merge

configure

@@ -9,7 +9,7 @@ echo "QP_ROOT="$QP_ROOT
 unset CC
 unset CCXX
 
-TREXIO_VERSION=2.4.2
+TREXIO_VERSION=2.5.0
 
 # Force GCC instead of ICC for dependencies
 export CC=gcc

scripts/qp_import_trexio.py

@@ -160,7 +160,6 @@ def write_ezfio(trexio_filename, filename):
             ezfio.set_basis_shell_ang_mom(ang_mom)
             ezfio.set_basis_basis_nucleus_index([ x+1 for x in nucl_index ])
             ezfio.set_basis_prim_expo(exponent)
-            ezfio.set_basis_prim_coef(coefficient)
 
             nucl_shell_num = []
             prev = None
@@ -194,6 +193,10 @@ def write_ezfio(trexio_filename, filename):
 
             shell_factor = trexio.read_basis_shell_factor(trexio_file)
             prim_factor  = trexio.read_basis_prim_factor(trexio_file)
+            for i,p in enumerate(prim_factor):
+                coefficient[i] *= prim_factor[i]
+            ezfio.set_ao_basis_primitives_normalized(False)
+            ezfio.set_basis_prim_coef(coefficient)
 
         elif basis_type.lower() == "numerical":
 
@@ -245,13 +248,12 @@ def write_ezfio(trexio_filename, filename):
             ezfio.set_basis_nucleus_shell_num(nucl_shell_num)
 
             shell_factor = trexio.read_basis_shell_factor(trexio_file)
-            prim_factor  = [1.]*prim_num
         else:
            raise TypeError
 
         print(basis_type)
     except:
-        raise
+        basis_type = "None"
         print("None")
         ezfio.set_ao_basis_ao_cartesian(True)
 
@@ -262,9 +264,6 @@ def write_ezfio(trexio_filename, filename):
     except:
         cartesian = True
 
-    ao_num = trexio.read_ao_num(trexio_file)
-    ezfio.set_ao_basis_ao_num(ao_num)
-
     trexio_file_cart = trexio_file
     if basis_type.lower() == "gaussian" and not cartesian:
         try:
@@ -278,8 +277,12 @@ def write_ezfio(trexio_filename, filename):
         except:
           pass
 
+    ao_num = trexio.read_ao_num(trexio_file_cart)
+    ezfio.set_ao_basis_ao_num(ao_num)
+
+
     if cartesian and basis_type.lower() == "gaussian" and shell_num > 0:
-        ao_shell    = trexio.read_ao_shell(trexio_file)
+        ao_shell    = trexio.read_ao_shell(trexio_file_cart)
         at = [ nucl_index[i]+1 for i in ao_shell ]
         ezfio.set_ao_basis_ao_nucl(at)
 
@@ -314,6 +317,7 @@ def write_ezfio(trexio_filename, filename):
                 exponent.append(expo[i])
                 num_prim.append(num_prim0[i])
 
+        print (len(coefficient), ao_num)
         assert (len(coefficient) == ao_num)
         ezfio.set_ao_basis_ao_power(power_x + power_y + power_z)
         ezfio.set_ao_basis_ao_prim_num(num_prim)
@@ -384,6 +388,14 @@ def write_ezfio(trexio_filename, filename):
 
       # Read coefs from temporary cartesian file created in the AO section
       MoMatrix = trexio.read_mo_coefficient(trexio_file_cart)
+
+      # Renormalize MO coefs if needed
+      if trexio.has_ao_normalization(trexio_file_cart):
+        ezfio.set_ao_basis_ao_normalized(False)
+        norm = trexio.read_ao_normalization(trexio_file_cart)
+#        for j in range(mo_num):
+#           for i,f in enumerate(norm):
+#              MoMatrix[i,j] *= f
       ezfio.set_mo_basis_mo_coef(MoMatrix)
 
       mo_occ = [ 0. for i in range(mo_num) ]
@@ -486,10 +498,10 @@ def write_ezfio(trexio_filename, filename):
     if trexio.has_mo_spin(trexio_file):
        spin = trexio.read_mo_spin(trexio_file)
        if max(spin) == 1:
-         alpha = [ i for i in range(len(spin)) if spin[i] == 0 ]
-         alpha = [ alpha[i] for i in range(num_alpha) ]
-         beta  = [ i for i in range(len(spin)) if spin[i] == 1 ]
-         beta  = [ beta[i] for i in range(num_beta) ]
+         tmp   = [ i for i in range(len(spin)) if spin[i] == 0 ]
+         alpha = [ tmp[i] for i in range(num_alpha) ]
+         tmp   = [ i for i in range(len(spin)) if spin[i] == 1 ]
+         beta  = [ tmp[i] for i in range(num_beta) ]
          warnings.append("UHF orbitals orbitals read", end=' ')
     alpha_s = ['0']*mo_num
     beta_s  = ['0']*mo_num

src/ao_basis/aos.irp.f

@@ -55,9 +55,6 @@ END_PROVIDER
 
   do i=1,ao_num
 
-!    powA(1) = ao_power(i,1) +  ao_power(i,2) +  ao_power(i,3)
-!    powA(2) = 0
-!    powA(3) = 0
     powA(1) = ao_power(i,1)
     powA(2) = ao_power(i,2)
     powA(3) = ao_power(i,3)
@@ -76,16 +73,19 @@ END_PROVIDER
     endif
 
     ! Normalization of the contracted basis functions
-    if (ao_normalized) then
-      norm = 0.d0
-      do j=1,ao_prim_num(i)
-        do k=1,ao_prim_num(i)
-          call overlap_gaussian_xyz(C_A,C_A,ao_expo(i,j),ao_expo(i,k),powA,powA,overlap_x,overlap_y,overlap_z,c,nz)
-          norm = norm+c*ao_coef_normalized(i,j)*ao_coef_normalized(i,k)
-        enddo
+    norm = 0.d0
+    do j=1,ao_prim_num(i)
+      do k=1,ao_prim_num(i)
+        call overlap_gaussian_xyz(C_A,C_A,ao_expo(i,j),ao_expo(i,k),powA,powA,overlap_x,overlap_y,overlap_z,c,nz)
+        norm = norm+c*ao_coef_normalized(i,j)*ao_coef_normalized(i,k)
+      enddo
+    enddo
+    ao_coef_normalization_factor(i) = 1.d0/dsqrt(norm)
+
+    if (.not.ao_normalized) then
+      do j=1,ao_prim_num(i)
+        ao_coef_normalized(i,j) = ao_coef_normalized(i,j) * ao_coef_normalization_factor(i)
       enddo
-      ao_coef_normalization_factor(i) = 1.d0/dsqrt(norm)
-    else
       ao_coef_normalization_factor(i) = 1.d0
     endif
   enddo
@@ -339,3 +339,22 @@ BEGIN_PROVIDER [ character*(4), ao_l_char_space, (ao_num) ]
    ao_l_char_space(i) = give_ao_character_space
  enddo
 END_PROVIDER
+
+! ---
+
+BEGIN_PROVIDER [ logical, use_pw ]
+
+  implicit none
+
+  logical :: exist
+
+  use_pw = .false.
+
+  call ezfio_has_ao_basis_ao_expo_pw(exist)
+  if(exist) then
+    PROVIDE ao_expo_pw_ord_transp
+    if(maxval(dabs(ao_expo_pw_ord_transp(4,:,:))) .gt. 1d-15) use_pw = .true.
+  endif
+
+END_PROVIDER
+

src/ao_one_e_ints/ao_one_e_ints.irp.f

@@ -45,4 +45,3 @@ BEGIN_PROVIDER [ double precision, ao_one_e_integrals_imag,(ao_num,ao_num)]
 
 END_PROVIDER
 
-

src/ao_two_e_ints/cholesky.irp.f

@@ -314,7 +314,7 @@ END_PROVIDER
 
        do j=1,nq
 
-         if ( (Qmax < Dmin).or.(N+j*1_8 > ndim8) ) exit
+         if ( (Qmax <= Dmin).or.(N+j*1_8 > ndim8) ) exit
 
          ! i.
          rank = N+j

src/ao_two_e_ints/two_e_integrals.irp.f

@@ -40,8 +40,11 @@ double precision function ao_two_e_integral(i, j, k, l)
   double precision, external     :: ao_two_e_integral_erf
   double precision, external     :: ao_two_e_integral_cgtos
   double precision, external     :: ao_two_e_integral_schwartz_accel
+  double precision, external     :: ao_two_e_integral_general
+  double precision, external     :: general_primitive_integral
 
   logical, external :: do_schwartz_accel
+  double precision               :: coef1, coef2, coef3, coef4
 
   if(use_cgtos) then
 
@@ -58,83 +61,44 @@ double precision function ao_two_e_integral(i, j, k, l)
 
   else
 
-    dim1 = n_pt_max_integrals
-
     num_i = ao_nucl(i)
     num_j = ao_nucl(j)
     num_k = ao_nucl(k)
     num_l = ao_nucl(l)
     ao_two_e_integral = 0.d0
 
-      if (num_i /= num_j .or. num_k /= num_l .or. num_j /= num_k)then
-        do p = 1, 3
-          I_power(p) = ao_power(i,p)
-          J_power(p) = ao_power(j,p)
-          K_power(p) = ao_power(k,p)
-          L_power(p) = ao_power(l,p)
-          I_center(p) = nucl_coord(num_i,p)
-          J_center(p) = nucl_coord(num_j,p)
-          K_center(p) = nucl_coord(num_k,p)
-          L_center(p) = nucl_coord(num_l,p)
-        enddo
+    if (num_i /= num_j .or. num_k /= num_l .or. num_j /= num_k) then
 
-        double precision               :: coef1, coef2, coef3, coef4
-        double precision               :: p_inv,q_inv
-        double precision               :: general_primitive_integral
+      ao_two_e_integral = ao_two_e_integral_general(i,j,k,l,general_primitive_integral)
 
-        do p = 1, ao_prim_num(i)
-          coef1 = ao_coef_normalized_ordered_transp(p,i)
-          do q = 1, ao_prim_num(j)
-            coef2 = coef1*ao_coef_normalized_ordered_transp(q,j)
-            call give_explicit_poly_and_gaussian(P_new,P_center,pp,fact_p,iorder_p,&
-                ao_expo_ordered_transp(p,i),ao_expo_ordered_transp(q,j),                 &
-                I_power,J_power,I_center,J_center,dim1)
-            p_inv = 1.d0/pp
-            do r = 1, ao_prim_num(k)
-              coef3 = coef2*ao_coef_normalized_ordered_transp(r,k)
-              do s = 1, ao_prim_num(l)
-                coef4 = coef3*ao_coef_normalized_ordered_transp(s,l)
-                call give_explicit_poly_and_gaussian(Q_new,Q_center,qq,fact_q,iorder_q,&
-                    ao_expo_ordered_transp(r,k),ao_expo_ordered_transp(s,l),             &
-                    K_power,L_power,K_center,L_center,dim1)
-                q_inv = 1.d0/qq
-                integral = general_primitive_integral(dim1,              &
-                    P_new,P_center,fact_p,pp,p_inv,iorder_p,             &
-                    Q_new,Q_center,fact_q,qq,q_inv,iorder_q)
-                ao_two_e_integral = ao_two_e_integral +  coef4 * integral
-              enddo ! s
-            enddo  ! r
-          enddo   ! q
-        enddo    ! p
+    else
 
-      else
+      do p = 1, 3
+        I_power(p) = ao_power(i,p)
+        J_power(p) = ao_power(j,p)
+        K_power(p) = ao_power(k,p)
+        L_power(p) = ao_power(l,p)
+      enddo
+      double  precision              :: ERI
 
-        do p = 1, 3
-          I_power(p) = ao_power(i,p)
-          J_power(p) = ao_power(j,p)
-          K_power(p) = ao_power(k,p)
-          L_power(p) = ao_power(l,p)
-        enddo
-        double  precision              :: ERI
-
-        do p = 1, ao_prim_num(i)
-          coef1 = ao_coef_normalized_ordered_transp(p,i)
-          do q = 1, ao_prim_num(j)
-            coef2 = coef1*ao_coef_normalized_ordered_transp(q,j)
-            do r = 1, ao_prim_num(k)
-              coef3 = coef2*ao_coef_normalized_ordered_transp(r,k)
-              do s = 1, ao_prim_num(l)
-                coef4 = coef3*ao_coef_normalized_ordered_transp(s,l)
-                integral = ERI(                                          &
-                    ao_expo_ordered_transp(p,i),ao_expo_ordered_transp(q,j),ao_expo_ordered_transp(r,k),ao_expo_ordered_transp(s,l),&
-                    I_power(1),J_power(1),K_power(1),L_power(1),         &
-                    I_power(2),J_power(2),K_power(2),L_power(2),         &
-                    I_power(3),J_power(3),K_power(3),L_power(3))
-                ao_two_e_integral = ao_two_e_integral + coef4 * integral
-              enddo ! s
-            enddo  ! r
-          enddo   ! q
-        enddo    ! p
+      do p = 1, ao_prim_num(i)
+        coef1 = ao_coef_normalized_ordered_transp(p,i)
+        do q = 1, ao_prim_num(j)
+          coef2 = coef1*ao_coef_normalized_ordered_transp(q,j)
+          do r = 1, ao_prim_num(k)
+            coef3 = coef2*ao_coef_normalized_ordered_transp(r,k)
+            do s = 1, ao_prim_num(l)
+              coef4 = coef3*ao_coef_normalized_ordered_transp(s,l)
+              integral = ERI(                                          &
+                  ao_expo_ordered_transp(p,i),ao_expo_ordered_transp(q,j),ao_expo_ordered_transp(r,k),ao_expo_ordered_transp(s,l),&
+                  I_power(1),J_power(1),K_power(1),L_power(1),         &
+                  I_power(2),J_power(2),K_power(2),L_power(2),         &
+                  I_power(3),J_power(3),K_power(3),L_power(3))
+              ao_two_e_integral = ao_two_e_integral + coef4 * integral
+            enddo ! s
+          enddo  ! r
+        enddo   ! q
+      enddo    ! p
 
     endif
 
@@ -144,6 +108,76 @@ end
 
 ! ---
 
+double precision function ao_two_e_integral_general(i, j, k, l, op)
+
+  BEGIN_DOC
+  !  integral of the AO basis <ik|jl> or (ij|kl)
+  !     i(r1) j(r1) 1/r12 k(r2) l(r2)
+  END_DOC
+
+  implicit none
+  include 'utils/constants.include.F'
+
+  integer, intent(in)            :: i, j, k, l
+  double precision, external     :: op   ! Operator function
+
+  integer                        :: p, q, r, s
+  integer                        :: num_i,num_j,num_k,num_l,dim1,I_power(3),J_power(3),K_power(3),L_power(3)
+  integer                        :: iorder_p(3), iorder_q(3)
+  double precision               :: I_center(3), J_center(3), K_center(3), L_center(3)
+  double precision               :: integral
+  double precision               :: P_new(0:max_dim,3),P_center(3),fact_p,pp
+  double precision               :: Q_new(0:max_dim,3),Q_center(3),fact_q,qq
+
+  dim1 = n_pt_max_integrals
+
+  num_i = ao_nucl(i)
+  num_j = ao_nucl(j)
+  num_k = ao_nucl(k)
+  num_l = ao_nucl(l)
+  ao_two_e_integral_general = 0.d0
+
+  do p = 1, 3
+    I_power(p) = ao_power(i,p)
+    J_power(p) = ao_power(j,p)
+    K_power(p) = ao_power(k,p)
+    L_power(p) = ao_power(l,p)
+    I_center(p) = nucl_coord(num_i,p)
+    J_center(p) = nucl_coord(num_j,p)
+    K_center(p) = nucl_coord(num_k,p)
+    L_center(p) = nucl_coord(num_l,p)
+  enddo
+
+  double precision               :: coef1, coef2, coef3, coef4
+  double precision               :: p_inv,q_inv
+
+  do p = 1, ao_prim_num(i)
+    coef1 = ao_coef_normalized_ordered_transp(p,i)
+    do q = 1, ao_prim_num(j)
+      coef2 = coef1*ao_coef_normalized_ordered_transp(q,j)
+      call give_explicit_poly_and_gaussian(P_new,P_center,pp,fact_p,iorder_p,&
+          ao_expo_ordered_transp(p,i),ao_expo_ordered_transp(q,j),                 &
+          I_power,J_power,I_center,J_center,dim1)
+      p_inv = 1.d0/pp
+      do r = 1, ao_prim_num(k)
+        coef3 = coef2*ao_coef_normalized_ordered_transp(r,k)
+        do s = 1, ao_prim_num(l)
+          coef4 = coef3*ao_coef_normalized_ordered_transp(s,l)
+          call give_explicit_poly_and_gaussian(Q_new,Q_center,qq,fact_q,iorder_q,&
+              ao_expo_ordered_transp(r,k),ao_expo_ordered_transp(s,l),             &
+              K_power,L_power,K_center,L_center,dim1)
+          q_inv = 1.d0/qq
+          integral = op(dim1,              &
+              P_new,P_center,fact_p,pp,p_inv,iorder_p,             &
+              Q_new,Q_center,fact_q,qq,q_inv,iorder_q)
+          ao_two_e_integral_general = ao_two_e_integral_general +  coef4 * integral
+        enddo ! s
+      enddo  ! r
+    enddo   ! q
+  enddo    ! p
+
+end
+
 double precision function ao_two_e_integral_schwartz_accel(i,j,k,l)
   implicit none
   BEGIN_DOC
@@ -512,7 +546,7 @@ double precision function general_primitive_integral(dim,            &
   double precision               :: a,b,c,d,e,f,accu,pq,const
   double precision               :: pq_inv, p10_1, p10_2, p01_1, p01_2,pq_inv_2
   integer                        :: n_pt_tmp,n_pt_out, iorder
-  double precision               :: d1(0:max_dim),d_poly(0:max_dim),rint,d1_screened(0:max_dim)
+  double precision               :: d1(0:max_dim),d_poly(0:max_dim),d1_screened(0:max_dim)
 
   general_primitive_integral = 0.d0
 

src/mo_one_e_ints/mo_one_e_ints.irp.f

@@ -21,3 +21,14 @@ BEGIN_PROVIDER [ double precision, mo_one_e_integrals,(mo_num,mo_num)]
   call nullify_small_elements(mo_num,mo_num,mo_one_e_integrals,size(mo_one_e_integrals,1),1.d-15)
 
 END_PROVIDER
+
+
+BEGIN_PROVIDER [ double precision, ao_one_e_integrals_from_mo, (ao_num, ao_num)]
+ implicit none
+ BEGIN_DOC
+! Integrals of the one e hamiltonian obtained from the integrals on the MO basis 
+!
+! WARNING : this is equal to ao_one_e_integrals only if the AO and MO basis have the same number of functions
+ END_DOC
+ call mo_to_ao(mo_one_e_integrals,mo_num,ao_one_e_integrals_from_mo,ao_num)
+END_PROVIDER