separate file for complex ao 2e ints

src/ao_two_e_ints/map_integrals.irp.f

@@ -46,30 +46,6 @@ subroutine two_e_integrals_index(i,j,k,l,i1)
   i1 = i1+shiftr(i2*i2-i2,1)
 end
 
-subroutine two_e_integrals_index_periodic(i,j,k,l,i1,p,q)
-  use map_module
-  implicit none
-  BEGIN_DOC
-! Gives a unique index for i,j,k,l using permtuation symmetry.
-! i <-> k, j <-> l, and (i,k) <-> (j,l) 
-  END_DOC
-  integer, intent(in)            :: i,j,k,l
-  integer(key_kind), intent(out) :: i1
-  integer(key_kind)              :: r,s,i2
-  integer(key_kind),intent(out)   :: p,q
-  p = min(i,k)
-  r = max(i,k)
-  p = p+shiftr(r*r-r,1)
-  q = min(j,l)
-  s = max(j,l)
-  q = q+shiftr(s*s-s,1)
-  i1 = min(p,q)
-  i2 = max(p,q)
-  i1 = i1+shiftr(i2*i2-i2,1)
-end
-
-
-
 subroutine two_e_integrals_index_reverse(i,j,k,l,i1)
   use map_module
   implicit none
@@ -159,120 +135,6 @@ subroutine two_e_integrals_index_reverse(i,j,k,l,i1)
 
 end
 
-subroutine two_e_integrals_index_reverse_complex_1(i,j,k,l,i1)
-  use map_module
-  implicit none
-  BEGIN_DOC
-! Computes the 4 indices $i,j,k,l$ from a unique index $i_1$.
-! For 2 indices $i,j$ and $i \le j$, we have
-! $p = i(i-1)/2 + j$.
-! The key point is that because $j < i$,
-! $i(i-1)/2 < p \le i(i+1)/2$. So $i$ can be found by solving
-! $i^2 - i - 2p=0$. One obtains $i=1 + \sqrt{1+8p}/2$
-! and $j = p - i(i-1)/2$.
-! This rule is applied 3 times. First for the symmetry of the
-! pairs (i,k) and (j,l), and then for the symmetry within each pair.
-! always returns first set such that i<=k, j<=l, ik<=jl
-  END_DOC
-  integer, intent(out)           :: i(4),j(4),k(4),l(4)
-  integer(key_kind), intent(in)  :: i1
-  integer(key_kind)              :: i2,i3
-  i = 0
-  i2   = ceiling(0.5d0*(dsqrt(dble(shiftl(i1,3)+1))-1.d0))
-  l(1) = ceiling(0.5d0*(dsqrt(dble(shiftl(i2,3)+1))-1.d0))
-  i3   = i1 - shiftr(i2*i2-i2,1)
-  k(1) = ceiling(0.5d0*(dsqrt(dble(shiftl(i3,3)+1))-1.d0))
-  j(1) = int(i2 - shiftr(l(1)*l(1)-l(1),1),4)
-  i(1) = int(i3 - shiftr(k(1)*k(1)-k(1),1),4)
-
-              !ijkl a+ib
-  i(2) = j(1) !jilk a+ib
-  j(2) = i(1)
-  k(2) = l(1)
-  l(2) = k(1)
-
-  i(3) = k(1) !klij a-ib
-  j(3) = l(1)
-  k(3) = i(1)
-  l(3) = j(1)
-
-  i(4) = l(1) !lkji a-ib
-  j(4) = k(1)
-  k(4) = j(1)
-  l(4) = i(1)
-
-  integer :: ii, jj
-  do ii=2,4
-    do jj=1,ii-1
-      if ( (i(ii) == i(jj)).and. &
-           (j(ii) == j(jj)).and. &
-           (k(ii) == k(jj)).and. &
-           (l(ii) == l(jj)) ) then
-         i(ii) = 0
-         exit
-      endif
-    enddo
-  enddo
-end
-
-subroutine two_e_integrals_index_reverse_complex_2(i,j,k,l,i1)
-  use map_module
-  implicit none
-  BEGIN_DOC
-! Computes the 4 indices $i,j,k,l$ from a unique index $i_1$.
-! For 2 indices $i,j$ and $i \le j$, we have
-! $p = i(i-1)/2 + j$.
-! The key point is that because $j < i$,
-! $i(i-1)/2 < p \le i(i+1)/2$. So $i$ can be found by solving
-! $i^2 - i - 2p=0$. One obtains $i=1 + \sqrt{1+8p}/2$
-! and $j = p - i(i-1)/2$.
-! This rule is applied 3 times. First for the symmetry of the
-! pairs (i,k) and (j,l), and then for the symmetry within each pair.
-! always returns first set such that k<=i, j<=l, ik<=jl
-  END_DOC
-  integer, intent(out)           :: i(4),j(4),k(4),l(4)
-  integer(key_kind), intent(in)  :: i1
-  integer(key_kind)              :: i2,i3
-  i = 0
-  i2   = ceiling(0.5d0*(dsqrt(dble(shiftl(i1,3)+1))-1.d0))
-  l(1) = ceiling(0.5d0*(dsqrt(dble(shiftl(i2,3)+1))-1.d0))
-  i3   = i1 - shiftr(i2*i2-i2,1)
-  i(1) = ceiling(0.5d0*(dsqrt(dble(shiftl(i3,3)+1))-1.d0))
-  j(1) = int(i2 - shiftr(l(1)*l(1)-l(1),1),4)
-  k(1) = int(i3 - shiftr(i(1)*i(1)-i(1),1),4)
-
-              !kjil a+ib
-  i(2) = j(1) !jkli a+ib
-  j(2) = i(1)
-  k(2) = l(1)
-  l(2) = k(1)
-
-  i(3) = k(1) !ilkj a-ib
-  j(3) = l(1)
-  k(3) = i(1)
-  l(3) = j(1)
-
-  i(4) = l(1) !lijk a-ib
-  j(4) = k(1)
-  k(4) = j(1)
-  l(4) = i(1)
-
-  integer :: ii, jj
-  do ii=2,4
-    do jj=1,ii-1
-      if ( (i(ii) == i(jj)).and. &
-           (j(ii) == j(jj)).and. &
-           (k(ii) == k(jj)).and. &
-           (l(ii) == l(jj)) ) then
-         i(ii) = 0
-         exit
-      endif
-    enddo
-  enddo
-end
-
-
-
  BEGIN_PROVIDER [ integer, ao_integrals_cache_min ]
 &BEGIN_PROVIDER [ integer, ao_integrals_cache_max ]
  implicit none
@@ -356,223 +218,6 @@ double precision function get_ao_two_e_integral(i,j,k,l,map) result(result)
   result = tmp
 end
 
-BEGIN_PROVIDER [ complex*16, ao_integrals_cache_periodic, (0:64*64*64*64) ]
- implicit none
- BEGIN_DOC
- ! Cache of AO integrals for fast access
- END_DOC
- PROVIDE ao_two_e_integrals_in_map
- integer                        :: i,j,k,l,ii
- integer(key_kind)              :: idx1, idx2
- real(integral_kind)            :: tmp_re, tmp_im
- integer(key_kind)              :: idx_re,idx_im
- complex(integral_kind)         :: integral
-  integer(key_kind)              :: p,q,r,s,ik,jl
-  logical :: ilek, jlel, iklejl
-  complex*16 :: get_ao_two_e_integral_periodic_simple
-
-
- !$OMP PARALLEL DO PRIVATE (ilek,jlel,p,q,r,s, ik,jl,iklejl, &
- !$OMP                     i,j,k,l,idx1,idx2,tmp_re,tmp_im,idx_re,idx_im,ii,integral)
- do l=ao_integrals_cache_min,ao_integrals_cache_max
-   do k=ao_integrals_cache_min,ao_integrals_cache_max
-     do j=ao_integrals_cache_min,ao_integrals_cache_max
-       do i=ao_integrals_cache_min,ao_integrals_cache_max
-         !DIR$ FORCEINLINE
-         integral = get_ao_two_e_integral_periodic_simple(i,j,k,l,&
-                    ao_integrals_map,ao_integrals_map_2)
-         
-         ii = l-ao_integrals_cache_min
-         ii = ior( shiftl(ii,6), k-ao_integrals_cache_min)
-         ii = ior( shiftl(ii,6), j-ao_integrals_cache_min)
-         ii = ior( shiftl(ii,6), i-ao_integrals_cache_min)
-         ao_integrals_cache_periodic(ii) = integral
-       enddo
-     enddo
-   enddo
- enddo
- !$OMP END PARALLEL DO
-
-END_PROVIDER
-
-subroutine ao_two_e_integral_periodic_map_idx_sign(i,j,k,l,use_map1,idx,sign) 
-  use map_module
-  implicit none
-  BEGIN_DOC
-  ! get position of periodic AO integral <ij|kl> 
-  ! use_map1: true if integral is in first ao map, false if integral is in second ao map
-  ! idx: position of real part of integral in map (imag part is at idx+1)
-  ! sign: sign of imaginary part
-  !
-  !
-  !  for <ab|cd>, conditionals are [a<c, b<d, ac<bd]
-  !  last two rows are real (ab==cd)
-  ! +---------+---------+---------+---------+---------+---------+---------+---------+---------+
-  ! | NEW     | <ij|kl> | <ji|lk> | <kl|ij> | <lk|ji> | <kj|il> | <jk|li> | <il|kj> | <li|jk> |
-  ! +---------+---------+---------+---------+---------+---------+---------+---------+---------+
-  ! |         |         m1        |         m1*       |         m2        |         m2*       |
-  ! +---------+---------+---------+---------+---------+---------+---------+---------+---------+
-  ! | <ij|kl> | TTT     | TTF     | FFT     | FFF     | FTT     | TFF     | TFT     | FTF     |
-  ! | <ij|il> | 0TT     | T0F     | 0FT     | F0F     |         |         |         |         |
-  ! | <ij|kj> | T0T     | 0TF     | F0T     | 0FF     |         |         |         |         |
-  ! | <ii|jj> | TT0     |         | FF0     |         | FT0(r)  | TF0(r)  |         |         |
-  ! +---------+---------+---------+---------+---------+---------+---------+---------+---------+
-  ! | <ij|ij> | 00T     | 00F     |         |         |         |         |         |         |
-  ! | <ii|ii> | 000     |         |         |         |         |         |         |         |
-  ! +---------+---------+---------+---------+---------+---------+---------+---------+---------+
-  END_DOC
-  integer, intent(in)            :: i,j,k,l
-  integer(key_kind), intent(out) :: idx
-  logical, intent(out)           :: use_map1
-  double precision, intent(out)  :: sign
-  integer(key_kind)              :: p,q,r,s,ik,jl,ij,kl
-  !DIR$ FORCEINLINE
-  call two_e_integrals_index_periodic(i,j,k,l,idx,ik,jl)
-  p = min(i,j)
-  r = max(i,j)
-  ij = p+shiftr(r*r-r,1)
-  q = min(k,l)
-  s = max(k,l)
-  kl = q+shiftr(s*s-s,1)
-
-  idx = 2*idx-1
-
-  if (ij==kl) then !real, J -> map1, K -> map2
-    sign=0.d0
-    if (i==k) then
-      use_map1=.True.
-    else
-      use_map1=.False.
-    endif
-  else
-    if (ik.eq.jl) then
-      if (i.lt.k) then   !TT0
-        sign=1.d0
-        use_map1=.True. 
-      else               !FF0
-        sign=-1.d0
-        use_map1=.True.
-      endif
-    else if (i.eq.k) then
-      if (j.lt.l) then   !0T* 
-        sign=1.d0
-        use_map1=.True.
-      else               !0F*
-        sign=-1.d0
-        use_map1=.True.
-      endif
-    else if (j.eq.l) then
-      if (i.lt.k) then
-        sign=1.d0
-        use_map1=.True.
-      else
-        sign=-1.d0
-        use_map1=.True.
-      endif
-    else if ((i.lt.k).eqv.(j.lt.l)) then
-      if (i.lt.k) then
-        sign=1.d0
-        use_map1=.True.
-      else
-        sign=-1.d0
-        use_map1=.True.
-      endif
-    else
-      if ((j.lt.l).eqv.(ik.lt.jl)) then
-        sign=1.d0
-        use_map1=.False.
-      else
-        sign=-1.d0
-        use_map1=.False.
-      endif
-    endif
-  endif
-end
-
-complex*16 function get_ao_two_e_integral_periodic_simple(i,j,k,l,map,map2) result(result)
-  use map_module
-  implicit none
-  BEGIN_DOC
-  ! Gets one AO bi-electronic integral from the AO map
-  END_DOC
-  integer, intent(in)            :: i,j,k,l
-  integer(key_kind)              :: idx1,idx2,idx
-  real(integral_kind)            :: tmp_re, tmp_im
-  integer(key_kind)              :: idx_re,idx_im
-  type(map_type), intent(inout)  :: map,map2
-  integer                        :: ii
-  complex(integral_kind)         :: tmp
-  integer(key_kind)              :: p,q,r,s,ik,jl
-  logical :: ilek, jlel, iklejl,use_map1
-  double precision :: sign
-  ! a.le.c, b.le.d, tri(a,c).le.tri(b,d)
-  PROVIDE ao_two_e_integrals_in_map
-  call ao_two_e_integral_periodic_map_idx_sign(i,j,k,l,use_map1,idx,sign)
-  if (use_map1) then
-    call map_get(map,idx,tmp_re)
-    if (sign/=0.d0) then
-      call map_get(map,idx+1,tmp_im)
-      tmp_im *= sign
-    else
-      tmp_im=0.d0
-    endif
-  else
-    call map_get(map2,idx,tmp_re)
-    if (sign/=0.d0) then
-      call map_get(map2,idx+1,tmp_im)
-      tmp_im *= sign
-    else
-      tmp_im=0.d0
-    endif
-  endif
-  tmp = dcmplx(tmp_re,tmp_im)
-  result = tmp
-end
-
-
-complex*16 function get_ao_two_e_integral_periodic(i,j,k,l,map,map2) result(result)
-  use map_module
-  implicit none
-  BEGIN_DOC
-  ! Gets one AO bi-electronic integral from the AO map
-  END_DOC
-  integer, intent(in)            :: i,j,k,l
-  integer(key_kind)              :: idx1,idx2
-  real(integral_kind)            :: tmp_re, tmp_im
-  integer(key_kind)              :: idx_re,idx_im
-  type(map_type), intent(inout)  :: map,map2
-  integer                        :: ii
-  complex(integral_kind)         :: tmp
-  complex(integral_kind)         :: get_ao_two_e_integral_periodic_simple
-  integer(key_kind)              :: p,q,r,s,ik,jl
-  logical :: ilek, jlel, iklejl
-  ! a.le.c, b.le.d, tri(a,c).le.tri(b,d)
-  PROVIDE ao_two_e_integrals_in_map ao_integrals_cache_periodic ao_integrals_cache_min
-  !DIR$ FORCEINLINE
-!  if (ao_overlap_abs(i,k)*ao_overlap_abs(j,l) < ao_integrals_threshold ) then
-!    tmp = (0.d0,0.d0)
-!  else if (ao_two_e_integral_schwartz(i,k)*ao_two_e_integral_schwartz(j,l) < ao_integrals_threshold) then
-!    tmp = (0.d0,0.d0)
-!  else
-  if (.True.) then
-    ii = l-ao_integrals_cache_min
-    ii = ior(ii, k-ao_integrals_cache_min)
-    ii = ior(ii, j-ao_integrals_cache_min)
-    ii = ior(ii, i-ao_integrals_cache_min)
-    if (iand(ii, -64) /= 0) then
-      tmp = get_ao_two_e_integral_periodic_simple(i,j,k,l,map,map2)
-    else
-      ii = l-ao_integrals_cache_min
-      ii = ior( shiftl(ii,6), k-ao_integrals_cache_min)
-      ii = ior( shiftl(ii,6), j-ao_integrals_cache_min)
-      ii = ior( shiftl(ii,6), i-ao_integrals_cache_min)
-      tmp = ao_integrals_cache_periodic(ii)
-    endif
-    result = tmp
-  endif
-end
-
-
 subroutine get_ao_two_e_integrals(j,k,l,sze,out_val)
   use map_module
   BEGIN_DOC
@@ -603,34 +248,6 @@ subroutine get_ao_two_e_integrals(j,k,l,sze,out_val)
 end
 
 
-subroutine get_ao_two_e_integrals_periodic(j,k,l,sze,out_val)
-  use map_module
-  BEGIN_DOC
-  ! Gets multiple AO bi-electronic integral from the AO map .
-  ! All i are retrieved for j,k,l fixed.
-  ! physicist convention : <ij|kl> 
-  END_DOC
-  implicit none
-  integer, intent(in)            :: j,k,l, sze
-  complex*16, intent(out) :: out_val(sze)
-
-  integer                        :: i
-  integer(key_kind)              :: hash
-  double precision               :: thresh
-  PROVIDE ao_two_e_integrals_in_map ao_integrals_map
-  thresh = ao_integrals_threshold
-
-  if (ao_overlap_abs(j,l) < thresh) then
-    out_val = (0.d0,0.d0)
-    return
-  endif
-
-  complex*16 :: get_ao_two_e_integral_periodic
-  do i=1,sze
-    out_val(i) = get_ao_two_e_integral_periodic(i,j,k,l,ao_integrals_map,ao_integrals_map_2)
-  enddo
-
-end
 
 subroutine get_ao_two_e_integrals_non_zero(j,k,l,sze,out_val,out_val_index,non_zero_int)
   use map_module
@@ -816,18 +433,4 @@ subroutine insert_into_ao_integrals_map(n_integrals,buffer_i, buffer_values)
   call map_append(ao_integrals_map, buffer_i, buffer_values, n_integrals)
 end
 
-subroutine insert_into_ao_integrals_map_2(n_integrals,buffer_i, buffer_values)
-  use map_module
-  implicit none
-  BEGIN_DOC
-  ! Create new entry into AO map
-  END_DOC
-
-  integer, intent(in)                :: n_integrals
-  integer(key_kind), intent(inout)   :: buffer_i(n_integrals)
-  real(integral_kind), intent(inout) :: buffer_values(n_integrals)
-
-  call map_append(ao_integrals_map_2, buffer_i, buffer_values, n_integrals)
-end
-
 

src/ao_two_e_ints/map_integrals_complex.irp.f

@@ -0,0 +1,546 @@
+use map_module
+
+
+subroutine two_e_integrals_index_periodic(i,j,k,l,i1,p,q)
+  use map_module
+  implicit none
+  BEGIN_DOC
+! Gives a unique index for i,j,k,l using permtuation symmetry.
+! i <-> k, j <-> l, and (i,k) <-> (j,l) 
+  END_DOC
+  integer, intent(in)            :: i,j,k,l
+  integer(key_kind), intent(out) :: i1
+  integer(key_kind)              :: r,s,i2
+  integer(key_kind),intent(out)   :: p,q
+  p = min(i,k)
+  r = max(i,k)
+  p = p+shiftr(r*r-r,1)
+  q = min(j,l)
+  s = max(j,l)
+  q = q+shiftr(s*s-s,1)
+  i1 = min(p,q)
+  i2 = max(p,q)
+  i1 = i1+shiftr(i2*i2-i2,1)
+end
+
+
+
+subroutine two_e_integrals_index_reverse_complex_1(i,j,k,l,i1)
+  use map_module
+  implicit none
+  BEGIN_DOC
+! Computes the 4 indices $i,j,k,l$ from a unique index $i_1$.
+! For 2 indices $i,j$ and $i \le j$, we have
+! $p = i(i-1)/2 + j$.
+! The key point is that because $j < i$,
+! $i(i-1)/2 < p \le i(i+1)/2$. So $i$ can be found by solving
+! $i^2 - i - 2p=0$. One obtains $i=1 + \sqrt{1+8p}/2$
+! and $j = p - i(i-1)/2$.
+! This rule is applied 3 times. First for the symmetry of the
+! pairs (i,k) and (j,l), and then for the symmetry within each pair.
+! always returns first set such that i<=k, j<=l, ik<=jl
+  END_DOC
+  integer, intent(out)           :: i(4),j(4),k(4),l(4)
+  integer(key_kind), intent(in)  :: i1
+  integer(key_kind)              :: i2,i3
+  i = 0
+  i2   = ceiling(0.5d0*(dsqrt(dble(shiftl(i1,3)+1))-1.d0))
+  l(1) = ceiling(0.5d0*(dsqrt(dble(shiftl(i2,3)+1))-1.d0))
+  i3   = i1 - shiftr(i2*i2-i2,1)
+  k(1) = ceiling(0.5d0*(dsqrt(dble(shiftl(i3,3)+1))-1.d0))
+  j(1) = int(i2 - shiftr(l(1)*l(1)-l(1),1),4)
+  i(1) = int(i3 - shiftr(k(1)*k(1)-k(1),1),4)
+
+              !ijkl a+ib
+  i(2) = j(1) !jilk a+ib
+  j(2) = i(1)
+  k(2) = l(1)
+  l(2) = k(1)
+
+  i(3) = k(1) !klij a-ib
+  j(3) = l(1)
+  k(3) = i(1)
+  l(3) = j(1)
+
+  i(4) = l(1) !lkji a-ib
+  j(4) = k(1)
+  k(4) = j(1)
+  l(4) = i(1)
+
+  integer :: ii, jj
+  do ii=2,4
+    do jj=1,ii-1
+      if ( (i(ii) == i(jj)).and. &
+           (j(ii) == j(jj)).and. &
+           (k(ii) == k(jj)).and. &
+           (l(ii) == l(jj)) ) then
+         i(ii) = 0
+         exit
+      endif
+    enddo
+  enddo
+end
+
+subroutine two_e_integrals_index_reverse_complex_2(i,j,k,l,i1)
+  use map_module
+  implicit none
+  BEGIN_DOC
+! Computes the 4 indices $i,j,k,l$ from a unique index $i_1$.
+! For 2 indices $i,j$ and $i \le j$, we have
+! $p = i(i-1)/2 + j$.
+! The key point is that because $j < i$,
+! $i(i-1)/2 < p \le i(i+1)/2$. So $i$ can be found by solving
+! $i^2 - i - 2p=0$. One obtains $i=1 + \sqrt{1+8p}/2$
+! and $j = p - i(i-1)/2$.
+! This rule is applied 3 times. First for the symmetry of the
+! pairs (i,k) and (j,l), and then for the symmetry within each pair.
+! always returns first set such that k<=i, j<=l, ik<=jl
+  END_DOC
+  integer, intent(out)           :: i(4),j(4),k(4),l(4)
+  integer(key_kind), intent(in)  :: i1
+  integer(key_kind)              :: i2,i3
+  i = 0
+  i2   = ceiling(0.5d0*(dsqrt(dble(shiftl(i1,3)+1))-1.d0))
+  l(1) = ceiling(0.5d0*(dsqrt(dble(shiftl(i2,3)+1))-1.d0))
+  i3   = i1 - shiftr(i2*i2-i2,1)
+  i(1) = ceiling(0.5d0*(dsqrt(dble(shiftl(i3,3)+1))-1.d0))
+  j(1) = int(i2 - shiftr(l(1)*l(1)-l(1),1),4)
+  k(1) = int(i3 - shiftr(i(1)*i(1)-i(1),1),4)
+
+              !kjil a+ib
+  i(2) = j(1) !jkli a+ib
+  j(2) = i(1)
+  k(2) = l(1)
+  l(2) = k(1)
+
+  i(3) = k(1) !ilkj a-ib
+  j(3) = l(1)
+  k(3) = i(1)
+  l(3) = j(1)
+
+  i(4) = l(1) !lijk a-ib
+  j(4) = k(1)
+  k(4) = j(1)
+  l(4) = i(1)
+
+  integer :: ii, jj
+  do ii=2,4
+    do jj=1,ii-1
+      if ( (i(ii) == i(jj)).and. &
+           (j(ii) == j(jj)).and. &
+           (k(ii) == k(jj)).and. &
+           (l(ii) == l(jj)) ) then
+         i(ii) = 0
+         exit
+      endif
+    enddo
+  enddo
+end
+
+
+BEGIN_PROVIDER [ complex*16, ao_integrals_cache_periodic, (0:64*64*64*64) ]
+ implicit none
+ BEGIN_DOC
+ ! Cache of AO integrals for fast access
+ END_DOC
+ PROVIDE ao_two_e_integrals_in_map
+ integer                        :: i,j,k,l,ii
+ integer(key_kind)              :: idx1, idx2
+ real(integral_kind)            :: tmp_re, tmp_im
+ integer(key_kind)              :: idx_re,idx_im
+ complex(integral_kind)         :: integral
+  integer(key_kind)              :: p,q,r,s,ik,jl
+  logical :: ilek, jlel, iklejl
+  complex*16 :: get_ao_two_e_integral_periodic_simple
+
+
+ !$OMP PARALLEL DO PRIVATE (ilek,jlel,p,q,r,s, ik,jl,iklejl, &
+ !$OMP                     i,j,k,l,idx1,idx2,tmp_re,tmp_im,idx_re,idx_im,ii,integral)
+ do l=ao_integrals_cache_min,ao_integrals_cache_max
+   do k=ao_integrals_cache_min,ao_integrals_cache_max
+     do j=ao_integrals_cache_min,ao_integrals_cache_max
+       do i=ao_integrals_cache_min,ao_integrals_cache_max
+         !DIR$ FORCEINLINE
+         integral = get_ao_two_e_integral_periodic_simple(i,j,k,l,&
+                    ao_integrals_map,ao_integrals_map_2)
+         
+         ii = l-ao_integrals_cache_min
+         ii = ior( shiftl(ii,6), k-ao_integrals_cache_min)
+         ii = ior( shiftl(ii,6), j-ao_integrals_cache_min)
+         ii = ior( shiftl(ii,6), i-ao_integrals_cache_min)
+         ao_integrals_cache_periodic(ii) = integral
+       enddo
+     enddo
+   enddo
+ enddo
+ !$OMP END PARALLEL DO
+
+END_PROVIDER
+
+subroutine ao_two_e_integral_periodic_map_idx_sign(i,j,k,l,use_map1,idx,sign) 
+  use map_module
+  implicit none
+  BEGIN_DOC
+  ! get position of periodic AO integral <ij|kl> 
+  ! use_map1: true if integral is in first ao map, false if integral is in second ao map
+  ! idx: position of real part of integral in map (imag part is at idx+1)
+  ! sign: sign of imaginary part
+  !
+  !
+  !  for <ab|cd>, conditionals are [a<c, b<d, ac<bd]
+  !  last two rows are real (ab==cd)
+  ! +---------+---------+---------+---------+---------+---------+---------+---------+---------+
+  ! | NEW     | <ij|kl> | <ji|lk> | <kl|ij> | <lk|ji> | <kj|il> | <jk|li> | <il|kj> | <li|jk> |
+  ! +---------+---------+---------+---------+---------+---------+---------+---------+---------+
+  ! |         |         m1        |         m1*       |         m2        |         m2*       |
+  ! +---------+---------+---------+---------+---------+---------+---------+---------+---------+
+  ! | <ij|kl> | TTT     | TTF     | FFT     | FFF     | FTT     | TFF     | TFT     | FTF     |
+  ! | <ij|il> | 0TT     | T0F     | 0FT     | F0F     |         |         |         |         |
+  ! | <ij|kj> | T0T     | 0TF     | F0T     | 0FF     |         |         |         |         |
+  ! | <ii|jj> | TT0     |         | FF0     |         | FT0(r)  | TF0(r)  |         |         |
+  ! +---------+---------+---------+---------+---------+---------+---------+---------+---------+
+  ! | <ij|ij> | 00T     | 00F     |         |         |         |         |         |         |
+  ! | <ii|ii> | 000     |         |         |         |         |         |         |         |
+  ! +---------+---------+---------+---------+---------+---------+---------+---------+---------+
+  END_DOC
+  integer, intent(in)            :: i,j,k,l
+  integer(key_kind), intent(out) :: idx
+  logical, intent(out)           :: use_map1
+  double precision, intent(out)  :: sign
+  integer(key_kind)              :: p,q,r,s,ik,jl,ij,kl
+  !DIR$ FORCEINLINE
+  call two_e_integrals_index_periodic(i,j,k,l,idx,ik,jl)
+  p = min(i,j)
+  r = max(i,j)
+  ij = p+shiftr(r*r-r,1)
+  q = min(k,l)
+  s = max(k,l)
+  kl = q+shiftr(s*s-s,1)
+
+  idx = 2*idx-1
+
+  if (ij==kl) then !real, J -> map1, K -> map2
+    sign=0.d0
+    if (i==k) then
+      use_map1=.True.
+    else
+      use_map1=.False.
+    endif
+  else
+    if (ik.eq.jl) then
+      if (i.lt.k) then   !TT0
+        sign=1.d0
+        use_map1=.True. 
+      else               !FF0
+        sign=-1.d0
+        use_map1=.True.
+      endif
+    else if (i.eq.k) then
+      if (j.lt.l) then   !0T* 
+        sign=1.d0
+        use_map1=.True.
+      else               !0F*
+        sign=-1.d0
+        use_map1=.True.
+      endif
+    else if (j.eq.l) then
+      if (i.lt.k) then
+        sign=1.d0
+        use_map1=.True.
+      else
+        sign=-1.d0
+        use_map1=.True.
+      endif
+    else if ((i.lt.k).eqv.(j.lt.l)) then
+      if (i.lt.k) then
+        sign=1.d0
+        use_map1=.True.
+      else
+        sign=-1.d0
+        use_map1=.True.
+      endif
+    else
+      if ((j.lt.l).eqv.(ik.lt.jl)) then
+        sign=1.d0
+        use_map1=.False.
+      else
+        sign=-1.d0
+        use_map1=.False.
+      endif
+    endif
+  endif
+end
+
+complex*16 function get_ao_two_e_integral_periodic_simple(i,j,k,l,map,map2) result(result)
+  use map_module
+  implicit none
+  BEGIN_DOC
+  ! Gets one AO bi-electronic integral from the AO map
+  END_DOC
+  integer, intent(in)            :: i,j,k,l
+  integer(key_kind)              :: idx1,idx2,idx
+  real(integral_kind)            :: tmp_re, tmp_im
+  integer(key_kind)              :: idx_re,idx_im
+  type(map_type), intent(inout)  :: map,map2
+  integer                        :: ii
+  complex(integral_kind)         :: tmp
+  integer(key_kind)              :: p,q,r,s,ik,jl
+  logical :: ilek, jlel, iklejl,use_map1
+  double precision :: sign
+  ! a.le.c, b.le.d, tri(a,c).le.tri(b,d)
+  PROVIDE ao_two_e_integrals_in_map
+  call ao_two_e_integral_periodic_map_idx_sign(i,j,k,l,use_map1,idx,sign)
+  if (use_map1) then
+    call map_get(map,idx,tmp_re)
+    if (sign/=0.d0) then
+      call map_get(map,idx+1,tmp_im)
+      tmp_im *= sign
+    else
+      tmp_im=0.d0
+    endif
+  else
+    call map_get(map2,idx,tmp_re)
+    if (sign/=0.d0) then
+      call map_get(map2,idx+1,tmp_im)
+      tmp_im *= sign
+    else
+      tmp_im=0.d0
+    endif
+  endif
+  tmp = dcmplx(tmp_re,tmp_im)
+  result = tmp
+end
+
+
+complex*16 function get_ao_two_e_integral_periodic(i,j,k,l,map,map2) result(result)
+  use map_module
+  implicit none
+  BEGIN_DOC
+  ! Gets one AO bi-electronic integral from the AO map
+  END_DOC
+  integer, intent(in)            :: i,j,k,l
+  integer(key_kind)              :: idx1,idx2
+  real(integral_kind)            :: tmp_re, tmp_im
+  integer(key_kind)              :: idx_re,idx_im
+  type(map_type), intent(inout)  :: map,map2
+  integer                        :: ii
+  complex(integral_kind)         :: tmp
+  complex(integral_kind)         :: get_ao_two_e_integral_periodic_simple
+  integer(key_kind)              :: p,q,r,s,ik,jl
+  logical :: ilek, jlel, iklejl
+  ! a.le.c, b.le.d, tri(a,c).le.tri(b,d)
+  PROVIDE ao_two_e_integrals_in_map ao_integrals_cache_periodic ao_integrals_cache_min
+  !DIR$ FORCEINLINE
+!  if (ao_overlap_abs(i,k)*ao_overlap_abs(j,l) < ao_integrals_threshold ) then
+!    tmp = (0.d0,0.d0)
+!  else if (ao_two_e_integral_schwartz(i,k)*ao_two_e_integral_schwartz(j,l) < ao_integrals_threshold) then
+!    tmp = (0.d0,0.d0)
+!  else
+  if (.True.) then
+    ii = l-ao_integrals_cache_min
+    ii = ior(ii, k-ao_integrals_cache_min)
+    ii = ior(ii, j-ao_integrals_cache_min)
+    ii = ior(ii, i-ao_integrals_cache_min)
+    if (iand(ii, -64) /= 0) then
+      tmp = get_ao_two_e_integral_periodic_simple(i,j,k,l,map,map2)
+    else
+      ii = l-ao_integrals_cache_min
+      ii = ior( shiftl(ii,6), k-ao_integrals_cache_min)
+      ii = ior( shiftl(ii,6), j-ao_integrals_cache_min)
+      ii = ior( shiftl(ii,6), i-ao_integrals_cache_min)
+      tmp = ao_integrals_cache_periodic(ii)
+    endif
+    result = tmp
+  endif
+end
+
+
+subroutine get_ao_two_e_integrals_periodic(j,k,l,sze,out_val)
+  use map_module
+  BEGIN_DOC
+  ! Gets multiple AO bi-electronic integral from the AO map .
+  ! All i are retrieved for j,k,l fixed.
+  ! physicist convention : <ij|kl> 
+  END_DOC
+  implicit none
+  integer, intent(in)            :: j,k,l, sze
+  complex*16, intent(out) :: out_val(sze)
+
+  integer                        :: i
+  integer(key_kind)              :: hash
+  double precision               :: thresh
+  PROVIDE ao_two_e_integrals_in_map ao_integrals_map
+  thresh = ao_integrals_threshold
+
+  if (ao_overlap_abs(j,l) < thresh) then
+    out_val = (0.d0,0.d0)
+    return
+  endif
+
+  complex*16 :: get_ao_two_e_integral_periodic
+  do i=1,sze
+    out_val(i) = get_ao_two_e_integral_periodic(i,j,k,l,ao_integrals_map,ao_integrals_map_2)
+  enddo
+
+end
+
+!subroutine get_ao_two_e_integrals_non_zero_periodic(j,k,l,sze,out_val,out_val_index,non_zero_int)
+!  use map_module
+!  implicit none
+!  BEGIN_DOC
+!  ! Gets multiple AO bi-electronic integral from the AO map .
+!  ! All non-zero i are retrieved for j,k,l fixed.
+!  END_DOC
+!  integer, intent(in)            :: j,k,l, sze
+!  real(integral_kind), intent(out) :: out_val(sze)
+!  integer, intent(out)           :: out_val_index(sze),non_zero_int
+!
+!  integer                        :: i
+!  integer(key_kind)              :: hash
+!  double precision               :: thresh,tmp
+!  if(is_periodic) then
+!    print*,'not implemented for periodic:',irp_here
+!    stop -1
+!  endif
+!  PROVIDE ao_two_e_integrals_in_map
+!  thresh = ao_integrals_threshold
+!
+!  non_zero_int = 0
+!  if (ao_overlap_abs(j,l) < thresh) then
+!    out_val = 0.d0
+!    return
+!  endif
+!
+!  non_zero_int = 0
+!  do i=1,sze
+!    integer, external :: ao_l4
+!    double precision, external :: ao_two_e_integral
+!    !DIR$ FORCEINLINE
+!    if (ao_two_e_integral_schwartz(i,k)*ao_two_e_integral_schwartz(j,l) < thresh) then
+!      cycle
+!    endif
+!    call two_e_integrals_index(i,j,k,l,hash)
+!    call map_get(ao_integrals_map, hash,tmp)
+!    if (dabs(tmp) < thresh ) cycle
+!    non_zero_int = non_zero_int+1
+!    out_val_index(non_zero_int) = i
+!    out_val(non_zero_int) = tmp
+!  enddo
+!
+!end
+
+
+!subroutine get_ao_two_e_integrals_non_zero_jl_periodic(j,l,thresh,sze_max,sze,out_val,out_val_index,non_zero_int)
+!  use map_module
+!  implicit none
+!  BEGIN_DOC
+!  ! Gets multiple AO bi-electronic integral from the AO map .
+!  ! All non-zero i are retrieved for j,k,l fixed.
+!  END_DOC
+!  double precision, intent(in)   :: thresh
+!  integer, intent(in)            :: j,l, sze,sze_max
+!  real(integral_kind), intent(out) :: out_val(sze_max)
+!  integer, intent(out)           :: out_val_index(2,sze_max),non_zero_int
+!
+!  integer                        :: i,k
+!  integer(key_kind)              :: hash
+!  double precision               :: tmp
+!
+!  if(is_periodic) then
+!    print*,'not implemented for periodic:',irp_here
+!    stop -1
+!  endif
+!  PROVIDE ao_two_e_integrals_in_map
+!  non_zero_int = 0
+!  if (ao_overlap_abs(j,l) < thresh) then
+!    out_val = 0.d0
+!    return
+!  endif
+!
+!  non_zero_int = 0
+!  do k = 1, sze
+!   do i = 1, sze
+!     integer, external :: ao_l4
+!     double precision, external :: ao_two_e_integral
+!     !DIR$ FORCEINLINE
+!     if (ao_two_e_integral_schwartz(i,k)*ao_two_e_integral_schwartz(j,l) < thresh) then
+!       cycle
+!     endif
+!     call two_e_integrals_index(i,j,k,l,hash)
+!     call map_get(ao_integrals_map, hash,tmp)
+!     if (dabs(tmp) < thresh ) cycle
+!     non_zero_int = non_zero_int+1
+!     out_val_index(1,non_zero_int) = i
+!     out_val_index(2,non_zero_int) = k
+!     out_val(non_zero_int) = tmp
+!   enddo
+!  enddo
+!
+!end
+
+
+!subroutine get_ao_two_e_integrals_non_zero_jl_from_list_periodic(j,l,thresh,list,n_list,sze_max,out_val,out_val_index,non_zero_int)
+!  use map_module
+!  implicit none
+!  BEGIN_DOC
+!  ! Gets multiple AO two-electron integrals from the AO map .
+!  ! All non-zero i are retrieved for j,k,l fixed.
+!  END_DOC
+!  double precision, intent(in)   :: thresh
+!  integer, intent(in)            :: sze_max
+!  integer, intent(in)            :: j,l, n_list,list(2,sze_max)
+!  real(integral_kind), intent(out) :: out_val(sze_max)
+!  integer, intent(out)           :: out_val_index(2,sze_max),non_zero_int
+!
+!  integer                        :: i,k
+!  integer(key_kind)              :: hash
+!  double precision               :: tmp
+!
+!  if(is_periodic) then
+!    print*,'not implemented for periodic:',irp_here
+!    stop -1
+!  endif
+!  PROVIDE ao_two_e_integrals_in_map
+!  non_zero_int = 0
+!  if (ao_overlap_abs(j,l) < thresh) then
+!    out_val = 0.d0
+!    return
+!  endif
+!
+!  non_zero_int = 0
+! integer :: kk
+!  do kk = 1, n_list
+!   k = list(1,kk)
+!   i = list(2,kk)
+!   integer, external :: ao_l4
+!   double precision, external :: ao_two_e_integral
+!   !DIR$ FORCEINLINE
+!   if (ao_two_e_integral_schwartz(i,k)*ao_two_e_integral_schwartz(j,l) < thresh) then
+!     cycle
+!   endif
+!   call two_e_integrals_index(i,j,k,l,hash)
+!   call map_get(ao_integrals_map, hash,tmp)
+!   if (dabs(tmp) < thresh ) cycle
+!   non_zero_int = non_zero_int+1
+!   out_val_index(1,non_zero_int) = i
+!   out_val_index(2,non_zero_int) = k
+!   out_val(non_zero_int) = tmp
+!  enddo
+!
+!end
+
+subroutine insert_into_ao_integrals_map_2(n_integrals,buffer_i, buffer_values)
+  use map_module
+  implicit none
+  BEGIN_DOC
+  ! Create new entry into AO map
+  END_DOC
+
+  integer, intent(in)                :: n_integrals
+  integer(key_kind), intent(inout)   :: buffer_i(n_integrals)
+  real(integral_kind), intent(inout) :: buffer_values(n_integrals)
+
+  call map_append(ao_integrals_map_2, buffer_i, buffer_values, n_integrals)
+end
+
+