_number=extunit)

         CALL atom_density(density, pmatread, atom%basis, maxl_occ, typ="RHO")

         extunit = get_unit_number()
         CALL open_file(file_name="rho_target.dat", file_status="UNKNOWN", &
                        file_form="FORMATTED", file_action="WRITE", unit_number=extunit)

         IF (iw > 0) WRITE (iw, fmt="(' ZMP       | Writing target density from density matrix')")

         WRITE (extunit, fmt='("# Target density built from density matrix : ",A20)') filename
         WRITE (extunit, fmt='("#",T10,"R[bohr]",T36,"Rho[au]")')

         nr = atom%basis%grid%nr

         DO ir = 1, nr
            WRITE (extunit, fmt='(T1,E24.15,T26,E24.15)') &
               atom%basis%grid%rad(ir), density(ir)
         END DO
         DEALLOCATE (pmatread)

         CALL close_file(unit_number=extunit)

      END IF

   END SUBROUTINE atom_read_external_density

! **************************************************************************************************
!> \brief ZMP subroutine to read external v_xc in the atomic code.
!> \param vxc   external exchange-correlation potential
!> \param atom  information about the atomic kind
!> \param iw    output file unit
!> \author D. Varsano [daniele.varsano@nano.cnr.it]
! **************************************************************************************************
   SUBROUTINE atom_read_external_vxc(vxc, atom, iw)
      REAL(KIND=dp), DIMENSION(:), INTENT(OUT)           :: vxc
      TYPE(atom_type), INTENT(INOUT)                     :: atom
      INTEGER, INTENT(IN)                                :: iw

      CHARACTER(LEN=default_string_length)               :: adum, filename
      INTEGER                                            :: extunit, ir, nr
      REAL(KIND=dp)                                      :: rr

      filename = atom%ext_vxc_file
      extunit = get_unit_number()

      CALL open_file(file_name=filename, file_status="OLD", &
                     file_form="FORMATTED", file_action="READ", &
                     unit_number=extunit)

      READ (extunit, *)
      READ (extunit, *) adum, nr

      IF (nr .NE. atom%basis%grid%nr) THEN
         IF (iw > 0) WRITE (iw, fmt="(' ZMP       | ERROR! External grid dimension ',I4,' differs from internal grid ',I4)") &
            nr, atom%basis%grid%nr
         IF (iw > 0) WRITE (iw, fmt="(' ZMP       | ERROR! Stopping ZMP calculation')")
         CPABORT("")
      END IF
      DO ir = 1, nr
         READ (extunit, *) rr, vxc(ir)
         IF (ABS(rr - atom%basis%grid%rad(ir)) .GT. atom%zmpvxcgrid_tol) THEN
            IF (iw > 0) WRITE (iw, fmt="(' ZMP       | ERROR! Grid points do not coincide: ')")
            IF (iw > 0) WRITE (iw, fmt='(" ZMP       |",T20,"R_out[bohr]",T36,"R_in[bohr]",T61,"R_diff[bohr]")')
            IF (iw > 0) WRITE (iw, fmt='(" ZMP       |",T14,E24.15,T39,E24.15,T64,E24.15)') &
               rr, atom%basis%grid%rad(ir), ABS(rr - atom%basis%grid%rad(ir))
            CPABORT("")
         END IF
      END DO

   END SUBROUTINE atom_read_external_vxc

! **************************************************************************************************
!> \brief ...
!> \param charge ...
!> \param wfn ...
!> \param rcov ...
!> \param l ...
!> \param basis ...
! **************************************************************************************************
   PURE SUBROUTINE atom_orbital_charge(charge, wfn, rcov, l, basis)
      REAL(KIND=dp), INTENT(OUT)                         :: charge
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: wfn
      REAL(KIND=dp), INTENT(IN)                          :: rcov
      INTEGER, INTENT(IN)                                :: l
      TYPE(atom_basis_type), INTENT(IN)                  :: basis

      INTEGER                                            :: i, j, m, n
      REAL(KIND=dp)                                      :: ff
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: den

      charge = 0._dp
      m = SIZE(basis%bf, 1)
      ALLOCATE (den(m))
      n = basis%nbas(l)
      den = 0._dp
      DO i = 1, n
         DO j = 1, n
            ff = wfn(i)*wfn(j)
            den(1:m) = den(1:m) + ff*basis%bf(1:m, i, l)*basis%bf(1:m, j, l)
         END DO
      END DO
      DO i = 1, m
         IF (basis%grid%rad(i) > rcov) den(i) = 0._dp
      END DO
      charge = SUM(den(1:m)*basis%grid%wr(1:m))
      DEALLOCATE (den)

   END SUBROUTINE atom_orbital_charge

! **************************************************************************************************
!> \brief ...
!> \param corden ...
!> \param potential ...
!> \param typ ...
!> \param rr ...
!> \par History
!>    * 01.2017 rewritten [Juerg Hutter]
!>    * 03.2010 extension of GTH pseudo-potential definition [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE atom_core_density(corden, potential, typ, rr)
      REAL(KIND=dp), DIMENSION(:), INTENT(INOUT)         :: corden
      TYPE(atom_potential_type), INTENT(IN)              :: potential
      CHARACTER(LEN=*), OPTIONAL                         :: typ
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: rr

      CHARACTER(LEN=3)                                   :: my_typ
      INTEGER                                            :: i, j, m, n
      LOGICAL                                            :: reverse
      REAL(KIND=dp)                                      :: a, a2, cval, fb
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: fe, rc, rhoc, rval

      my_typ = "RHO"
      IF (PRESENT(typ)) my_typ = typ(1:3)

      SELECT CASE (potential%ppot_type)
      CASE (no_pseudo, ecp_pseudo)
         ! we do nothing
      CASE (gth_pseudo)
         IF (potential%gth_pot%nlcc) THEN
            m = SIZE(corden)
            ALLOCATE (fe(m), rc(m))
            n = potential%gth_pot%nexp_nlcc
            DO i = 1, n
               a = potential%gth_pot%alpha_nlcc(i)
               a2 = a*a
               ! note that all terms are computed with rc, not rr
               rc(:) = rr(:)/a
               fe(:) = EXP(-0.5_dp*rc(:)*rc(:))
               DO j = 1, potential%gth_pot%nct_nlcc(i)
                  cval = potential%gth_pot%cval_nlcc(j, i)
                  IF (my_typ == "RHO") THEN
                     corden(:) = corden(:) + fe(:)*rc**(2*j - 2)*cval
                  ELSE IF (my_typ == "DER") THEN
                     corden(:) = corden(:) - fe(:)*rc**(2*j - 1)*cval/a
                     IF (j > 1) THEN
                        corden(:) = corden(:) + REAL(2*j - 2, dp)*fe(:)*rc**(2*j - 3)*cval/a
                     END IF
                  ELSE IF (my_typ == "LAP") THEN
                     fb = 2._dp*cval/a
                     corden(:) = corden(:) - fb*fe(:)/rr(:)*rc**(2*j - 1)
                     corden(:) = corden(:) + fe(:)*rc**(2*j)*cval/a2
                     IF (j > 1) THEN
                        corden(:) = corden(:) + fb*REAL(2*j - 2, dp)*fe(:)/rr(:)*rc**(2*j - 3)
                        corden(:) = corden(:) + REAL((2*j - 2)*(2*j - 3), dp)*fe(:)*rc**(2*j - 4)*cval/a2
                        corden(:) = corden(:) - REAL(2*j - 2, dp)*fe(:)*rc**(2*j - 2)*cval/a2
                     END IF
                  ELSE
                     CPABORT("")
                  END IF
               END DO
            END DO
            DEALLOCATE (fe, rc)
         END IF
      CASE (upf_pseudo)
         IF (potential%upf_pot%core_correction) THEN
            m = SIZE(corden)
            n = potential%upf_pot%mesh_size
            reverse = .FALSE.
            IF (rr(1) > rr(m)) reverse = .TRUE.
            ALLOCATE (rhoc(m), rval(m))
            IF (reverse) THEN
               DO i = 1, m
                  rval(i) = rr(m - i + 1)
               END DO
            ELSE
               rval(1:m) = rr(1:m)
            END IF
            IF (my_typ == "RHO") THEN
               CALL spline3ders(potential%upf_pot%r(1:n), potential%upf_pot%rho_nlcc(1:n), rval(1:m), &
                                ynew=rhoc(1:m))
            ELSE IF (my_typ == "DER") THEN
               CALL spline3ders(potential%upf_pot%r(1:n), potential%upf_pot%rho_nlcc(1:n), rval(1:m), &
                                dynew=rhoc(1:m))
            ELSE IF (my_typ == "LAP") THEN
               CALL spline3ders(potential%upf_pot%r(1:n), potential%upf_pot%rho_nlcc(1:n), rval(1:m), &
                                d2ynew=rhoc(1:m))
            ELSE
               CPABORT("")
            END IF
            IF (reverse) THEN
               DO i = 1, m
                  rval(i) = rr(m - i + 1)
                  corden(i) = corden(i) + rhoc(m - i + 1)
               END DO
            ELSE
               corden(1:m) = corden(1:m) + rhoc(1:m)
            END IF
            DEALLOCATE (rhoc, rval)
         END IF
      CASE (sgp_pseudo)
         IF (potential%sgp_pot%has_nlcc) THEN
            CPABORT("not implemented")
         END IF
      CASE DEFAULT
         CPABORT("Unknown PP type")
      END SELECT

   END SUBROUTINE atom_core_density

! **************************************************************************************************
!> \brief ...
!> \param locpot ...
!> \param gthpot ...
!> \param rr ...
! **************************************************************************************************
   PURE SUBROUTINE atom_local_potential(locpot, gthpot, rr)
      REAL(KIND=dp), DIMENSION(:), INTENT(INOUT)         :: locpot
      TYPE(atom_gthpot_type), INTENT(IN)                 :: gthpot
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: rr

      INTEGER                                            :: i, j, m, n
      REAL(KIND=dp)                                      :: a
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: fe, rc

      m = SIZE(locpot)
      ALLOCATE (fe(m), rc(m))
      rc(:) = rr(:)/gthpot%rc
      DO i = 1, m
         locpot(i) = -gthpot%zion*erf(rc(i)/SQRT(2._dp))/rr(i)
      END DO
      n = gthpot%ncl
      fe(:) = EXP(-0.5_dp*rc(:)*rc(:))
      DO i = 1, n
         locpot(:) = locpot(:) + fe(:)*rc**(2*i - 2)*gthpot%cl(i)
      END DO
      IF (gthpot%lpotextended) THEN
         DO j = 1, gthpot%nexp_lpot
            a = gthpot%alpha_lpot(j)
            rc(:) = rr(:)/a
            fe(:) = EXP(-0.5_dp*rc(:)*rc(:))
            n = gthpot%nct_lpot(j)
            DO i = 1, n
               locpot(:) = locpot(:) + fe(:)*rc**(2*i - 2)*gthpot%cval_lpot(i, j)
            END DO
         END DO
      END IF
      DEALLOCATE (fe, rc)

   END SUBROUTINE atom_local_potential

! **************************************************************************************************
!> \brief ...
!> \param rmax ...
!> \param wfn ...
!> \param rcov ...
!> \param l ...
!> \param basis ...
! **************************************************************************************************
   PURE SUBROUTINE atom_orbital_max(rmax, wfn, rcov, l, basis)
      REAL(KIND=dp), INTENT(OUT)                         :: rmax
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: wfn
      REAL(KIND=dp), INTENT(IN)                          :: rcov
      INTEGER, INTENT(IN)                                :: l
      TYPE(atom_basis_type), INTENT(IN)                  :: basis

      INTEGER                                            :: i, m, n
      REAL(KIND=dp)                                      :: ff
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: dorb

      m = SIZE(basis%bf, 1)
      ALLOCATE (dorb(m))
      n = basis%nbas(l)
      dorb = 0._dp
      DO i = 1, n
         ff = wfn(i)
         dorb(1:m) = dorb(1:m) + ff*basis%dbf(1:m, i, l)
      END DO
      rmax = -1._dp
      DO i = 1, m - 1
         IF (basis%grid%rad(i) < 2*rcov) THEN
            IF (dorb(i)*dorb(i + 1) < 0._dp) THEN
               rmax = MAX(rmax, basis%grid%rad(i))
            END IF
         END IF
      END DO
      DEALLOCATE (dorb)

   END SUBROUTINE atom_orbital_max

! **************************************************************************************************
!> \brief ...
!> \param node ...
!> \param wfn ...
!> \param rcov ...
!> \param l ...
!> \param basis ...
! **************************************************************************************************
   PURE SUBROUTINE atom_orbital_nodes(node, wfn, rcov, l, basis)
      INTEGER, INTENT(OUT)                               :: node
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: wfn
      REAL(KIND=dp), INTENT(IN)                          :: rcov
      INTEGER, INTENT(IN)                                :: l
      TYPE(atom_basis_type), INTENT(IN)                  :: basis

      INTEGER                                            :: i, m, n
      REAL(KIND=dp)                                      :: ff
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: orb

      node = 0
      m = SIZE(basis%bf, 1)
      ALLOCATE (orb(m))
      n = basis%nbas(l)
      orb = 0._dp
      DO i = 1, n
         ff = wfn(i)
         orb(1:m) = orb(1:m) + ff*basis%bf(1:m, i, l)
      END DO
      DO i = 1, m - 1
         IF (basis%grid%rad(i) < rcov) THEN
            IF (orb(i)*orb(i + 1) < 0._dp) node = node + 1
         END IF
      END DO
      DEALLOCATE (orb)

   END SUBROUTINE atom_orbital_nodes

! **************************************************************************************************
!> \brief ...
!> \param value ...
!> \param wfn ...
!> \param basis ...
! **************************************************************************************************
   PURE SUBROUTINE atom_wfnr0(value, wfn, basis)
      REAL(KIND=dp), INTENT(OUT)                         :: value
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: wfn
      TYPE(atom_basis_type), INTENT(IN)                  :: basis

      INTEGER                                            :: i, m, n

      value = 0._dp
      m = MAXVAL(MINLOC(basis%grid%rad))
      n = basis%nbas(0)
      DO i = 1, n
         value = value + wfn(i)*basis%bf(m, i, 0)
      END DO
   END SUBROUTINE atom_wfnr0

! **************************************************************************************************
!> \brief Solve the generalised eigenproblem for every angular momentum.
!> \param hmat  Hamiltonian matrix
!> \param umat  transformation matrix which reduces the overlap matrix to its unitary form
!> \param orb   atomic wavefunctions
!> \param ener  atomic orbital energies
!> \param nb    number of contracted basis functions
!> \param nv    number of linear-independent contracted basis functions
!> \param maxl  maximum angular momentum to consider
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE atom_solve(hmat, umat, orb, ener, nb, nv, maxl)
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(IN)     :: hmat, umat
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(INOUT)  :: orb
      REAL(KIND=dp), DIMENSION(:, 0:), INTENT(INOUT)     :: ener
      INTEGER, DIMENSION(0:), INTENT(IN)                 :: nb, nv
      INTEGER, INTENT(IN)                                :: maxl

      INTEGER                                            :: info, l, lwork, m, n
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: w, work
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :)        :: a

      CPASSERT(ALL(nb >= nv))

      orb = 0._dp
      DO l = 0, maxl
         n = nb(l)
         m = nv(l)
         IF (n > 0 .AND. m > 0) THEN
            lwork = 10*m
            ALLOCATE (a(n, n), w(n), work(lwork))
            a(1:m, 1:m) = MATMUL(TRANSPOSE(umat(1:n, 1:m, l)), MATMUL(hmat(1:n, 1:n, l), umat(1:n, 1:m, l)))
            CALL lapack_ssyev("V", "U", m, a(1:m, 1:m), m, w(1:m), work, lwork, info)
            a(1:n, 1:m) = MATMUL(umat(1:n, 1:m, l), a(1:m, 1:m))

            m = MIN(m, SIZE(orb, 2))
            orb(1:n, 1:m, l) = a(1:n, 1:m)
            ener(1:m, l) = w(1:m)

            DEALLOCATE (a, w, work)
         END IF
      END DO

   END SUBROUTINE atom_solve

! **************************************************************************************************
!> \brief THIS FUNCTION IS NO LONGER IN USE.
!> \param fun ...
!> \param deps ...
!> \return ...
! **************************************************************************************************
   FUNCTION prune_grid(fun, deps) RESULT(nc)
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: fun
      REAL(KIND=dp), INTENT(IN), OPTIONAL                :: deps
      INTEGER                                            :: nc

      INTEGER                                            :: i, nr
      REAL(KIND=dp)                                      :: meps

      meps = 1.e-14_dp
      IF (PRESENT(deps)) meps = deps

      nr = SIZE(fun)
      nc = 0
      DO i = nr, 1, -1
         IF (ABS(fun(i)) > meps) THEN
            nc = i
            EXIT
         END IF
      END DO

   END FUNCTION prune_grid

! **************************************************************************************************
!> \brief Integrate a function on an atomic radial grid.
!> \param fun   function to integrate
!> \param grid  atomic radial grid
!> \return      value of the integral
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   PURE FUNCTION integrate_grid_function1(fun, grid) RESULT(integral)
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: fun
      TYPE(grid_atom_type), INTENT(IN)                   :: grid
      REAL(KIND=dp)                                      :: integral

      INTEGER                                            :: nc

      nc = SIZE(fun)
      integral = SUM(fun(1:nc)*grid%wr(1:nc))

   END FUNCTION integrate_grid_function1

! **************************************************************************************************
!> \brief Integrate the product of two functions on an atomic radial grid.
!> \param fun1  first function
!> \param fun2  second function
!> \param grid  atomic radial grid
!> \return      value of the integral
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   PURE FUNCTION integrate_grid_function2(fun1, fun2, grid) RESULT(integral)
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: fun1, fun2
      TYPE(grid_atom_type), INTENT(IN)                   :: grid
      REAL(KIND=dp)                                      :: integral

      INTEGER                                            :: nc

      nc = MIN(SIZE(fun1), SIZE(fun2))
      integral = SUM(fun1(1:nc)*fun2(1:nc)*grid%wr(1:nc))

   END FUNCTION integrate_grid_function2

! **************************************************************************************************
!> \brief Integrate the product of three functions on an atomic radial grid.
!> \param fun1  first function
!> \param fun2  second function
!> \param fun3  third function
!> \param grid  atomic radial grid
!> \return      value of the integral
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   PURE FUNCTION integrate_grid_function3(fun1, fun2, fun3, grid) RESULT(integral)
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: fun1, fun2, fun3
      TYPE(grid_atom_type), INTENT(IN)                   :: grid
      REAL(KIND=dp)                                      :: integral

      INTEGER                                            :: nc

      nc = MIN(SIZE(fun1), SIZE(fun2), SIZE(fun3))
      integral = SUM(fun1(1:nc)*fun2(1:nc)*fun3(1:nc)*grid%wr(1:nc))

   END FUNCTION integrate_grid_function3

! **************************************************************************************************
!> \brief Numerically compute the Coulomb potential on an atomic radial grid.
!> \param cpot     Coulomb potential on the radial grid
!> \param density  electron density on the radial grid
!> \param grid     atomic radial grid
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE coulomb_potential_numeric(cpot, density, grid)
      REAL(KIND=dp), DIMENSION(:), INTENT(INOUT)         :: cpot
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: density
      TYPE(grid_atom_type), INTENT(IN)                   :: grid

      INTEGER                                            :: i, nc
      REAL(dp)                                           :: int1, int2
      REAL(dp), DIMENSION(:), POINTER                    :: r, wr

      nc = MIN(SIZE(cpot), SIZE(density))
      r => grid%rad
      wr => grid%wr

      int1 = fourpi*integrate_grid(density, grid)
      int2 = 0._dp
      cpot(nc:) = int1/r(nc:)
      !   IF (log_unit>0) WRITE(log_unit,"(A,2F10.8)") "r", int1, cpot(nc:)

      ! test that grid is decreasing
      CPASSERT(r(1) > r(nc))
      DO i = 1, nc
         cpot(i) = int1/r(i) + int2
         int1 = int1 - fourpi*density(i)*wr(i)
         int2 = int2 + fourpi*density(i)*wr(i)/r(i)
      END DO

   END SUBROUTINE coulomb_potential_numeric

! **************************************************************************************************
!> \brief Analytically compute the Coulomb potential on an atomic radial grid.
!> \param cpot   Coulomb potential on the radial grid
!> \param pmat   density matrix
!> \param basis  atomic basis set
!> \param grid   atomic radial grid
!> \param maxl   maximum angular momentum to consider
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE coulomb_potential_analytic(cpot, pmat, basis, grid, maxl)
      REAL(KIND=dp), DIMENSION(:), INTENT(INOUT)         :: cpot
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(IN)     :: pmat
      TYPE(atom_basis_type), INTENT(IN)                  :: basis
      TYPE(grid_atom_type)                               :: grid
      INTEGER, INTENT(IN)                                :: maxl

      INTEGER                                            :: i, j, k, l, m, n
      REAL(KIND=dp)                                      :: a, b, ff, oab, sab
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: erfa, expa, z
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :)        :: unp

      m = SIZE(cpot)
      ALLOCATE (erfa(1:m), expa(1:m), z(1:m))

      cpot = 0._dp

      DO l = 0, maxl
         IF (MAXVAL(ABS(pmat(:, :, l))) < 1.e-14_dp) CYCLE
         SELECT CASE (basis%basis_type)
         CASE DEFAULT
            CPABORT("")
         CASE (GTO_BASIS)
            DO i = 1, basis%nbas(l)
               DO j = i, basis%nbas(l)
                  IF (ABS(pmat(i, j, l)) < 1.e-14_dp) CYCLE
                  ff = pmat(i, j, l)
                  IF (i /= j) ff = 2._dp*ff
                  a = basis%am(i, l)
                  b = basis%am(j, l)
                  sab = SQRT(a + b)
                  oab = rootpi/(a + b)**(l + 1.5_dp)*ff
                  z(:) = sab*grid%rad(:)
                  DO k = 1, SIZE(erfa)
                     erfa(k) = oab*erf(z(k))/grid%rad(k)
                  END DO
                  expa(:) = EXP(-z(:)**2)*ff/(a + b)**(l + 1)
                  SELECT CASE (l)
                  CASE DEFAULT
                     CPABORT("")
                  CASE (0)
                     cpot(:) = cpot(:) + 0.25_dp*erfa(:)
                  CASE (1)
                     cpot(:) = cpot(:) + 0.375_dp*erfa(:) - 0.25_dp*expa(:)
                  CASE (2)
                     cpot(:) = cpot(:) + 0.9375_dp*erfa(:) - expa(:)*(0.875_dp + 0.25_dp*z(:)**2)
                  CASE (3)
                     cpot(:) = cpot(:) + 3.28125_dp*erfa(:) - expa(:)*(3.5625_dp + 1.375_dp*z(:)**2 + 0.25*z(:)**4)
                  END SELECT
               END DO
            END DO
         CASE (CGTO_BASIS)
            n = basis%nprim(l)
            m = basis%nbas(l)
            ALLOCATE (unp(n, n))

            unp(1:n, 1:n) = MATMUL(MATMUL(basis%cm(1:n, 1:m, l), pmat(1:m, 1:m, l)), &
                                   TRANSPOSE(basis%cm(1:n, 1:m, l)))
            DO i = 1, basis%nprim(l)
               DO j = i, basis%nprim(l)
                  IF (ABS(unp(i, j)) < 1.e-14_dp) CYCLE
                  ff = unp(i, j)
                  IF (i /= j) ff = 2._dp*ff
                  a = basis%am(i, l)
                  b = basis%am(j, l)
                  sab = SQRT(a + b)
                  oab = rootpi/(a + b)**(l + 1.5_dp)*ff
                  z(:) = sab*grid%rad(:)
                  DO k = 1, SIZE(erfa)
                     erfa(k) = oab*erf(z(k))/grid%rad(k)
                  END DO
                  expa(:) = EXP(-z(:)**2)*ff/(a + b)**(l + 1)
                  SELECT CASE (l)
                  CASE DEFAULT
                     CPABORT("")
                  CASE (0)
                     cpot(:) = cpot(:) + 0.25_dp*erfa(:)
                  CASE (1)
                     cpot(:) = cpot(:) + 0.375_dp*erfa(:) - 0.25_dp*expa(:)
                  CASE (2)
                     cpot(:) = cpot(:) + 0.9375_dp*erfa(:) - expa(:)*(0.875_dp + 0.25_dp*z(:)**2)
                  CASE (3)
                     cpot(:) = cpot(:) + 3.28125_dp*erfa(:) - expa(:)*(3.5625_dp + 1.375_dp*z(:)**2 + 0.25*z(:)**4)
                  END SELECT
               END DO
            END DO

            DEALLOCATE (unp)
         END SELECT
      END DO
      DEALLOCATE (erfa, expa, z)

   END SUBROUTINE coulomb_potential_analytic

! **************************************************************************************************
!> \brief Calculate the exchange potential numerically.
!> \param kmat   Kohn-Sham matrix
!> \param state  electronic state
!> \param occ    occupation numbers
!> \param wfn    wavefunctions
!> \param basis  atomic basis set
!> \param hfx_pot potential parameters from Hartree-Fock section
!> \par History
!>    * 01.2009 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE exchange_numeric(kmat, state, occ, wfn, basis, hfx_pot)
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(INOUT)  :: kmat
      TYPE(atom_state), INTENT(IN)                       :: state
      REAL(KIND=dp), DIMENSION(0:, :), INTENT(IN)        :: occ
      REAL(KIND=dp), DIMENSION(:, :, :), POINTER         :: wfn
      TYPE(atom_basis_type), INTENT(IN)                  :: basis
      TYPE(atom_hfx_type), INTENT(IN)                    :: hfx_pot

      INTEGER                                            :: i, ia, ib, k, lad, lbc, lh, ll, nbas, &
                                                            norb, nr, nu
      REAL(KIND=dp)                                      :: almn
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: cpot, nai, nbi, pot
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :)        :: orb
      REAL(KIND=dp), DIMENSION(0:maxfac)                 :: arho

      arho = 0._dp
      DO ll = 0, maxfac, 2
         lh = ll/2
         arho(ll) = fac(ll)/fac(lh)**2
      END DO

      kmat = 0._dp

      nr = basis%grid%nr
      ALLOCATE (nai(nr), nbi(nr), cpot(nr), pot(nr))

      DO lad = 0, state%maxl_calc
         DO lbc = 0, state%maxl_occ
            norb = state%maxn_occ(lbc)
            nbas = basis%nbas(lbc)
            ! calculate orbitals for angmom lbc
            ALLOCATE (orb(nr, norb))
            orb = 0._dp
            DO i = 1, norb
               DO k = 1, nbas
                  orb(:, i) = orb(:, i) + wfn(k, i, lbc)*basis%bf(:, k, lbc)
               END DO
            END DO
            DO nu = ABS(lad - lbc), lad + lbc, 2
               almn = arho(-lad + lbc + nu)*arho(lad - lbc + nu)*arho(lad + lbc - nu)/(REAL(lad + lbc + nu + 1, dp) &
                                                                                       *arho(lad + lbc + nu))
               almn = -0.5_dp*almn

               DO ia = 1, basis%nbas(lad)
                  DO i = 1, norb
                     nai(:) = orb(:, i)*basis%bf(:, ia, lad)
                     cpot = 0.0_dp
                     IF (hfx_pot%scale_coulomb /= 0.0_dp) THEN
                        CALL potential_coulomb_numeric(pot, nai, nu, basis%grid)
                        cpot(:) = cpot(:) + pot(:)*hfx_pot%scale_coulomb
                     END IF
                     IF (hfx_pot%scale_longrange /= 0.0_dp) THEN
                        IF (hfx_pot%do_gh) THEN
                           CALL potential_longrange_numeric_gh(pot, nai, nu, basis%grid, hfx_pot%omega, &
                                                               hfx_pot%kernel(:, :, nu))
                        ELSE
                           CALL potential_longrange_numeric(pot, nai, nu, basis%grid, hfx_pot%omega, &
                                                            hfx_pot%kernel(:, :, nu))
                        END IF
                        cpot(:) = cpot(:) + pot(:)*hfx_pot%scale_longrange
                     END IF
                     DO ib = 1, basis%nbas(lad)
                        kmat(ia, ib, lad) = kmat(ia, ib, lad) + almn*occ(lbc, i)* &
                                            integrate_grid(cpot, orb(:, i), basis%bf(:, ib, lad), basis%grid)
                     END DO
                  END DO
               END DO

            END DO
            DEALLOCATE (orb)
         END DO
      END DO

      DEALLOCATE (nai, nbi, cpot)

   END SUBROUTINE exchange_numeric

! **************************************************************************************************
!> \brief Calculate the exchange potential semi-analytically.
!> \param kmat   Kohn-Sham matrix
!> \param state  electronic state
!> \param occ    occupation numbers
!> \param wfn    wavefunctions
!> \param basis  atomic basis set
!> \param hfx_pot properties of the Hartree-Fock potential
!> \par History
!>    * 01.2009 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE exchange_semi_analytic(kmat, state, occ, wfn, basis, hfx_pot)
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(INOUT)  :: kmat
      TYPE(atom_state), INTENT(IN)                       :: state
      REAL(KIND=dp), DIMENSION(0:, :), INTENT(IN)        :: occ
      REAL(KIND=dp), DIMENSION(:, :, :), POINTER         :: wfn
      TYPE(atom_basis_type), INTENT(IN)                  :: basis
      TYPE(atom_hfx_type), INTENT(IN)                    :: hfx_pot

      INTEGER                                            :: i, ia, ib, k, lad, lbc, lh, ll, nbas, &
                                                            norb, nr, nu
      REAL(KIND=dp)                                      :: almn
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: cpot, nai, nbi
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :)        :: orb
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :, :)     :: pot
      REAL(KIND=dp), DIMENSION(0:maxfac)                 :: arho

      arho = 0._dp
      DO ll = 0, maxfac, 2
         lh = ll/2
         arho(ll) = fac(ll)/fac(lh)**2
      END DO

      kmat = 0._dp

      nr = basis%grid%nr
      nbas = MAXVAL(basis%nbas)
      ALLOCATE (pot(nr, nbas, nbas))
      ALLOCATE (nai(nr), nbi(nr), cpot(nr))

      DO lad = 0, state%maxl_calc
         DO lbc = 0, state%maxl_occ
            norb = state%maxn_occ(lbc)
            nbas = basis%nbas(lbc)
            ! calculate orbitals for angmom lbc
            ALLOCATE (orb(nr, norb))
            orb = 0._dp
            DO i = 1, norb
               DO k = 1, nbas
                  orb(:, i) = orb(:, i) + wfn(k, i, lbc)*basis%bf(:, k, lbc)
               END DO
            END DO
            DO nu = ABS(lad - lbc), lad + lbc, 2
               almn = arho(-lad + lbc + nu)*arho(lad - lbc + nu) &
                      *arho(lad + lbc - nu)/(REAL(lad + lbc + nu + 1, dp)*arho(lad + lbc + nu))
               almn = -0.5_dp*almn
               ! calculate potential for basis function pair (lad,lbc)
               pot = 0._dp
               CALL potential_analytic(pot, lad, lbc, nu, basis, hfx_pot)
               DO ia = 1, basis%nbas(lad)
                  DO i = 1, norb
                     cpot = 0._dp
                     DO k = 1, nbas
                        cpot(:) = cpot(:) + pot(:, ia, k)*wfn(k, i, lbc)
                     END DO
                     DO ib = 1, basis%nbas(lad)
                        kmat(ia, ib, lad) = kmat(ia, ib, lad) + almn*occ(lbc, i)* &
                                            integrate_grid(cpot, orb(:, i), basis%bf(:, ib, lad), basis%grid)
                     END DO
                  END DO
               END DO
            END DO
            DEALLOCATE (orb)
         END DO
      END DO

      DEALLOCATE (pot)
      DEALLOCATE (nai, nbi, cpot)

   END SUBROUTINE exchange_semi_analytic

! **************************************************************************************************
!> \brief Calculate the electrostatic potential using numerical differentiation.
!> \param cpot     computed potential
!> \param density  electron density on the atomic radial grid
!> \param nu       integer parameter [ABS(la-lb) .. la+lb];
!>                 see potential_analytic() and exchange_numeric()
!> \param grid     atomic radial grid
!> \par History
!>    * 01.2009 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE potential_coulomb_numeric(cpot, density, nu, grid)
      REAL(KIND=dp), DIMENSION(:), INTENT(OUT)           :: cpot
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: density
      INTEGER, INTENT(IN)                                :: nu
      TYPE(grid_atom_type), INTENT(IN)                   :: grid

      INTEGER                                            :: i, nc
      REAL(dp)                                           :: int1, int2
      REAL(dp), DIMENSION(:), POINTER                    :: r, wr

      nc = MIN(SIZE(cpot), SIZE(density))
      r => grid%rad
      wr => grid%wr

      int1 = integrate_grid(density, r**nu, grid)
      int2 = 0._dp
      cpot(nc:) = int1/r(nc:)**(nu + 1)

      ! test that grid is decreasing
      CPASSERT(r(1) > r(nc))
      DO i = 1, nc
         cpot(i) = int1/r(i)**(nu + 1) + int2*r(i)**nu
         int1 = int1 - r(i)**(nu)*density(i)*wr(i)
         int2 = int2 + density(i)*wr(i)/r(i)**(nu + 1)
      END DO

   END SUBROUTINE potential_coulomb_numeric

! **************************************************************************************************
!> \brief ...
!> \param cpot ...
!> \param density ...
!> \param nu ...
!> \param grid ...
!> \param omega ...
!> \param kernel ...
! **************************************************************************************************
   SUBROUTINE potential_longrange_numeric(cpot, density, nu, grid, omega, kernel)
      REAL(KIND=dp), DIMENSION(:), INTENT(OUT)           :: cpot
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: density
      INTEGER, INTENT(IN)                                :: nu
      TYPE(grid_atom_type), INTENT(IN)                   :: grid
      REAL(KIND=dp), INTENT(IN)                          :: omega
      REAL(KIND=dp), DIMENSION(:, :), INTENT(IN)         :: kernel

      INTEGER                                            :: nc
      REAL(dp), DIMENSION(:), POINTER                    :: r, wr
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: work_inp, work_out

      nc = MIN(SIZE(cpot), SIZE(density))
      r => grid%rad
      wr => grid%wr

      ALLOCATE (work_inp(nc), work_out(nc))

      cpot = 0.0_dp

      ! First Bessel transform
      work_inp(:nc) = density(:nc)*wr(:nc)
      CALL DSYMV('U', nc, 1.0_dp, kernel, nc, work_inp, 1, 0.0_dp, work_out, 1)

      ! Second Bessel transform
      work_inp(:nc) = work_out(:nc)*EXP(-r(:nc)**2)/r(:nc)**2*wr(:nc)
      CALL DSYMV('U', nc, 1.0_dp, kernel, nc, work_inp, 1, 0.0_dp, work_out, 1)

      cpot(:nc) = work_out(:nc)*(2.0_dp*REAL(nu, dp) + 1.0_dp)*4.0_dp/pi*omega

   END SUBROUTINE potential_longrange_numeric

! **************************************************************************************************
!> \brief ...
!> \param cpot ...
!> \param density ...
!> \param nu ...
!> \param grid ...
!> \param omega ...
!> \param kernel ...
! **************************************************************************************************
   SUBROUTINE potential_longrange_numeric_gh(cpot, density, nu, grid, omega, kernel)
      REAL(KIND=dp), DIMENSION(:), INTENT(OUT)           :: cpot
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: density
      INTEGER, INTENT(IN)                                :: nu
      TYPE(grid_atom_type), INTENT(IN)                   :: grid
      REAL(KIND=dp), INTENT(IN)                          :: omega
      REAL(KIND=dp), DIMENSION(:, :), INTENT(IN)         :: kernel

      INTEGER                                            :: n_max, nc, nc_kernel, nr_kernel
      REAL(dp), DIMENSION(:), POINTER                    :: wr
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: work_inp, work_out

      nc = MIN(SIZE(cpot), SIZE(density))
      wr => grid%wr

      nc_kernel = SIZE(kernel, 1)
      nr_kernel = SIZE(kernel, 2)
      n_max = MAX(nc, nc_kernel, nr_kernel)

      ALLOCATE (work_inp(n_max), work_out(n_max))

      cpot = 0.0_dp

      ! First Bessel transform
      work_inp(:nc) = density(:nc)*wr(:nc)
      CALL DGEMV('T', nc_kernel, nr_kernel, 1.0_dp, kernel, nc_kernel, work_inp, 1, 0.0_dp, work_out, 1)

      ! Second Bessel transform
      work_inp(:nr_kernel) = work_out(:nr_kernel)
      CALL DGEMV('N', nc_kernel, nr_kernel, 1.0_dp, kernel, nc_kernel, work_inp, 1, 0.0_dp, work_out, 1)

      cpot(:nc) = work_out(:nc)*(2.0_dp*REAL(nu, dp) + 1.0_dp)*4.0_dp/pi*omega

   END SUBROUTINE potential_longrange_numeric_gh

! **************************************************************************************************
!> \brief Calculate the electrostatic potential using analytical expressions.
!>        The interaction potential has the form
!>        V(r)=scale_coulomb*1/r+scale_lr*erf(omega*r)/r
!> \param cpot   computed potential
!> \param la     angular momentum of the calculated state
!> \param lb     angular momentum of the occupied state
!> \param nu     integer parameter [ABS(la-lb) .. la+lb] with the parity of 'la+lb'
!> \param basis  atomic basis set
!> \param hfx_pot properties of the Hartree-Fock potential
!> \par History
!>    * 01.2009 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE potential_analytic(cpot, la, lb, nu, basis, hfx_pot)
      REAL(KIND=dp), DIMENSION(:, :, :), INTENT(OUT)     :: cpot
      INTEGER, INTENT(IN)                                :: la, lb, nu
      TYPE(atom_basis_type), INTENT(IN)                  :: basis
      TYPE(atom_hfx_type), INTENT(IN)                    :: hfx_pot

      INTEGER                                            :: i, j, k, l, ll, m
      REAL(KIND=dp)                                      :: a, b
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: erfa, pot

      m = SIZE(cpot, 1)
      ALLOCATE (erfa(1:m))

      ll = la + lb

      cpot = 0._dp

      SELECT CASE (basis%basis_type)
      CASE DEFAULT
         CPABORT("")
      CASE (GTO_BASIS)
         DO i = 1, basis%nbas(la)
            DO j = 1, basis%nbas(lb)
               a = basis%am(i, la)
               b = basis%am(j, lb)

               IF (hfx_pot%scale_coulomb /= 0.0_dp) THEN
                  CALL potential_coulomb_analytic(erfa, a, b, ll, nu, basis%grid%rad)

                  cpot(:, i, j) = cpot(:, i, j) + erfa(:)*hfx_pot%scale_coulomb
               END IF

               IF (hfx_pot%scale_longrange /= 0.0_dp) THEN
                  CALL potential_longrange_analytic(erfa, a, b, ll, nu, basis%grid%rad, hfx_pot%omega)

                  cpot(:, i, j) = cpot(:, i, j) + erfa(:)*hfx_pot%scale_longrange
               END IF
            END DO
         END DO
      CASE (CGTO_BASIS)
         ALLOCATE (pot(1:m))

         DO i = 1, basis%nprim(la)
            DO j = 1, basis%nprim(lb)
               a = basis%am(i, la)
               b = basis%am(j, lb)

               pot = 0.0_dp

               IF (hfx_pot%scale_coulomb /= 0.0_dp) THEN
                  CALL potential_coulomb_analytic(erfa, a, b, ll, nu, basis%grid%rad)

                  pot(:) = pot(:) + erfa(:)*hfx_pot%scale_coulomb
               END IF

               IF (hfx_pot%scale_longrange /= 0.0_dp) THEN
                  CALL potential_longrange_analytic(erfa, a, b, ll, nu, basis%grid%rad, hfx_pot%omega)

                  pot(:) = pot(:) + erfa(:)*hfx_pot%scale_longrange
               END IF

               DO k = 1, basis%nbas(la)
                  DO l = 1, basis%nbas(lb)
                     cpot(:, k, l) = cpot(:, k, l) + pot(:)*basis%cm(i, k, la)*basis%cm(j, l, lb)
                  END DO
               END DO
            END DO
         END DO

      END SELECT

      DEALLOCATE (erfa)

   END SUBROUTINE potential_analytic

! **************************************************************************************************
!> \brief ...
!> \param erfa Array will contain the potential
!> \param a Exponent of first Gaussian charge distribution
!> \param b Exponent of second Gaussian charge distribution
!> \param ll Sum of angular momentum quantum numbers building one charge distribution
!> \param nu Angular momentum of interaction, (ll-nu) should be even.
!> \param rad Radial grid
! **************************************************************************************************
   SUBROUTINE potential_coulomb_analytic(erfa, a, b, ll, nu, rad)
      REAL(KIND=dp), DIMENSION(:), INTENT(OUT)           :: erfa
      REAL(KIND=dp), INTENT(IN)                          :: a, b
      INTEGER, INTENT(IN)                                :: ll, nu
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: rad

      INTEGER                                            :: nr
      REAL(KIND=dp)                                      :: oab, sab
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: expa, z

      nr = SIZE(rad)
      ALLOCATE (expa(nr), z(nr))

      sab = SQRT(a + b)
      oab = dfac(ll + nu + 1)*rootpi/sab**(ll + 2)/2._dp**((ll + nu)/2 + 2)
      z(:) = sab*rad(:)
      erfa(:) = oab*erf(z(:))/z(:)**(nu + 1)
      expa(:) = EXP(-z(:)**2)/sab**(ll + 2)/2._dp**((ll + nu)/2 + 2)
      SELECT CASE (ll)
      CASE DEFAULT
         CPABORT("")
      CASE (0)
         CPASSERT(nu == 0)
      CASE (1)
         CPASSERT(nu == 1)
         erfa(:) = erfa(:) - 6._dp*expa(:)/z(:)
      CASE (2)
         SELECT CASE (nu)
         CASE DEFAULT
            CPABORT("")
         CASE (0)
            erfa(:) = erfa(:) - 2._dp*expa(:)
         CASE (2)
            erfa(:) = erfa(:) - expa(:)*(20._dp + 30._dp/z(:)**2)
         END SELECT
      CASE (3)
         SELECT CASE (nu)
         CASE DEFAULT
            CPABORT("")
         CASE (1)
            erfa(:) = erfa(:) - expa(:)*(12._dp*z(:) + 30._dp/z(:))
         CASE (3)
            erfa(:) = erfa(:) - expa(:)*(56._dp*z(:) + 140._dp/z(:) + 210._dp/z(:)**3)
         END SELECT
      CASE (4)
         SELECT CASE (nu)
         CASE DEFAULT
            CPABORT("")
         CASE (0)
            erfa(:) = erfa(:) - expa(:)*(4._dp*z(:)**2 + 14._dp)
         CASE (2)
            erfa(:) = erfa(:) - expa(:)*(40._dp*z(:)**2 + 140._dp + 210._dp/z(:)**2)
         CASE (4)
            erfa(:) = erfa(:) - expa(:)*(144._dp*z(:)**2 + 504._dp + 1260._dp/z(:)**2 + 1890._dp/z(:)**4)
         END SELECT
      CASE (5)
         SELECT CASE (nu)
         CASE DEFAULT
            CPABORT("")
         CASE (1)
            erfa(:) = erfa(:) - expa(:)*(24._dp*z(:)**3 + 108._dp*z(:) + 210._dp/z(:))
         CASE (3)
            erfa(:) = erfa(:) - expa(:)*(112._dp*z(:)**3 + 504._dp*z(:) + 1260._dp/z(:) + 1890._dp/z(:)**3)
         CASE (5)
            erfa(:) = erfa(:) - expa(:)*(352._dp*z(:)**3 + 1584._dp*z(:) + 5544._dp/z(:) + &
                                         13860._dp/z(:)**3 + 20790._dp/z(:)**5)
         END SELECT
      CASE (6)
         SELECT CASE (nu)
         CASE DEFAULT
            CPABORT("")
         CASE (0)
            erfa(:) = erfa(:) - expa(:)*(8._dp*z(:)**4 + 44._dp*z(:)**2 + 114._dp)
         CASE (2)
            erfa(:) = erfa(:) - expa(:)*(80._dp*z(:)**4 + 440._dp*z(:)**2 + 1260._dp + 1896._dp/z(:)**2)
         CASE (4)
            erfa(:) = erfa(:) - expa(:)*(288._dp*z(:)**4 + 1584._dp*z(:)**2 + 5544._dp + &
                                         13860._dp/z(:)**2 + 20790._dp/z(:)**4)
         CASE (6)
            erfa(:) = erfa(:) - expa(:)*(832._dp*z(:)**4 + 4576._dp*z(:)**2 + 20592._dp + &
                                         72072._dp/z(:)**2 + 180180._dp/z(:)**4 + 270270._dp/z(:)**6)
         END SELECT
      END SELECT

      DEALLOCATE (expa, z)

   END SUBROUTINE potential_coulomb_analytic

! **************************************************************************************************
!> \brief This routine calculates the longrange Coulomb potential of a product of two Gaussian with given angular momentum
!> \param erfa Array will contain the potential
!> \param a Exponent of first Gaussian charge distribution
!> \param b Exponent of second Gaussian charge distribution
!> \param ll Sum of angular momentum quantum numbers building one charge distribution
!> \param nu Angular momentum of interaction, (ll-nu) should be even.
!> \param rad Radial grid
!> \param omega Range-separation parameter
! **************************************************************************************************
   PURE SUBROUTINE potential_longrange_analytic(erfa, a, b, ll, nu, rad, omega)
      REAL(KIND=dp), DIMENSION(:), INTENT(OUT)           :: erfa
      REAL(KIND=dp), INTENT(IN)                          :: a, b
      INTEGER, INTENT(IN)                                :: ll, nu
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: rad
      REAL(KIND=dp), INTENT(IN)                          :: omega

      INTEGER                                            :: i, lambda, nr
      REAL(KIND=dp)                                      :: ab, oab, pab, prel, sab
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: expa, z

      IF (MOD(ll - nu, 2) == 0 .AND. ll >= nu .AND. nu >= 0) THEN
         nr = SIZE(rad)
         ALLOCATE (expa(nr), z(nr))

         lambda = (ll - nu)/2
         ab = a + b
         sab = SQRT(ab)
         pab = omega**2*ab/(omega**2 + ab)
         prel = pab/ab
         z(:) = SQRT(pab)*rad(:)
         oab = fac(lambda)/SQRT(ab)**(ll + 2)/4.0_dp*SQRT(prel)**(nu + 1)*(2.0_dp*REAL(nu, KIND=dp) + 1.0_dp)
         expa(:) = EXP(-z(:)**2)
         lambda = (ll - nu)/2

         IF (lambda > 0) THEN
            erfa = 0.0_dp
            DO i = 1, lambda
               erfa = erfa + (-prel)**i/REAL(i, KIND=dp)*binomial_gen(lambda + nu + 0.5_dp, lambda - i)* &
                      assoc_laguerre(z, REAL(nu, KIND=dp) + 0.5_dp, i - 1)
            END DO
            erfa = erfa*expa*z**nu

            erfa = erfa + 2.0_dp*binomial_gen(lambda + nu + 0.5_dp, lambda)*znFn(z, expa, nu)
         ELSE
            erfa = 2.0_dp*znFn(z, expa, nu)
         END IF

         erfa = erfa*oab

         DEALLOCATE (expa, z)
      ELSE
         ! Contribution to potential is zero (properties of spherical harmonics)
         erfa = 0.0_dp
      END IF

   END SUBROUTINE potential_longrange_analytic

! **************************************************************************************************
!> \brief Boys' function times z**n
!> \param z ...
!> \param expa ...
!> \param n ...
!> \return ...
! **************************************************************************************************
   ELEMENTAL FUNCTION znFn(z, expa, n) RESULT(res)

      REAL(KIND=dp), INTENT(IN)                          :: z, expa
      INTEGER, INTENT(IN)                                :: n
      REAL(KIND=dp)                                      :: res

      INTEGER                                            :: i
      REAL(KIND=dp)                                      :: z_exp

      IF (n >= 0) THEN
         IF (ABS(z) < 1.0E-20) THEN
            res = z**n/(2.0_dp*REAL(n, KIND=dp) + 1.0_dp)
         ELSE IF (n == 0) THEN
            res = rootpi/2.0_dp*ERF(z)/z
         ELSE
            res = rootpi/4.0_dp*ERF(z)/z**2 - expa/z/2.0_dp
            z_exp = -expa*0.5_dp

            DO i = 2, n
               res = (REAL(i, KIND=dp) - 0.5_dp)*res/z + z_exp
               z_exp = z_exp*z
            END DO
         END IF
      ELSE ! Set it to zero (no Boys' function, to keep the ELEMENTAL keyword)
         res = 0.0_dp
      END IF

   END FUNCTION znFn

! **************************************************************************************************
!> \brief ...
!> \param z ...
!> \param a ...
!> \param n ...
!> \return ...
! **************************************************************************************************
   ELEMENTAL FUNCTION assoc_laguerre(z, a, n) RESULT(res)

      REAL(KIND=dp), INTENT(IN)                          :: z, a
      INTEGER, INTENT(IN)                                :: n
      REAL(KIND=dp)                                      :: res

      INTEGER                                            :: i
      REAL(KIND=dp)                                      :: f0, f1

      IF (n == 0) THEN
         res = 1.0_dp
      ELSE IF (n == 1) THEN
         res = a + 1.0_dp - z
      ELSE IF (n > 0) THEN
         f0 = 1.0_dp
         f1 = a + 1.0_dp - z

         DO i = 3, n
            res = (2.0_dp + (a - 1.0_dp - z)/REAL(i, dp))*f1 - (1.0_dp + (a - 1.0_dp)/REAL(i, dp))*f0
            f0 = f1
            f1 = res
         END DO
      ELSE ! n is negative, set it zero (no polynomials, to keep the ELEMENTAL keyword)
         res = 0.0_dp
      END IF

   END FUNCTION assoc_laguerre

! **************************************************************************************************
!> \brief Compute Trace[opmat * pmat] == Trace[opmat * pmat^T] .
!> \param opmat  operator matrix (e.g. Kohn-Sham matrix or overlap matrix)
!> \param pmat   density matrix
!> \return       value of trace
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   PURE FUNCTION atom_trace(opmat, pmat) RESULT(trace)
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(IN)     :: opmat, pmat
      REAL(KIND=dp)                                      :: trace

      trace = accurate_dot_product(opmat, pmat)

   END FUNCTION atom_trace

! **************************************************************************************************
!> \brief Calculate a potential matrix by integrating the potential on an atomic radial grid.
!> \param imat         potential matrix
!> \param cpot         potential on the atomic radial grid
!> \param basis        atomic basis set
!> \param derivatives  order of derivatives
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE numpot_matrix(imat, cpot, basis, derivatives)
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(INOUT)  :: imat
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: cpot
      TYPE(atom_basis_type), INTENT(INOUT)               :: basis
      INTEGER, INTENT(IN)                                :: derivatives

      INTEGER                                            :: i, j, l, n

      SELECT CASE (derivatives)
      CASE (0)
         DO l = 0, lmat
            n = basis%nbas(l)
            DO i = 1, n
               DO j = i, n
                  imat(i, j, l) = imat(i, j, l) + &
                                  integrate_grid(cpot, basis%bf(:, i, l), basis%bf(:, j, l), basis%grid)
                  imat(j, i, l) = imat(i, j, l)
               END DO
            END DO
         END DO
      CASE (1)
         DO l = 0, lmat
            n = basis%nbas(l)
            DO i = 1, n
               DO j = i, n
                  imat(i, j, l) = imat(i, j, l) + &
                                  integrate_grid(cpot, basis%dbf(:, i, l), basis%bf(:, j, l), basis%grid)
                  imat(i, j, l) = imat(i, j, l) + &
                                  integrate_grid(cpot, basis%bf(:, i, l), basis%dbf(:, j, l), basis%grid)
                  imat(j, i, l) = imat(i, j, l)
               END DO
            END DO
         END DO
      CASE (2)
         DO l = 0, lmat
            n = basis%nbas(l)
            DO i = 1, n
               DO j = i, n
                  imat(i, j, l) = imat(i, j, l) + &
                                  integrate_grid(cpot, basis%dbf(:, i, l), basis%dbf(:, j, l), basis%grid)
                  imat(j, i, l) = imat(i, j, l)
               END DO
            END DO
         END DO
      CASE DEFAULT
         CPABORT("")
      END SELECT

   END SUBROUTINE numpot_matrix

! **************************************************************************************************
!> \brief Contract Coulomb Electron Repulsion Integrals.
!> \param jmat ...
!> \param erint ...
!> \param pmat ...
!> \param nsize ...
!> \param all_nu ...
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   PURE SUBROUTINE ceri_contract(jmat, erint, pmat, nsize, all_nu)
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(INOUT)  :: jmat
      TYPE(eri), DIMENSION(:), INTENT(IN)                :: erint
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(IN)     :: pmat
      INTEGER, DIMENSION(0:), INTENT(IN)                 :: nsize
      LOGICAL, INTENT(IN), OPTIONAL                      :: all_nu

      INTEGER                                            :: i1, i2, ij1, ij2, j1, j2, l1, l2, ll, &
                                                            n1, n2
      LOGICAL                                            :: have_all_nu
      REAL(KIND=dp)                                      :: eint, f1, f2

      IF (PRESENT(all_nu)) THEN
         have_all_nu = all_nu
      ELSE
         have_all_nu = .FALSE.
      END IF

      jmat(:, :, :) = 0._dp
      ll = 0
      DO l1 = 0, lmat
         n1 = nsize(l1)
         DO l2 = 0, l1
            n2 = nsize(l2)
            ll = ll + 1
            ij1 = 0
            DO i1 = 1, n1
               DO j1 = i1, n1
                  ij1 = ij1 + 1
                  f1 = 1._dp
                  IF (i1 /= j1) f1 = 2._dp
                  ij2 = 0
                  DO i2 = 1, n2
                     DO j2 = i2, n2
                        ij2 = ij2 + 1
                        f2 = 1._dp
                        IF (i2 /= j2) f2 = 2._dp
                        eint = erint(ll)%int(ij1, ij2)
                        IF (l1 == l2) THEN
                           jmat(i1, j1, l1) = jmat(i1, j1, l1) + f2*pmat(i2, j2, l2)*eint
                        ELSE
                           jmat(i1, j1, l1) = jmat(i1, j1, l1) + f2*pmat(i2, j2, l2)*eint
                           jmat(i2, j2, l2) = jmat(i2, j2, l2) + f1*pmat(i1, j1, l1)*eint
                        END IF
                     END DO
                  END DO
               END DO
            END DO
            IF (have_all_nu) THEN
               ! skip integral blocks with nu/=0
               ll = ll + l2
            END IF
         END DO
      END DO
      DO l1 = 0, lmat
         n1 = nsize(l1)
         DO i1 = 1, n1
            DO j1 = i1, n1
               jmat(j1, i1, l1) = jmat(i1, j1, l1)
            END DO
         END DO
      END DO

   END SUBROUTINE ceri_contract

! **************************************************************************************************
!> \brief Contract exchange Electron Repulsion Integrals.
!> \param kmat ...
!> \param erint ...
!> \param pmat ...
!> \param nsize ...
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   PURE SUBROUTINE eeri_contract(kmat, erint, pmat, nsize)
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(INOUT)  :: kmat
      TYPE(eri), DIMENSION(:), INTENT(IN)                :: erint
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(IN)     :: pmat
      INTEGER, DIMENSION(0:), INTENT(IN)                 :: nsize

      INTEGER                                            :: i1, i2, ij1, ij2, j1, j2, l1, l2, lh, &
                                                            ll, n1, n2, nu
      REAL(KIND=dp)                                      :: almn, eint, f1, f2
      REAL(KIND=dp), DIMENSION(0:maxfac)                 :: arho

      arho = 0._dp
      DO ll = 0, maxfac, 2
         lh = ll/2
         arho(ll) = fac(ll)/fac(lh)**2
      END DO

      kmat(:, :, :) = 0._dp
      ll = 0
      DO l1 = 0, lmat
         n1 = nsize(l1)
         DO l2 = 0, l1
            n2 = nsize(l2)
            DO nu = ABS(l1 - l2), l1 + l2, 2
               almn = arho(-l1 + l2 + nu)*arho(l1 - l2 + nu)*arho(l1 + l2 - nu)/(REAL(l1 + l2 + nu + 1, dp)*arho(l1 + l2 + nu))
               almn = -0.5_dp*almn
               ll = ll + 1
               ij1 = 0
               DO i1 = 1, n1
                  DO j1 = i1, n1
                     ij1 = ij1 + 1
                     f1 = 1._dp
                     IF (i1 /= j1) f1 = 2._dp
                     ij2 = 0
                     DO i2 = 1, n2
                        DO j2 = i2, n2
                           ij2 = ij2 + 1
                           f2 = 1._dp
                           IF (i2 /= j2) f2 = 2._dp
                           eint = erint(ll)%int(ij1, ij2)
                           IF (l1 == l2) THEN
                              kmat(i1, j1, l1) = kmat(i1, j1, l1) + f2*almn*pmat(i2, j2, l2)*eint
                           ELSE
                              kmat(i1, j1, l1) = kmat(i1, j1, l1) + f2*almn*pmat(i2, j2, l2)*eint
                              kmat(i2, j2, l2) = kmat(i2, j2, l2) + f1*almn*pmat(i1, j1, l1)*eint
                           END IF
                        END DO
                     END DO
                  END DO
               END DO
            END DO
         END DO
      END DO
      DO l1 = 0, lmat
         n1 = nsize(l1)
         DO i1 = 1, n1
            DO j1 = i1, n1
               kmat(j1, i1, l1) = kmat(i1, j1, l1)
            END DO
         END DO
      END DO

   END SUBROUTINE eeri_contract

! **************************************************************************************************
!> \brief Calculate the error matrix for each angular momentum.
!> \param emat   error matrix
!> \param demax  the largest absolute value of error matrix elements
!> \param kmat   Kohn-Sham matrix
!> \param pmat   electron density matrix
!> \param umat   transformation matrix which reduce overlap matrix to its unitary form
!> \param upmat  transformation matrix which reduce density matrix to its unitary form
!> \param nval   number of linear-independent contracted basis functions
!> \param nbs    number of contracted basis functions
!> \par History
!>    * 08.2008 created [Juerg Hutter]
! **************************************************************************************************
   PURE SUBROUTINE err_matrix(emat, demax, kmat, pmat, umat, upmat, nval, nbs)
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(OUT)    :: emat
      REAL(KIND=dp), INTENT(OUT)                         :: demax
      REAL(KIND=dp), DIMENSION(:, :, 0:), INTENT(IN)     :: kmat, pmat, umat, upmat
      INTEGER, DIMENSION(0:), INTENT(IN)                 :: nval, nbs

      INTEGER                                            :: l, m, n
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :)        :: tkmat, tpmat

      emat = 0._dp
      DO l = 0, lmat
         n = nval(l)
         m = nbs(l)
         IF (m > 0) THEN
            ALLOCATE (tkmat(1:m, 1:m), tpmat(1:m, 1:m))
            tkmat = 0._dp
            tpmat = 0._dp
            tkmat(1:m, 1:m) = MATMUL(TRANSPOSE(umat(1:n, 1:m, l)), MATMUL(kmat(1:n, 1:n, l), umat(1:n, 1:m, l)))
            tpmat(1:m, 1:m) = MATMUL(TRANSPOSE(umat(1:n, 1:m, l)), MATMUL(pmat(1:n, 1:n, l), umat(1:n, 1:m, l)))
            tpmat(1:m, 1:m) = MATMUL(upmat(1:m, 1:m, l), MATMUL(tpmat(1:m, 1:m), upmat(1:m, 1:m, l)))

            emat(1:m, 1:m, l) = MATMUL(tkmat(1:m, 1:m), tpmat(1:m, 1:m)) - MATMUL(tpmat(1:m, 1:m), tkmat(1:m, 1:m))

            DEALLOCATE (tkmat, tpmat)
         END IF
      END DO
      demax = MAXVAL(ABS(emat))

   END SUBROUTINE err_matrix

! **************************************************************************************************
!> \brief Calculate Slater density on a radial grid.
!> \param density1  alpha-spin electron density
!> \param density2  beta-spin electron density
!> \param zcore     nuclear charge
!> \param state     electronic state
!> \param grid      atomic radial grid
!> \par History
!>    * 06.2018 bugfix [Rustam Khaliullin]
!>    * 02.2010 unrestricted KS and HF methods [Juerg Hutter]
!>    * 12.2008 created [Juerg Hutter]
!> \note  An initial electron density to guess atomic orbitals.
! **************************************************************************************************
   SUBROUTINE slater_density(density1, density2, zcore, state, grid)
      REAL(KIND=dp), DIMENSION(:), INTENT(OUT)           :: density1, density2
      INTEGER, INTENT(IN)                                :: zcore
      TYPE(atom_state), INTENT(IN)                       :: state
      TYPE(grid_atom_type), INTENT(IN)                   :: grid

      INTEGER                                            :: counter, i, l, mc, mm(0:lmat), mo, n, ns
      INTEGER, DIMENSION(lmat+1, 20)                     :: ne
      REAL(KIND=dp)                                      :: a, pf

      ! fill out a table with the total number of electrons
      ! core + valence. format ne(l,n)
      ns = SIZE(ne, 2)
      ne = 0
      mm = get_maxn_occ(state%core)
      DO l = 0, lmat
         mo = state%maxn_occ(l)
         IF (SUM(state%core(l, :)) == 0) THEN
            CPASSERT(ns >= l + mo)
            DO counter = 1, mo
               ne(l + 1, l + counter) = NINT(state%occ(l, counter))
            END DO
         ELSE
            mc = mm(l) ! number of levels in the core
            CPASSERT(SUM(state%occ(l, 1:mc)) == 0)
            CPASSERT(ns >= l + mc)
            DO counter = 1, mc
               ne(l + 1, l + counter) = NINT(state%core(l, counter))
            END DO
            CPASSERT(ns >= l + mc + mo)
            DO counter = mc + 1, mc + mo
               ne(l + 1, l + counter) = NINT(state%occ(l, counter))
            END DO
         END IF
      END DO

      density1 = 0._dp
      density2 = 0._dp
      DO l = 0, state%maxl_occ
         DO i = 1, SIZE(state%occ, 2)
            IF (state%occ(l, i) > 0._dp) THEN
               n = i + l
               a = srules(zcore, ne, n, l)
               pf = 1._dp/SQRT(fac(2*n))*(2._dp*a)**(n + 0.5_dp)
               IF (state%multiplicity == -1) THEN
                  density1(:) = density1(:) + state%occ(l, i)/fourpi*(grid%rad(:)**(n - 1)*EXP(-a*grid%rad(:))*pf)**2
               ELSE
                  density1(:) = density1(:) + state%occa(l, i)/fourpi*(grid%rad(:)**(n - 1)*EXP(-a*grid%rad(:))*pf)**2
                  density2(:) = density2(:) + state%occb(l, i)/fourpi*(grid%rad(:)**(n - 1)*EXP(-a*grid%rad(:))*pf)**2
               END IF
            END IF
         END DO
      END DO

   END SUBROUTINE slater_density

! **************************************************************************************************
!> \brief Calculate the functional derivative of the Wigner (correlation) - Slater (exchange)
!>        density functional.
!> \param rho  electron density on a radial grid
!> \param vxc  (output) exchange-correlation potential
!> \par History
!>    * 12.2008 created [Juerg Hutter]
!> \note  A model XC-potential to guess atomic orbitals.
! **************************************************************************************************
   PURE SUBROUTINE wigner_slater_functional(rho, vxc)
      REAL(KIND=dp), DIMENSION(:), INTENT(IN)            :: rho
      REAL(KIND=dp), DIMENSION(:), INTENT(OUT)           :: vxc

      INTEGER                                            :: i
      REAL(KIND=dp)                                      :: ec, ex, rs, vc, vx

      vxc = 0._dp
      DO i = 1, SIZE(rho)
         IF (rho(i) > 1.e-20_dp) THEN
            ! 3/4 * (3/pi)^{1/3} == 0.7385588
            ex = -0.7385588_dp*rho(i)**0.333333333_dp
            vx = 1.333333333_dp*ex
            rs = (3._dp/fourpi/rho(i))**0.333333333_dp
            ec = -0.88_dp/(rs + 7.8_dp)
            vc = ec*(1._dp + rs/(3._dp*(rs + 7.8_dp)))
            vxc(i) = vx + vc
         END IF
      END DO

   END SUBROUTINE wigner_slater_functional

! **************************************************************************************************
!> \brief Check that the atomic multiplicity is consistent with the electronic structure method.
!> \param method        electronic structure method
!> \param multiplicity  multiplicity
!> \return              consistency status
!> \par History
!>    * 11.2009 unrestricted KS and HF methods [Juerg Hutter]
! **************************************************************************************************
   PURE FUNCTION atom_consistent_method(method, multiplicity) RESULT(consistent)
      INTEGER, INTENT(IN)                                :: method, multiplicity
      LOGICAL                                            :: consistent

      ! multiplicity == -1 means it has not been specified explicitly;
      ! see the source code of the subroutine atom_set_occupation() for further details.
      SELECT CASE (method)
      CASE DEFAULT
         consistent = .FALSE.
      CASE (do_rks_atom)
         consistent = (multiplicity == -1)
      CASE (do_uks_atom)
         consistent = (multiplicity /= -1)
      CASE (do_rhf_atom)
         consistent = (multiplicity == -1)
      CASE (do_uhf_atom)
         consistent = (multiplicity /= -1)
      CASE (do_rohf_atom)
         consistent = .FALSE.
      END SELECT

   END FUNCTION atom_consistent_method

! **************************************************************************************************
!> \brief Calculate the total electron density at R=0.
!> \param atom  information about the atomic kind
!> \param rho0  (output) computed density
!> \par History
!>    * 05.2016 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE get_rho0(atom, rho0)
      TYPE(atom_type), INTENT(IN)                        :: atom
      REAL(KIND=dp), INTENT(OUT)                         :: rho0

      INTEGER                                            :: m0, m1, m2, method, nr
      LOGICAL                                            :: nlcc, spinpol
      REAL(KIND=dp)                                      :: d0, d1, d2, r0, r1, r2, w0, w1
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: xfun
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :)        :: rho

      method = atom%method_type
      SELECT CASE (method)
      CASE (do_rks_atom, do_rhf_atom)
         spinpol = .FALSE.
      CASE (do_uks_atom, do_uhf_atom)
         spinpol = .TRUE.
      CASE (do_rohf_atom)
         CPABORT("")
      CASE DEFAULT
         CPABORT("")
      END SELECT

      nr = atom%basis%grid%nr
      nlcc = .FALSE.
      IF (atom%potential%ppot_type == gth_pseudo) THEN
         nlcc = atom%potential%gth_pot%nlcc
      ELSE IF (atom%potential%ppot_type == upf_pseudo) THEN
         nlcc = atom%potential%upf_pot%core_correction
      ELSE IF (atom%potential%ppot_type == sgp_pseudo) THEN
         nlcc = atom%potential%sgp_pot%has_nlcc
      END IF
      IF (nlcc) THEN
         ALLOCATE (xfun(nr))
      END IF

      m0 = MAXVAL(MINLOC(atom%basis%grid%rad))
      IF (m0 == nr) THEN
         m1 = m0 - 1
         m2 = m0 - 2
      ELSE IF (m0 == 1) THEN
         m1 = 2
         m2 = 3
      ELSE
         CPABORT("GRID Definition incompatible")
      END IF
      r0 = atom%basis%grid%rad(m0)
      r1 = atom%basis%grid%rad(m1)
      r2 = atom%basis%grid%rad(m2)
      w0 = r1/(r1 - r0)
      w1 = 1 - w0

      IF (spinpol) THEN
         ALLOCATE (rho(nr, 2))
         CALL atom_density(rho(:, 1), atom%orbitals%pmata, atom%basis, atom%state%maxl_occ, typ="RHO")
         CALL atom_density(rho(:, 2), atom%orbitals%pmatb, atom%basis, atom%state%maxl_occ, typ="RHO")
         IF (nlcc) THEN
            xfun = 0.0_dp
            CALL atom_core_density(xfun(:), atom%potential, typ="RHO", rr=atom%basis%grid%rad)
            rho(:, 1) = rho(:, 1) + 0.5_dp*xfun(:)
            rho(:, 2) = rho(:, 2) + 0.5_dp*xfun(:)
         END IF
         rho(:, 1) = rho(:, 1) + rho(:, 2)
      ELSE
         ALLOCATE (rho(nr, 1))
         CALL atom_density(rho(:, 1), atom%orbitals%pmat, atom%basis, atom%state%maxl_occ, typ="RHO")
         IF (nlcc) THEN
            CALL atom_core_density(rho(:, 1), atom%potential, typ="RHO", rr=atom%basis%grid%rad)
         END IF
      END IF
      d0 = rho(m0, 1)
      d1 = rho(m1, 1)
      d2 = rho(m2, 1)

      rho0 = w0*d0 + w1*d1
      rho0 = MAX(rho0, 0.0_dp)

      DEALLOCATE (rho)
      IF (nlcc) THEN
         DEALLOCATE (xfun)
      END IF

   END SUBROUTINE get_rho0

! **************************************************************************************************
!> \brief Print condition numbers of the given atomic basis set.
!> \param basis  atomic basis set
!> \param crad   atomic covalent radius
!> \param iw     output file unit
!> \par History
!>    * 05.2016 created [Juerg Hutter]
! **************************************************************************************************
   SUBROUTINE atom_condnumber(basis, crad, iw)
      TYPE(atom_basis_type), POINTER                     :: basis
      REAL(KIND=dp)                                      :: crad
      INTEGER, INTENT(IN)                                :: iw

      INTEGER                                            :: i
      REAL(KIND=dp)                                      :: ci
      REAL(KIND=dp), DIMENSION(10)                       :: cnum, rad

      WRITE (iw, '(/,A,F8.4)') " Basis Set Condition Numbers: 2*covalent radius=", 2*crad
      CALL init_orbital_pointers(lmat)
      CALL init_spherical_harmonics(lmat, 0)
      cnum = 0.0_dp
      DO i = 1, 9
         ci = 2.0_dp*(0.85_dp + i*0.05_dp)
         rad(i) = crad*ci
         CALL atom_basis_condnum(basis, rad(i), cnum(i))
         WRITE (iw, '(A,F15.3,T50,A,F14.4)') " Lattice constant:", &
            rad(i), "Condition number:", cnum(i)
      END DO
      rad(10) = 0.01_dp
      CALL atom_basis_condnum(basis, rad(10), cnum(10))
      WRITE (iw, '(A,A,T50,A,F14.4)') " Lattice constant:", &
         "            Inf", "Condition number:", cnum(i)
      CALL deallocate_orbital_pointers
      CALL deallocate_spherical_harmonics

   END SUBROUTINE atom_condnumber

! **************************************************************************************************
!> \brief Estimate completeness of the given atomic basis set.
!> \param basis  atomic basis set
!> \param zv     atomic number
!> \param iw     output file unit
! **************************************************************************************************
   SUBROUTINE atom_completeness(basis, zv, iw)
      TYPE(atom_basis_type), POINTER                     :: basis
      INTEGER, INTENT(IN)                                :: zv, iw

      INTEGER                                            :: i, j, l, ll, m, n, nbas, nl, nr
      INTEGER, DIMENSION(0:lmat)                         :: nelem, nlmax, nlmin
      INTEGER, DIMENSION(lmat+1, 7)                      :: ne
      REAL(KIND=dp)                                      :: al, c1, c2, pf
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: sfun
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :)        :: bmat
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :, :)     :: omat
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :, :, :)  :: sint
      REAL(KIND=dp), DIMENSION(0:lmat, 10)               :: snl
      REAL(KIND=dp), DIMENSION(2)                        :: sse
      REAL(KIND=dp), DIMENSION(lmat+1, 7)                :: sexp

      ne = 0
      nelem = 0
      nelem(0:3) = ptable(zv)%e_conv(0:3)
      DO l = 0, lmat
         ll = 2*(2*l + 1)
         DO i = 1, 7
            IF (nelem(l) >= ll) THEN
               ne(l + 1, i) = ll
               nelem(l) = nelem(l) - ll
            ELSE IF (nelem(l) > 0) THEN
               ne(l + 1, i) = nelem(l)
               nelem(l) = 0
            ELSE
               EXIT
            END IF
         END DO
      END DO

      nlmin = 1
      nlmax = 1
      DO l = 0, lmat
         nlmin(l) = l + 1
         DO i = 1, 7
            IF (ne(l + 1, i) > 0) THEN
               nlmax(l) = i + l
            END IF
         END DO
         nlmax(l) = MAX(nlmax(l), nlmin(l) + 1)
      END DO

      ! Slater exponents
      sexp = 0.0_dp
      DO l = 0, lmat
         sse(1) = 0.05_dp
         sse(2) = 10.0_dp
         DO i = l + 1, 7
            sexp(l + 1, i) = srules(zv, ne, i, l)
            IF (ne(l + 1, i - l) > 0) THEN
               sse(1) = MAX(sse(1), sexp(l + 1, i))
               sse(2) = MIN(sse(2), sexp(l + 1, i))
            END IF
         END DO
         DO i = 1, 10
            snl(l, i) = ABS(2._dp*sse(1) - 0.5_dp*sse(2))/9._dp*REAL(i - 1, KIND=dp) + 0.5_dp*MIN(sse(1), sse(2))
         END DO
      END DO

      nbas = MAXVAL(basis%nbas)
      ALLOCATE (omat(nbas, nbas, 0:lmat))
      nr = SIZE(basis%bf, 1)
      ALLOCATE (sfun(nr), sint(10, 2, nbas, 0:lmat))
      sint = 0._dp

      ! calculate overlaps between test functions and basis
      DO l = 0, lmat
         DO i = 1, 10
            al = snl(l, i)
            nl = nlmin(l)
            pf = (2._dp*al)**nl*SQRT(2._dp*al/fac(2*nl))
            sfun(1:nr) = pf*basis%grid%rad(1:nr)**(nl - 1)*EXP(-al*basis%grid%rad(1:nr))
            DO j = 1, basis%nbas(l)
               sint(i, 1, j, l) = SUM(sfun(1:nr)*basis%bf(1:nr, j, l)*basis%grid%wr(1:nr))
            END DO
            nl = nlmax(l)
            pf = (2._dp*al)**nl*SQRT(2._dp*al/fac(2*nl))
            sfun(1:nr) = pf*basis%grid%rad(1:nr)**(nl - 1)*EXP(-al*basis%grid%rad(1:nr))
            DO j = 1, basis%nbas(l)
               sint(i, 2, j, l) = SUM(sfun(1:nr)*basis%bf(1:nr, j, l)*basis%grid%wr(1:nr))
            END DO
         END DO
      END DO

      DO l = 0, lmat
         n = basis%nbas(l)
         IF (n <= 0) CYCLE
         m = basis%nprim(l)
         SELECT CASE (basis%basis_type)
         CASE DEFAULT
            CPABORT("")
         CASE (GTO_BASIS)
            CALL sg_overlap(omat(1:n, 1:n, l), l, basis%am(1:n, l), basis%am(1:n, l))
         CASE (CGTO_BASIS)
            ALLOCATE (bmat(m, m))
            CALL sg_overlap(bmat(1:m, 1:m), l, basis%am(1:m, l), basis%am(1:m, l))
            CALL contract2(omat(1:n, 1:n, l), bmat(1:m, 1:m), basis%cm(1:m, 1:n, l))
            DEALLOCATE (bmat)
         CASE (STO_BASIS)
            CALL sto_overlap(omat(1:n, 1:n, l), basis%ns(1:n, l), basis%as(1:n, l), &
                             basis%ns(1:n, l), basis%as(1:n, l))
         CASE (NUM_BASIS)
            CPABORT("")
         END SELECT
         CALL invmat_symm(omat(1:n, 1:n, l))
      END DO

      WRITE (iw, '(/,A)') " Basis Set Completeness Estimates"
      DO l = 0, lmat
         n = basis%nbas(l)
         IF (n <= 0) CYCLE
         WRITE (iw, '(A,I3)') "   L-quantum number: ", l
         WRITE (iw, '(A,T31,A,I2,T61,A,I2)') "    Slater Exponent", "Completeness n-qm=", nlmin(l), &
            "Completeness n-qm=", nlmax(l)
         DO i = 10, 1, -1
            c1 = DOT_PRODUCT(sint(i, 1, 1:n, l), MATMUL(omat(1:n, 1:n, l), sint(i, 1, 1:n, l)))
            c2 = DOT_PRODUCT(sint(i, 2, 1:n, l), MATMUL(omat(1:n, 1:n, l), sint(i, 2, 1:n, l)))
            WRITE (iw, "(T6,F14.6,T41,F10.6,T71,F10.6)") snl(l, i), c1, c2
         END DO
      END DO

      DEALLOCATE (omat, sfun, sint)

   END SUBROUTINE atom_completeness

! **************************************************************************************************
!> \brief Calculate the condition number of the given atomic basis set.
!> \param basis  atomic basis set
!> \param rad    lattice constant (e.g. doubled atomic covalent radius)
!> \param cnum   (output) condition number
! **************************************************************************************************
   SUBROUTINE atom_basis_condnum(basis, rad, cnum)
      TYPE(atom_basis_type)                              :: basis
      REAL(KIND=dp), INTENT(IN)                          :: rad
      REAL(KIND=dp), INTENT(OUT)                         :: cnum

      INTEGER                                            :: ia, ib, imax, info, ix, iy, iz, ja, jb, &
                                                            ka, kb, l, la, lb, lwork, na, nb, &
                                                            nbas, nna, nnb
      INTEGER, ALLOCATABLE, DIMENSION(:, :)              :: ibptr
      REAL(KIND=dp)                                      :: r1, r2, reps, rmax
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:)           :: weig, work
      REAL(KIND=dp), ALLOCATABLE, DIMENSION(:, :)        :: smat
      REAL(KIND=dp), DIMENSION(2*lmat+1, 2*lmat+1)       :: sab
      REAL(KIND=dp), DIMENSION(3)                        :: rab
      REAL(KIND=dp), DIMENSION(:), POINTER               :: zeta, zetb

      ! Number of spherical Gaussian orbitals with angular momentum lmat: nso(lmat) = 2*lmat+1

      ! total number of basis functions
      nbas = 0
      DO l = 0, lmat
         nbas = nbas + basis%nbas(l)*(2*l + 1)
      END DO

      ALLOCATE (smat(nbas, nbas), ibptr(nbas, 0:lmat))
      smat = 0.0_dp
      ibptr = 0
      na = 0
      DO l = 0, lmat
         DO ia = 1, basis%nbas(l)
            ibptr(ia, l) = na + 1
            na = na + (2*l + 1)
         END DO
      END DO

      reps = 1.e-14_dp
      IF (basis%basis_type == GTO_BASIS .OR. &
          basis%basis_type == CGTO_BASIS) THEN
         DO la = 0, lmat
            na = basis%nprim(la)
            nna = 2*la + 1
            IF (na == 0) CYCLE
            zeta => basis%am(:, la)
            DO lb = 0, lmat
               nb = basis%nprim(lb)
               nnb = 2*lb + 1
               IF (nb == 0) CYCLE
               zetb => basis%am(:, lb)
               DO ia = 1, na
                  DO ib = 1, nb
                     IF (rad < 0.1_dp) THEN
                        imax = 0
                     ELSE
                        r1 = exp_radius(la, zeta(ia), reps, 1.0_dp)
                        r2 = exp_radius(lb, zetb(ib), reps, 1.0_dp)
                        rmax = MAX(2._dp*r1, 2._dp*r2)
                        imax = INT(rmax/rad) + 1
                     END IF
                     IF (imax > 1) THEN
                        CALL overlap_ab_sp(la, zeta(ia), lb, zetb(ib), rad, sab)
                        IF (basis%basis_type == GTO_BASIS) THEN
                           ja = ibptr(ia, la)
                           jb = ibptr(ib, lb)
                           smat(ja:ja + nna - 1, jb:jb + nnb - 1) = smat(ja:ja + nna - 1, jb:jb + nnb - 1) + sab(1:nna, 1:nnb)
                        ELSEIF (basis%basis_type == CGTO_BASIS) THEN
                           DO ka = 1, basis%nbas(la)
                              DO kb = 1, basis%nbas(lb)
                                 ja = ibptr(ka, la)
                                 jb = ibptr(kb, lb)
                                 smat(ja:ja + nna - 1, jb:jb + nnb - 1) = smat(ja:ja + nna - 1, jb:jb + nnb - 1) + &
                                                                         sab(1:nna, 1:nnb)*basis%cm(ia, ka, la)*basis%cm(ib, kb, lb)
                              END DO
                           END DO
                        END IF
                     ELSE
                        DO ix = -imax, imax
                           rab(1) = rad*ix
                           DO iy = -imax, imax
                              rab(2) = rad*iy
                              DO iz = -imax, imax
                                 rab(3) = rad*iz
                                 CALL overlap_ab_s(la, zeta(ia), lb, zetb(ib), rab, sab)
                                 IF (basis%basis_type == GTO_BASIS) THEN
                                    ja = ibptr(ia, la)
                                    jb = ibptr(ib, lb)
                                    smat(ja:ja + nna - 1, jb:jb + nnb - 1) = smat(ja:ja + nna - 1, jb:jb + nnb - 1) &
                                                                             + sab(1:nna, 1:nnb)
                                 ELSEIF (basis%basis_type == CGTO_BASIS) THEN
                                    DO ka = 1, basis%nbas(la)
                                       DO kb = 1, basis%nbas(lb)
                                          ja = ibptr(ka, la)
                                          jb = ibptr(kb, lb)
                                          smat(ja:ja + nna - 1, jb:jb + nnb - 1) = &
                                             smat(ja:ja + nna - 1, jb:jb + nnb - 1) + &
                                             sab(1:nna, 1:nnb)*basis%cm(ia, ka, la)*basis%cm(ib, kb, lb)
                                       END DO
                                    END DO
                                 END IF
                              END DO
                           END DO
                        END DO
                     END IF
                  END DO
               END DO
            END DO
         END DO
      ELSE
         CPABORT("Condition number not available for this basis type")
      END IF

      info = 0
      lwork = MAX(nbas*nbas, nbas + 100)
      ALLOCATE (weig(nbas), work(lwork))

      CALL lapack_ssyev("N", "U", nbas, smat, nbas, weig, work, lwork, info)
      CPASSERT(info == 0)
      IF (weig(1) < 0.0_dp) THEN
         cnum = 100._dp
      ELSE
         cnum = ABS(weig(nbas)/weig(1))
         cnum = LOG10(cnum)
      END IF

      DEALLOCATE (smat, ibptr, weig, work)

   END SUBROUTINE atom_basis_condnum

! **************************************************************************************************
!> \brief Transform a matrix expressed in terms of a uncontracted basis set to a contracted one.
!> \param int   (output) contracted matrix
!> \param omat  uncontracted matrix
!> \param cm    matrix of contraction coefficients
! **************************************************************************************************
   SUBROUTINE contract2(int, omat, cm)
      REAL(dp), DIMENSION(:, :), INTENT(INOUT)           :: int
      REAL(dp), DIMENSION(:, :), INTENT(IN)              :: omat, cm

      CHARACTER(len=*), PARAMETER                        :: routineN = 'contract2'

      INTEGER                                            :: handle, m, n

      CALL timeset(routineN, handle)

      n = SIZE(int, 1)
      m = SIZE(omat, 1)

      INT(1:n, 1:n) = MATMUL(TRANSPOSE(cm(1:m, 1:n)), MATMUL(omat(1:m, 1:m), cm(1:m, 1:n)))

      CALL timestop(handle)

   END SUBROUTINE contract2

! **************************************************************************************************
!> \brief Same as contract2(), but add the new contracted matrix to the old one
!>        instead of overwriting it.
!> \param int   (input/output) contracted matrix to be updated
!> \param omat  uncontracted matrix
!> \param cm    matrix of contraction coefficients
! **************************************************************************************************
   SUBROUTINE contract2add(int, omat, cm)
      REAL(dp), DIMENSION(:, :), INTENT(INOUT)           :: int
      REAL(dp), DIMENSION(:, :), INTENT(IN)              :: omat, cm

      CHARACTER(len=*), PARAMETER                        :: routineN = 'contract2add'

      INTEGER                                            :: handle, m, n

      CALL timeset(routineN, handle)

      n = SIZE(int, 1)
      m = SIZE(omat, 1)

      INT(1:n, 1:n) = INT(1:n, 1:n) + MATMUL(TRANSPOSE(cm(1:m, 1:n)), MATMUL(omat(1:m, 1:m), cm(1:m, 1:n)))

      CALL timestop(handle)

   END SUBROUTINE contract2add

! **************************************************************************************************
!> \brief Contract a matrix of Electron Repulsion Integrals (ERI-s).
!> \param eri   (output) contracted ERI-s
!> \param omat  uncontracted ERI-s
!> \param cm1   first matrix of contraction coefficients
!> \param cm2   second matrix of contraction coefficients
! **************************************************************************************************
   SUBROUTINE contract4(eri, omat, cm1, cm2)
      REAL(dp), DIMENSION(:, :), INTENT(INOUT)           :: eri
      REAL(dp), DIMENSION(:, :), INTENT(IN)              :: omat, cm1, cm2

      CHARACTER(len=*), PARAMETER                        :: routineN = 'contract4'

      INTEGER                                            :: handle, i1, i2, m1, m2, mm1, mm2, n1, &
                                                            n2, nn1, nn2
      REAL(dp), ALLOCATABLE, DIMENSION(:, :)             :: amat, atran, bmat, btran, hint

      CALL timeset(routineN, handle)

      m1 = SIZE(cm1, 1)
      n1 = SIZE(cm1, 2)
      m2 = SIZE(cm2, 1)
      n2 = SIZE(cm2, 2)
      nn1 = SIZE(eri, 1)
      nn2 = SIZE(eri, 2)
      mm1 = SIZE(omat, 1)
      mm2 = SIZE(omat, 2)

      ALLOCATE (amat(m1, m1), atran(n1, n1), bmat(m2, m2), btran(n2, n2))
      ALLOCATE (hint(mm1, nn2))

      DO i1 = 1, mm1
         CALL iunpack(bmat(1:m2, 1:m2), omat(i1, 1:mm2), m2)
         CALL contract2(btran(1:n2, 1:n2), bmat(1:m2, 1:m2), cm2(1:m2, 1:n2))
         CALL ipack(btran(1:n2, 1:n2), hint(i1, 1:nn2), n2)
      END DO

      DO i2 = 1, nn2
         CALL iunpack(amat(1:m1, 1:m1), hint(1:mm1, i2), m1)
         CALL contract2(atran(1:n1, 1:n1), amat(1:m1, 1:m1), cm1(1:m1, 1:n1))
         CALL ipack(atran(1:n1, 1:n1), eri(1:nn1, i2), n1)
      END DO

      DEALLOCATE (amat, atran, bmat, btran)
      DEALLOCATE (hint)

      CALL timestop(handle)

   END SUBROUTINE contract4

! **************************************************************************************************
!> \brief Pack an n x n square real matrix into a 1-D vector.
!> \param mat  matrix to pack
!> \param vec  resulting vector
!> \param n    size of the matrix
! **************************************************************************************************
   PURE SUBROUTINE ipack(mat, vec, n)
      REAL(dp), DIMENSION(:, :), INTENT(IN)              :: mat
      REAL(dp), DIMENSION(:), INTENT(INOUT)              :: vec
      INTEGER, INTENT(IN)                                :: n

      INTEGER                                            :: i, ij, j

      ij = 0
      DO i = 1, n
         DO j = i, n
            ij = ij + 1
            vec(ij) = mat(i, j)
         END DO
      END DO

   END SUBROUTINE ipack

! **************************************************************************************************
!> \brief Unpack a 1-D real vector as a n x n square matrix.
!> \param mat  resulting matrix
!> \param vec  vector to unpack
!> \param n    size of the matrix
! **************************************************************************************************
   PURE SUBROUTINE iunpack(mat, vec, n)
      REAL(dp), DIMENSION(:, :), INTENT(INOUT)           :: mat
      REAL(dp), DIMENSION(:), INTENT(IN)                 :: vec
      INTEGER, INTENT(IN)                                :: n

      INTEGER                                            :: i, ij, j

      ij = 0
      DO i = 1, n
         DO j = i, n
            ij = ij + 1
            mat(i, j) = vec(ij)
            mat(j, i) = vec(ij)
         END DO
      END DO

   END SUBROUTINE iunpack

END MODULE atom_utils