qp_plugins_scemama/devel/svdwf/buildpsi_diagSVDit_v0.irp.f

program buildpsi_diagSVDit_v0

  implicit none

  BEGIN_DOC
  ! perturbative approach to build psi_postsvd
  END_DOC

  read_wf = .True.
  TOUCH read_wf

  PROVIDE N_int

  call run()
end


subroutine run

  USE OMP_LIB

  implicit none

  integer(bit_kind)             :: det1(N_int,2), det2(N_int,2)
  integer                       :: degree, i_state
  double precision              :: h12

  integer                       :: i, j, k, l, ii, jj, nn, na, nb

  double precision              :: norm_psi, inv_sqrt_norm_psi
  double precision, allocatable :: Uref(:,:), Dref(:), Vtref(:,:), Aref(:,:), Vref(:,:)

  double precision              :: E0_av, E0_ap, E0pt2
  double precision              :: err0, err_tmp, e_tmp, E0, overlop, E0_old, tol_energy
  double precision              :: ctmp, htmp, Ept2
  double precision              :: E0_postsvd, overlop_postsvd
  double precision              :: norm_coeff_psi, inv_sqrt_norm_coeff_psi
  double precision              :: overlopU, overlopU_mat, overlopV, overlopV_mat, overlop_psi

  double precision, allocatable :: Hdiag(:), Hkl(:,:), H0(:,:)
  double precision, allocatable :: psi_postsvd(:), coeff_psi(:), coeff_psi_perturb(:)

  integer                       :: n_FSVD, n_selected, n_toselect, n_tmp, it_svd, it_svd_max
  integer                       :: n_selected2
  integer,          allocatable :: numalpha_selected(:), numbeta_selected(:)
  integer,          allocatable :: numalpha_toselect(:), numbeta_toselect(:)
  integer,          allocatable :: numalpha_tmp(:), numbeta_tmp(:)

  integer(kind=8)               :: W_tbeg, W_tend, W_tbeg_it, W_tend_it, W_ir
  real(kind=8)                  :: W_tot_time, W_tot_time_it
  real(kind=8)                  :: CPU_tbeg, CPU_tend, CPU_tbeg_it, CPU_tend_it
  real(kind=8)                  :: CPU_tot_time, CPU_tot_time_it
  real(kind=8)                  :: speedup, speedup_it
  integer                       :: nb_taches

  !$OMP PARALLEL
  nb_taches = OMP_GET_NUM_THREADS()
  !$OMP END PARALLEL

  call CPU_TIME(CPU_tbeg)
  call SYSTEM_CLOCK(COUNT=W_tbeg, COUNT_RATE=W_ir)

  i_state = 1


  det1(:,1) = psi_det_alpha_unique(:,1)
  det2(:,1) = psi_det_alpha_unique(:,1)
  call get_excitation_degree_spin(det1(1,1),det2(1,1),degree,N_int)
  det1(:,2) = psi_det_beta_unique(:,1)
  det2(:,2) = psi_det_beta_unique(:,1)
  call get_excitation_degree(det1,det2,degree,N_int)
  call i_H_j(det1, det2, N_int, h12)
  ! ---------------------------------------------------------------------------------------
  !                      construct the initial CISD matrix

  print *, ' ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~'
  print *, ' CISD matrix:', n_det_alpha_unique,'x',n_det_beta_unique
  print *, ' N det      :', N_det
  print *, ' ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~'
 
  norm_psi = 0.d0
  do k = 1, N_det
    norm_psi = norm_psi + psi_bilinear_matrix_values(k,i_state) &
                        * psi_bilinear_matrix_values(k,i_state)
  enddo
  print *, ' initial norm = ', norm_psi

  allocate( Aref(n_det_alpha_unique,n_det_beta_unique) )
  Aref(:,:) = 0.d0
  do k = 1, N_det
    i         = psi_bilinear_matrix_rows(k)
    j         = psi_bilinear_matrix_columns(k)
    Aref(i,j) = psi_bilinear_matrix_values(k,i_state)
  enddo

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


  ! ---------------------------------------------------------------------------------------
  !                                  perform a Full SVD

  allocate( Uref(n_det_alpha_unique,n_det_beta_unique) )
  allocate( Dref(n_det_beta_unique) )
  allocate( Vref(n_det_beta_unique,n_det_beta_unique)  )
  allocate( Vtref(n_det_beta_unique,n_det_beta_unique) )
  call svd_s(Aref, size(Aref,1), Uref, size(Uref,1), Dref, Vtref, size(Vtref,1)          &
       , n_det_alpha_unique, n_det_beta_unique)

  print *, ' ~~~~~~~~~~~~~~~~~~~~~~~~~~~ '
  print *, ' ---   First SVD: ok    ---  '
  print *, ' ~~~~~~~~~~~~~~~~~~~~~~~~~~~ '

  do l = 1, n_det_beta_unique
    do i = 1, n_det_beta_unique
      Vref(i,l) = Vtref(l,i)
    enddo
  enddo
  deallocate( Vtref )

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

  nn = n_det_beta_unique

  ! ---------------------------------------------------------------------------------------
  !                               numerote vectors 

  ! Full rank
  n_FSVD = nn * nn
  print*, ' Full psi space rank = ', n_FSVD

  ! Truncated rank
  n_selected  = 20
  n_selected2 = n_selected * n_selected
  print*, ' initial psi space rank = ', n_selected

  allocate( numalpha_selected(n_selected) , numbeta_selected(n_selected) )
  do i = 1, n_selected
    numalpha_selected(i) = i
    numbeta_selected (i) = i
  enddo
  ! check SVD error
  err0 = 0.d0
  do j = 1, nn
    do i = 1, n_det_alpha_unique
      err_tmp = 0.d0
      do l = 1, n_selected
        err_tmp = err_tmp + Dref(l) * Uref(i,l) * Vref(j,l)
      enddo
      err_tmp = Aref(i,j) - err_tmp
      err0   += err_tmp * err_tmp
    enddo
  enddo
  print *, ' SVD err (%)     = ', 100.d0 * dsqrt(err0/norm_psi)

  deallocate( Aref )

  ! perturbative space rank
  k = 0
  n_toselect =  nn*nn - n_selected*n_selected
  allocate( numalpha_toselect(n_toselect) , numbeta_toselect(n_toselect) )
  ! nondiagonal blocs
  do i = 1, n_selected
    do j = n_selected+1, nn
      k = k + 1
      numalpha_toselect(k) = j 
      numbeta_toselect (k) = i
    enddo
  enddo
  do j = 1, n_selected
    do i = n_selected+1, nn
      k = k + 1
      numalpha_toselect(k) = j 
      numbeta_toselect (k) = i
    enddo
  enddo
  ! diagonal bloc
  do i = n_selected+1, nn
    do j = n_selected+1, nn
      k = k + 1
      numalpha_toselect(k) = j 
      numbeta_toselect (k) = i
    enddo
  enddo

  if( k.ne.n_toselect ) then
    print*, ' error in numeroting '
    stop
  endif
  print*, ' perturbative psi space rank = ', n_toselect

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



  !________________________________________________________________________________________________________
  !
  !                                   loop over SVD iterations
  !________________________________________________________________________________________________________

  E0_old     = 0.d0
  tol_energy = 1.d0
  it_svd     = 0 
  it_svd_max = 100

  do while( ( it_svd .lt. it_svd_max) .and. ( tol_energy .gt. 1d-8 ) )

    call CPU_TIME(CPU_tbeg_it)
    call SYSTEM_CLOCK(COUNT=W_tbeg_it, COUNT_RATE=W_ir) 

    it_svd = it_svd + 1
    print*, '+ + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +'
    print*, '                                                                         '
    print*, ' iteration', it_svd

    norm_coeff_psi = 0.d0
    do j = 1, n_selected
      norm_coeff_psi += Dref(j) * Dref(j)
    enddo
    inv_sqrt_norm_coeff_psi = 1.d0 / dsqrt(norm_coeff_psi)
    do j = 1, n_selected
      Dref(j) = Dref(j) * inv_sqrt_norm_coeff_psi
    enddo

    allocate( H0(n_selected2,n_selected2) )
    print *,  ''
    print *,  ''
    print *,  ''
    print *,  '-- Compute H --'
    call const_psihpsi_postsvd_H0(n_selected, n_selected2, Uref, Vref, H0)

    ! avant SVD
    E0 = 0.d0 
    do i = 1, n_selected
      ii = (i-1)*n_selected + i
      do j = 1, n_selected
        jj = (j-1)*n_selected + j
        E0 += Dref(j) * H0(jj,ii) * Dref(i)
      enddo
    enddo
    E0_av = E0 + nuclear_repulsion
    print *,' E0 (avant SVD) =', E0_av

    allocate( psi_postsvd(n_selected2) )
    print *,  ' --- Diag post-SVD --- '
    call diag_postsvd(n_selected, n_selected2, Dref, H0, E0_postsvd, overlop_postsvd, psi_postsvd)
    print*, ' postsvd energy  = ', E0_postsvd
    deallocate( H0 )

    ! post-SVD
    print *,  ' --- SVD --- '
    !Dref(:) = 0.d0
    call perform_newpostSVD(n_selected, n_selected2, psi_postsvd, Uref, Vref, Dref)
    deallocate( psi_postsvd )

    allocate( H0(n_selected2,n_selected2) )
    print *,  ' --- Compute H --- '
    call const_psihpsi_postsvd_H0(n_selected, n_selected2, Uref, Vref, H0)

    E0             = 0.d0 
    norm_coeff_psi = 0.d0
    do i = 1, n_selected
      ii = (i-1)*n_selected + i
      do j = 1, n_selected
        jj = (j-1)*n_selected + j
        E0 += Dref(j) * H0(jj,ii) * Dref(i)
      enddo
      norm_coeff_psi += Dref(i) * Dref(i)
    enddo
    E0_ap = E0 + nuclear_repulsion
    print *,' E0 (apres SVD) =', E0_ap
    !print *,' norm =', norm_coeff_psi
   
    deallocate(H0)

    print *,  ' --- Perturbation --- '

    allocate( Hdiag(n_toselect), Hkl(n_selected2,n_toselect) )
    call const_Hdiag_Hkl(n_selected, n_selected2, n_toselect, Uref, Vref, numalpha_toselect, numbeta_toselect, Hdiag, Hkl)
    !do l = 1, n_toselect
    !  na = numalpha_toselect(l)
    !  nb = numbeta_toselect (l)
    !  print *, na, nb, Hdiag(l)
    !enddo

    ! evaluate the coefficients for all the vectors
    allocate( coeff_psi_perturb(n_toselect) )
    ept2 = 0.d0
    do ii = 1, n_toselect
      !na = numalpha_toselect(ii)
      !nb = numbeta_toselect (ii)
      ctmp = 0.d0
      do i = 1, n_selected
        l = (i-1)*n_selected + i
        ctmp += Dref(i) * Hkl(l,ii)
      enddo
      coeff_psi_perturb(ii) = ctmp / ( E0_ap - (Hdiag(ii)+nuclear_repulsion) )
      ept2            += ctmp*ctmp / ( E0_ap - (Hdiag(ii)+nuclear_repulsion) )
    enddo
    E0pt2 = E0_ap + ept2
    print *, ' perturb energy = ', E0pt2, ept2

    tol_energy = 100.d0 * dabs(E0pt2-E0_old) / dabs(E0pt2)
    E0_old     = E0pt2

    deallocate( Hdiag, Hkl)

    print *,  ' --- SVD --- '
    call perform_newSVD(n_selected, n_selected2, n_toselect, numalpha_toselect, numbeta_toselect, coeff_psi_perturb, Uref, Vref, Dref)

    deallocate( coeff_psi_perturb )

    write(11,'(i5,4x,4(f22.15,2x))') it_svd, E0_av, E0_postsvd, E0_ap, E0pt2

    call CPU_TIME(CPU_tend_it)
    call SYSTEM_CLOCK(COUNT=W_tend_it, COUNT_RATE=W_ir)
    CPU_tot_time_it = CPU_tend_it - CPU_tbeg_it
    W_tot_time_it   = real(W_tend_it-W_tbeg_it, kind=8) / real(W_ir, kind=8)
    speedup_it      = CPU_tot_time_it / W_tot_time_it
    print '(//, 3X, "elapsed time = ", 1PE10.3, " min.", /,  &
              & 3X, "CPU time     = ", 1PE10.3, " min.", /,  &
              & 3X, "speed up     = ", 1PE10.3,//)', W_tot_time_it/60.d0, CPU_tot_time_it/60.d0, speedup_it

  end do
  !________________________________________________________________________________________________________
  !________________________________________________________________________________________________________



  deallocate( Uref, Vref, Dref )


  call CPU_TIME(CPU_tend)
  call SYSTEM_CLOCK(COUNT=W_tend, COUNT_RATE=W_ir)
  CPU_tot_time = CPU_tend - CPU_tbeg
  W_tot_time   = real(W_tend - W_tbeg, kind=8) / real(W_ir, kind=8)
  speedup      = CPU_tot_time / W_tot_time
  print *,' ___________________________________________________________________'
  print '(//,3X,"Execution avec ",i2," threads")',nb_taches
  print '(//, 3X, "elapsed time = ", 1PE10.3, " min.", /,  &
            & 3X, "CPU time     = ", 1PE10.3, " min.", /,  &
            & 3X, "speed up     = ", 1PE10.3 ,// )', W_tot_time/60.d0, CPU_tot_time/60.d0, speedup
  print *,' ___________________________________________________________________'


end








subroutine const_psihpsi_postsvd_H0(n_selected, n_selected2, Uref, Vref, H0)

  USE OMP_LIB

  implicit none

  integer, intent(in)           :: n_selected, n_selected2
  double precision, intent(in)  :: Uref(n_det_alpha_unique,n_det_beta_unique)
  double precision, intent(in)  :: Vref(n_det_beta_unique ,n_det_beta_unique)
  double precision, intent(out) :: H0(n_selected2,n_selected2)

  integer(bit_kind)             :: det1(N_int,2), det2(N_int,2)
  integer                       :: i, j, k, l, degree
  integer                       :: ii0, jj0, ii, jj, n, m, np, mp
  integer                       :: nn0, mm0, nn, mm, ind_gs
  double precision              :: h12, x

  double precision, allocatable :: H0_tmp(:,:) 


  H0(:,:) = 0.d0

 !$OMP PARALLEL DEFAULT(NONE)                                                                         &
 !$OMP          PRIVATE(n,np,nn0,nn,ii0,jj0,x,m,mp,mm0,mm,ii,jj,i,j,k,l,h12,det1,det2,H0_tmp,degree)  &
 !$OMP          SHARED(n_det_alpha_unique,n_det_beta_unique,psi_det_alpha_unique,psi_det_beta_unique, &
 !$OMP                 N_int,n_selected,n_selected2,Uref,Vref,H0 )
  allocate( H0_tmp(n_selected2,n_selected2) )
  H0_tmp(:,:) = 0.d0
 !$OMP DO COLLAPSE(2) SCHEDULE(DYNAMIC,8)
  do i = 1, n_det_alpha_unique
    do k = 1, n_det_alpha_unique
      det1(:,1) = psi_det_alpha_unique(:,i)
      det2(:,1) = psi_det_alpha_unique(:,k)
      call get_excitation_degree_spin(det1(1,1),det2(1,1),degree,N_int)
      if (degree .gt. 2) then
        cycle
      endif
      do j = 1, n_det_beta_unique
        det1(:,2) = psi_det_beta_unique(:,j)
        do l = 1, n_det_beta_unique
          det2(:,2) = psi_det_beta_unique(:,l)
          call get_excitation_degree(det1,det2,degree,N_int)
          if (degree .gt. 2) then
            cycle
          endif
          ! !!!
          call i_H_j(det1, det2, N_int, h12)
          ! !!!
          ! ~~~            H0                  ~~~
          do n  = 1, n_selected
            nn0 = (n-1)*n_selected
            do np = 1, n_selected
              nn  = nn0 + np
              x   = Uref(k,n) * Vref(l,np) * h12
              do m  = 1, n_selected
                mm0 = (m-1)*n_selected
                do mp = 1, n_selected
                  mm  = mm0 + mp
                  H0_tmp(mm,nn) += Uref(i,m) * Vref(j,mp) * x
                enddo
              enddo
            enddo
          enddo
          ! ~~~          ~~~~~~                ~~~
        enddo
      enddo
    enddo
  enddo
 !$OMP END DO
 !$OMP CRITICAL
  do n = 1, n_selected2
     do m = 1, n_selected2
       H0(m,n) += H0_tmp(m,n)
     enddo
  enddo
 !$OMP END CRITICAL
  deallocate( H0_tmp )
 !$OMP END PARALLEL

  return
end subroutine const_psihpsi_postsvd_H0





subroutine diag_postsvd(n_selected, n_selected2, Dref, H0, E0, overlop, psi_postsvd )

  USE OMP_LIB

  implicit none

  integer, intent(in)           :: n_selected, n_selected2
  double precision, intent(in)  :: H0(n_selected2,n_selected2)
  double precision, intent(in)  :: Dref(n_det_beta_unique)
  double precision, intent(out) :: E0, overlop, psi_postsvd(n_selected2)

  integer(bit_kind)             :: det1(N_int,2), det2(N_int,2)
  integer                       :: i, j, k, l, degree
  integer                       :: ii0, jj0, ii, jj, n, m, np, mp
  integer                       :: nn0, mm0, nn, mm, ind_gs
  double precision              :: h12, x

  double precision, allocatable :: eigvec0(:,:), eigval0(:), check_ov(:)

  ! diagonalize H0
  allocate( eigvec0(n_selected2,n_selected2), eigval0(n_selected2) )
  call lapack_diag(eigval0, eigvec0, H0, n_selected2, n_selected2)

  ! get the postsvd ground state
  allocate( check_ov(n_selected2) )
  do l = 1, n_selected2
    overlop = 0.d0
    do i = 1, n_selected
      ii      = n_selected*(i-1) + i
      overlop = overlop + eigvec0(ii,l) * Dref(i)
    enddo
    check_ov(l) = dabs(overlop)
  enddo
  ind_gs      = MAXLOC( check_ov, DIM=1 )
  !ind_gs      = 1
  overlop     = check_ov(ind_gs)
  E0          = eigval0(ind_gs)+nuclear_repulsion
  psi_postsvd = eigvec0(:,ind_gs)

  deallocate( check_ov, eigvec0, eigval0 )

  return
end subroutine diag_postsvd




subroutine const_Hdiag_Hkl(n_selected, n_selected2, n_toselect, Uref, Vref, numalpha_toselect, numbeta_toselect, Hdiag, Hkl)

  implicit none

  integer, intent(in)           :: n_selected, n_selected2, n_toselect
  integer, intent(in)           :: numalpha_toselect(n_toselect), numbeta_toselect(n_toselect)
  double precision, intent(in)  :: Uref(n_det_alpha_unique,n_det_beta_unique)
  double precision, intent(in)  :: Vref(n_det_beta_unique ,n_det_beta_unique)
  double precision, intent(out) :: Hdiag(n_toselect), Hkl(n_selected2,n_toselect)

  integer(bit_kind)             :: det1(N_int,2)
  integer(bit_kind)             :: det2(N_int,2)
  integer                       :: degree

  integer                       :: i, j, k, l
  integer                       :: ii0, jj0, ii, jj, n, m, np, mp
  double precision              :: h12, y

  double precision, allocatable :: Hdiag_tmp(:), Hkl_tmp(:,:) 


  Hdiag(:) = 0.d0
  Hkl(:,:) = 0.d0

 !$OMP PARALLEL DEFAULT(NONE)                                                                         &
 !$OMP          PRIVATE(n,ii0,jj0,y,m,mp,ii,jj,i,j,k,l,h12,det1,det2,Hdiag_tmp,Hkl_tmp,degree)         &
 !$OMP          SHARED(n_det_alpha_unique,n_det_beta_unique,psi_det_alpha_unique,psi_det_beta_unique, &
 !$OMP                 N_int,n_selected,n_toselect,Uref,Vref,numalpha_toselect,numbeta_toselect,      &
 !$OMP                 Hkl,Hdiag,n_selected2 )
  allocate( Hdiag_tmp(n_toselect), Hkl_tmp(n_selected2,n_toselect) )
  Hdiag_tmp(:) = 0.d0
  Hkl_tmp(:,:) = 0.d0
 !$OMP DO COLLAPSE(2) SCHEDULE(DYNAMIC,8)
  do i = 1, n_det_alpha_unique
    do k = 1, n_det_alpha_unique
      det1(:,1) = psi_det_alpha_unique(:,i)
      det2(:,1) = psi_det_alpha_unique(:,k)
      ! !!!
      ! ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 
      call get_excitation_degree_spin(det1(1,1),det2(1,1),degree,N_int)
      if (degree .gt. 2) then
        cycle
      endif
      ! ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 
      ! !!!
      do j = 1, n_det_beta_unique
        det1(:,2) = psi_det_beta_unique(:,j)
        do l = 1, n_det_beta_unique
          det2(:,2) = psi_det_beta_unique(:,l)
          ! !!!
          ! ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 
          call get_excitation_degree(det1,det2,degree,N_int)
          if (degree .gt. 2) then
            cycle
          endif
          ! ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ 
          ! !!!
          call i_H_j(det1, det2, N_int, h12)
          ! ~ ~ ~               H                ~ ~ ~
          do n = 1, n_toselect
            ii0 = numalpha_toselect(n)
            jj0 = numbeta_toselect (n)
            y   = Uref(k,ii0) * Vref(l,jj0) * h12
            ! Hdiag
            Hdiag_tmp(n) += y * Uref(i,ii0) * Vref(j,jj0)
            do m = 1, n_selected
              ii = (m-1)*n_selected
              do mp = 1, n_selected
                jj = ii + mp
                ! Hkl
                Hkl_tmp(jj,n) += Uref(i,m) * Vref(j,mp) * y
              enddo
            enddo
          enddo
          ! ~ ~ ~             ! ! !              ~ ~ ~
        enddo
      enddo
      ! !!!
    enddo
  enddo
 !$OMP END DO
 !$OMP CRITICAL
  do n = 1, n_toselect
     Hdiag(n) += Hdiag_tmp(n)
     do m = 1, n_selected2
       Hkl(m,n) += Hkl_tmp(m,n)
     enddo
  enddo
 !$OMP END CRITICAL
  deallocate( Hdiag_tmp,Hkl_tmp )
 !$OMP END PARALLEL

end subroutine const_Hdiag_Hkl






subroutine perform_newSVD(n_selected, n_selected2, n_toselect, numalpha_toselect, numbeta_toselect, coeff_psi_perturb, Uref, Vref, Dref)

  USE OMP_LIB

  integer, intent(in)             :: n_selected, n_toselect, n_selected2
  integer, intent(in)             :: numalpha_toselect(n_toselect), numbeta_toselect(n_toselect)
  double precision, intent(in)    :: coeff_psi_perturb(n_toselect)
  double precision, intent(inout) :: Uref(n_det_alpha_unique,n_det_beta_unique)
  double precision, intent(inout) :: Vref(n_det_beta_unique ,n_det_beta_unique)
  double precision, intent(inout) :: Dref(n_det_beta_unique)

  integer                         :: mm, nn, i, j, ii0, ii, l, jj, na, nb
  double precision                :: err0, err_norm, err_tmp, norm_tmp
  double precision                :: overlopU_mat, overlopV_mat, overlopU, overlopV
  double precision, allocatable   :: S_mat(:,:), SxVt(:,:)
  double precision, allocatable   :: U_svd(:,:), V_svd(:,:)
  double precision, allocatable   :: U_newsvd(:,:), V_newsvd(:,:), Vt_newsvd(:,:), D_newsvd(:), A_newsvd(:,:)

  mm = n_det_alpha_unique
  nn = n_det_beta_unique

  allocate( U_svd(mm,nn) , V_svd(nn,nn) , S_mat(nn,nn) )

  U_svd(:,:) = Uref(:,:)
  V_svd(:,:) = Vref(:,:)
  S_mat(:,:) = 0.d0
  norm_tmp   = 0.d0
  do j  = 1, n_det_beta_unique
    S_mat(j,j) = Dref(j)
    norm_tmp  += S_mat(j,j)*S_mat(j,j)
  enddo
  do l = 1, n_toselect
    na = numalpha_toselect(l)
    nb = numbeta_toselect (l)
    S_mat(na,nb) = coeff_psi_perturb(l)
    norm_tmp    += S_mat(na,nb)*S_mat(na,nb)
  enddo

  print*, ' norm de S_mat =', norm_tmp
  !norm_tmp = 1.d0/dsqrt(norm_tmp)
  !do i = 1, nn 
  !  do j = 1, nn 
  !    S_mat(j,i) = S_mat(j,i) * norm_tmp
  !  enddo
  !enddo


  ! first compute S_mat x transpose(V_svd)
  allocate( SxVt(nn,nn) )
  call dgemm( 'N', 'T', nn, nn, nn, 1.d0     &
             , S_mat     , size(S_mat,1)     &
             , V_svd     , size(V_svd,1)     &
             , 0.d0, SxVt, size(SxVt ,1)     )
  ! then compute U_svd x SxVt
  allocate( A_newsvd(mm,nn) )
  call dgemm( 'N', 'N', mm, nn, nn, 1.d0            &
             , U_svd         , size(U_svd   ,1)     &
             , SxVt          , size(SxVt    ,1)     &
             , 0.d0, A_newsvd, size(A_newsvd,1)     )
  deallocate( SxVt )

  ! perform new SVD
  allocate( U_newsvd(mm,nn), Vt_newsvd(nn,nn), D_newsvd(nn) )
  call svd_s( A_newsvd, size(A_newsvd,1), U_newsvd, size(U_newsvd,1), D_newsvd, Vt_newsvd, size(Vt_newsvd,1), mm, nn)
  print *, '    +++ new perturbative SVD is performed +++       '
  allocate( V_newsvd(nn,nn) )
  do l = 1, nn
    do j = 1, nn
      V_newsvd(j,l) = Vt_newsvd(l,j)
    enddo
  enddo

  ! check SVD error
  err0     = 0.d0
  err_norm = 0.d0
  do j = 1, nn
    do i = 1, mm
      err_tmp  = 0.d0
      do l = 1, nn
        err_tmp = err_tmp + D_newsvd(l) * U_newsvd(i,l) * V_newsvd(j,l)
      enddo
      err_tmp   = A_newsvd(i,j) - err_tmp
      err0     += err_tmp * err_tmp
      err_norm += A_newsvd(i,j) * A_newsvd(i,j)
    enddo
  enddo
  print *, ' SVD err (%)              = ', 100.d0 * dsqrt(err0/err_norm)
  print *, ' ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ '


  do l = 1, nn
    Dref(l)   = D_newsvd(l)
    Uref(:,l) = U_newsvd(:,l)
    Vref(:,l) = V_newsvd(:,l)
  enddo
  !print *, Dref(:)


  overlopU_mat = 0.d0
  overlopV_mat = 0.d0
  do i = 1, nn
    do j = 1, nn
      overlopU = 0.d0 
      do ii = 1, mm
        overlopU += Uref(ii,j) * Uref(ii,i)
      enddo
      overlopU_mat += overlopU
      overlopV = 0.d0 
      do ii = 1, nn
        overlopV += Vref(ii,j) * Vref(ii,i)
      enddo
      overlopV_mat += overlopV
    enddo
  enddo
  print *, 'overlop U =', overlopU_mat
  print *, 'overlop V =', overlopV_mat


  deallocate( U_newsvd, V_newsvd, Vt_newsvd, D_newsvd, A_newsvd )

  return

end subroutine perform_newSVD





subroutine perform_newpostSVD(n_selected, n_selected2, psi_postsvd, Uref, Vref, Dref)

  USE OMP_LIB

  integer, intent(in)             :: n_selected, n_selected2
  double precision, intent(in)    :: psi_postsvd(n_selected2)
  double precision, intent(inout) :: Uref(n_det_alpha_unique,n_det_beta_unique)
  double precision, intent(inout) :: Vref(n_det_beta_unique ,n_det_beta_unique)
  double precision, intent(inout) :: Dref(n_det_beta_unique)

  integer                         :: mm, nn, i, j, ii0, ii, l, jj, na, nb
  double precision                :: err0, err_norm, err_tmp, norm_tmp
  double precision                :: overlopU_mat, overlopV_mat, overlopU, overlopV
  double precision, allocatable   :: S_mat(:,:), SxVt(:,:)
  double precision, allocatable   :: U_svd(:,:), V_svd(:,:)
  double precision, allocatable   :: U_newsvd(:,:), V_newsvd(:,:), Vt_newsvd(:,:), D_newsvd(:), A_newsvd(:,:)

  mm = n_det_alpha_unique
  nn = n_det_beta_unique

  allocate( U_svd(mm,n_selected) , V_svd(nn,n_selected) , S_mat(n_selected,n_selected) )

  U_svd(:,:) = Uref(:,1:n_selected)
  V_svd(:,:) = Vref(:,1:n_selected)
  S_mat(:,:) = 0.d0
  do i = 1, n_selected
    ii = (i-1)*n_selected
    do j = 1, n_selected
      jj = ii + j
      S_mat(i,j) = psi_postsvd(jj)
    enddo
  enddo

  ! first compute S_mat x transpose(V_svd)
  allocate( SxVt(n_selected,nn) )
  call dgemm( 'N', 'T', n_selected, nn, n_selected, 1.d0     &
             , S_mat     , size(S_mat,1)                     &
             , V_svd     , size(V_svd,1)                     &
             , 0.d0, SxVt, size(SxVt ,1)                     )
  ! then compute U_svd x SxVt
  allocate( A_newsvd(mm,nn) )
  call dgemm( 'N', 'N', mm, nn, n_selected, 1.d0            &
             , U_svd         , size(U_svd   ,1)             &
             , SxVt          , size(SxVt    ,1)             &
             , 0.d0, A_newsvd, size(A_newsvd,1)             )
  deallocate( SxVt )

  ! perform new SVD
  allocate( U_newsvd(mm,nn), Vt_newsvd(nn,nn), D_newsvd(nn) )
  call svd_s( A_newsvd, size(A_newsvd,1), U_newsvd, size(U_newsvd,1), D_newsvd, Vt_newsvd, size(Vt_newsvd,1), mm, nn)
  print *, '    +++ new SVD is performed +++       '
  allocate( V_newsvd(nn,nn) )
  do l = 1, nn
    do j = 1, nn
      V_newsvd(j,l) = Vt_newsvd(l,j)
    enddo
  enddo

  ! check SVD error
  err0     = 0.d0
  err_norm = 0.d0
  do j = 1, nn
    do i = 1, mm
      err_tmp  = 0.d0
      do l = 1, n_selected
        err_tmp = err_tmp + D_newsvd(l) * U_newsvd(i,l) * V_newsvd(j,l)
      enddo
      err_tmp   = A_newsvd(i,j) - err_tmp
      err0     += err_tmp * err_tmp
      err_norm += A_newsvd(i,j) * A_newsvd(i,j)
    enddo
  enddo
  print *, ' SVD err (%) = ', 100.d0 * dsqrt(err0/err_norm)
  print *, ' ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ '

  do l = 1, n_selected
    Dref(l)   = D_newsvd(l)
    Uref(:,l) = U_newsvd(:,l)
    Vref(:,l) = V_newsvd(:,l)
  enddo
!  print *, Dref(:)

  overlopU_mat = 0.d0
  overlopV_mat = 0.d0
  do i = 1, nn
    do j = 1, nn
      overlopU = 0.d0 
      do ii = 1, mm
        overlopU += Uref(ii,j) * Uref(ii,i)
      enddo
      overlopU_mat += overlopU
      overlopV = 0.d0 
      do ii = 1, nn
        overlopV += Vref(ii,j) * Vref(ii,i)
      enddo
      overlopV_mat += overlopV
    enddo
  enddo
  print *, 'overlop U =', overlopU_mat
  print *, 'overlop V =', overlopV_mat


  deallocate( U_newsvd, V_newsvd, Vt_newsvd, D_newsvd, A_newsvd )

  return

end subroutine perform_newpostSVD