d7/d77/cp__control__utils_8F_source.html

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

 !   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 Utilities to set up the control types

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

 MODULE cp_control_utils

    USE bibliography,                    ONLY: &

         andreussi2012, dewar1977, dewar1985, elstner1998, fattebert2002, grimme2017, hu2007, &

         krack2000, lippert1997, lippert1999, porezag1995, repasky2002, rocha2006, schenter2008, &

         seifert1996, souza2002, stengel2009, stewart1989, stewart2007, thiel1992, umari2002, &

         vanvoorhis2015, vandevondele2005a, vandevondele2005b, yin2017, zhechkov2005, cite_reference

    USE cp_control_types,                ONLY: &

         admm_control_create, admm_control_type, ddapc_control_create, ddapc_restraint_type, &

         dft_control_create, dft_control_type, efield_type, expot_control_create, &

         maxwell_control_create, qs_control_type, tddfpt2_control_type, tddfpt_control_create, &

         tddfpt_control_type, xtb_control_type

    USE cp_files,                        ONLY: close_file,&

                                               open_file

    USE cp_log_handling,                 ONLY: cp_get_default_logger,&

                                               cp_logger_type

    USE cp_output_handling,              ONLY: cp_print_key_finished_output,&

                                               cp_print_key_unit_nr

    USE cp_units,                        ONLY: cp_unit_from_cp2k,&

                                               cp_unit_to_cp2k

    USE force_fields_input,              ONLY: read_gp_section

    USE input_constants,                 ONLY: &

         admm1_type, admm2_type, admmp_type, admmq_type, admms_type, constant_env, custom_env, &

         do_admm_aux_exch_func_bee, do_admm_aux_exch_func_bee_libxc, do_admm_aux_exch_func_default, &

         do_admm_aux_exch_func_default_libxc, do_admm_aux_exch_func_none, &

         do_admm_aux_exch_func_opt, do_admm_aux_exch_func_opt_libxc, do_admm_aux_exch_func_pbex, &

         do_admm_aux_exch_func_pbex_libxc, do_admm_aux_exch_func_sx_libxc, &

         do_admm_basis_projection, do_admm_blocked_projection, do_admm_blocking_purify_full, &

         do_admm_charge_constrained_projection, do_admm_exch_scaling_merlot, &

         do_admm_exch_scaling_none, do_admm_purify_cauchy, do_admm_purify_cauchy_subspace, &

         do_admm_purify_mcweeny, do_admm_purify_mo_diag, do_admm_purify_mo_no_diag, &

         do_admm_purify_none, do_admm_purify_none_dm, do_ddapc_constraint, do_ddapc_restraint, &

         do_method_am1, do_method_dftb, do_method_gapw, do_method_gapw_xc, do_method_gpw, &

         do_method_lrigpw, do_method_mndo, do_method_mndod, do_method_ofgpw, do_method_pdg, &

         do_method_pm3, do_method_pm6, do_method_pm6fm, do_method_pnnl, do_method_rigpw, &

         do_method_rm1, do_method_xtb, do_pwgrid_ns_fullspace, do_pwgrid_ns_halfspace, &

         do_pwgrid_spherical, do_s2_constraint, do_s2_restraint, do_se_is_kdso, do_se_is_kdso_d, &

         do_se_is_slater, do_se_lr_ewald, do_se_lr_ewald_gks, do_se_lr_ewald_r3, do_se_lr_none, &

         gapw_1c_large, gapw_1c_medium, gapw_1c_orb, gapw_1c_small, gapw_1c_very_large, &

         gaussian_env, no_admm_type, numerical, ramp_env, real_time_propagation, sccs_andreussi, &

         sccs_derivative_cd3, sccs_derivative_cd5, sccs_derivative_cd7, sccs_derivative_fft, &

         sccs_fattebert_gygi, sic_ad, sic_eo, sic_list_all, sic_list_unpaired, sic_mauri_spz, &

         sic_mauri_us, sic_none, slater, tddfpt_dipole_length, tddfpt_excitations, &

         tddfpt_kernel_stda, use_mom_ref_user

    USE input_cp2k_check,                ONLY: xc_functionals_expand

    USE input_cp2k_dft,                  ONLY: create_dft_section

    USE input_enumeration_types,         ONLY: enum_i2c,&

                                               enumeration_type

    USE input_keyword_types,             ONLY: keyword_get,&

                                               keyword_type

    USE input_section_types,             ONLY: &

         section_get_ival, section_get_keyword, section_release, section_type, section_vals_get, &

         section_vals_get_subs_vals, section_vals_type, section_vals_val_get, section_vals_val_set

    USE kinds,                           ONLY: default_path_length,&

                                               default_string_length,&

                                               dp

    USE mathconstants,                   ONLY: fourpi

    USE pair_potential_types,            ONLY: pair_potential_reallocate

    USE periodic_table,                  ONLY: get_ptable_info

    USE qs_cdft_utils,                   ONLY: read_cdft_control_section

    USE string_utilities,                ONLY: uppercase

    USE util,                            ONLY: sort

    USE xc,                              ONLY: xc_uses_kinetic_energy_density,&

                                               xc_uses_norm_drho

    USE xc_input_constants,              ONLY: xc_deriv_collocate

    USE xc_write_output,                 ONLY: xc_write

 #include "./base/base_uses.f90"


    IMPLICIT NONE


    PRIVATE


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


    PUBLIC :: read_dft_control, &

              read_mgrid_section, &

              read_qs_section, &

              read_tddfpt_control, &

              read_tddfpt2_control, &

              write_dft_control, &

              write_qs_control, &

              write_admm_control, &

              read_ddapc_section

 CONTAINS


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

 !> \brief ...

 !> \param dft_control ...

 !> \param dft_section ...

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

    SUBROUTINE read_dft_control(dft_control, dft_section)

       TYPE(dft_control_type), POINTER                    :: dft_control

       TYPE(section_vals_type), POINTER                   :: dft_section


       CHARACTER(len=default_path_length)                 :: basis_set_file_name, potential_file_name

       CHARACTER(LEN=default_string_length), &

          DIMENSION(:), POINTER                           :: tmpstringlist

       INTEGER                                            :: admmtype, excitations, irep, isize, &

                                                             method_id, nrep, xc_deriv_method_id

       LOGICAL                                            :: do_ot, do_rtp, exopt1, exopt2, exopt3, &

                                                             explicit, is_present, l_param, not_se, &

                                                             was_present

       REAL(kind=dp)                                      :: density_cut, gradient_cut, tau_cut

       REAL(kind=dp), DIMENSION(:), POINTER               :: pol

       TYPE(cp_logger_type), POINTER                      :: logger

       TYPE(section_vals_type), POINTER                   :: maxwell_section, sccs_section, &

                                                             scf_section, tmp_section, &

                                                             xc_fun_section, xc_section


       was_present = .false.


       logger => cp_get_default_logger()


       NULLIFY (tmp_section, xc_fun_section, xc_section)

       ALLOCATE (dft_control)

       CALL dft_control_create(dft_control)

       ! determine wheather this is a semiempirical or DFTB run

       ! --> (no XC section needs to be provided)

       not_se = .true.

       CALL section_vals_val_get(dft_section, "QS%METHOD", i_val=method_id)

       SELECT CASE (method_id)

       CASE (do_method_dftb, do_method_xtb, do_method_mndo, do_method_am1, do_method_pm3, do_method_pnnl, &

             do_method_pm6, do_method_pm6fm, do_method_pdg, do_method_rm1, do_method_mndod)

          not_se = .false.

       END SELECT

       ! Check for XC section and XC_FUNCTIONAL section

       xc_section => section_vals_get_subs_vals(dft_section, "XC")

       CALL section_vals_get(xc_section, explicit=is_present)

       IF (.NOT. is_present .AND. not_se) THEN

          cpabort("XC section missing.")

       END IF

       IF (is_present) THEN

          CALL section_vals_val_get(xc_section, "density_cutoff", r_val=density_cut)

          CALL section_vals_val_get(xc_section, "gradient_cutoff", r_val=gradient_cut)

          CALL section_vals_val_get(xc_section, "tau_cutoff", r_val=tau_cut)

          ! Perform numerical stability checks and possibly correct the issues

          IF (density_cut <= epsilon(0.0_dp)*100.0_dp) &

             CALL cp_warn(__location__, &

                          "DENSITY_CUTOFF lower than 100*EPSILON, where EPSILON is the machine precision. "// &

                          "This may lead to numerical problems. Setting up shake_tol to 100*EPSILON! ")

          density_cut = max(epsilon(0.0_dp)*100.0_dp, density_cut)

          IF (gradient_cut <= epsilon(0.0_dp)*100.0_dp) &

             CALL cp_warn(__location__, &

                          "GRADIENT_CUTOFF lower than 100*EPSILON, where EPSILON is the machine precision. "// &

                          "This may lead to numerical problems. Setting up shake_tol to 100*EPSILON! ")

          gradient_cut = max(epsilon(0.0_dp)*100.0_dp, gradient_cut)

          IF (tau_cut <= epsilon(0.0_dp)*100.0_dp) &

             CALL cp_warn(__location__, &

                          "TAU_CUTOFF lower than 100*EPSILON, where EPSILON is the machine precision. "// &

                          "This may lead to numerical problems. Setting up shake_tol to 100*EPSILON! ")

          tau_cut = max(epsilon(0.0_dp)*100.0_dp, tau_cut)

          CALL section_vals_val_set(xc_section, "density_cutoff", r_val=density_cut)

          CALL section_vals_val_set(xc_section, "gradient_cutoff", r_val=gradient_cut)

          CALL section_vals_val_set(xc_section, "tau_cutoff", r_val=tau_cut)

       END IF

       xc_fun_section => section_vals_get_subs_vals(xc_section, "XC_FUNCTIONAL")

       CALL section_vals_get(xc_fun_section, explicit=is_present)

       IF (.NOT. is_present .AND. not_se) THEN

          cpabort("XC_FUNCTIONAL section missing.")

       END IF

       scf_section => section_vals_get_subs_vals(dft_section, "SCF")

       CALL section_vals_val_get(dft_section, "UKS", l_val=dft_control%uks)

       CALL section_vals_val_get(dft_section, "ROKS", l_val=dft_control%roks)

       IF (dft_control%uks .OR. dft_control%roks) THEN

          dft_control%nspins = 2

       ELSE

          dft_control%nspins = 1

       END IF


       dft_control%lsd = (dft_control%nspins > 1)

       dft_control%use_kinetic_energy_density = xc_uses_kinetic_energy_density(xc_fun_section, dft_control%lsd)


       xc_deriv_method_id = section_get_ival(xc_section, "XC_GRID%XC_DERIV")

       dft_control%drho_by_collocation = (xc_uses_norm_drho(xc_fun_section, dft_control%lsd) &

                                          .AND. (xc_deriv_method_id == xc_deriv_collocate))

       IF (dft_control%drho_by_collocation) THEN

          cpabort("derivatives by collocation not implemented")

       END IF


       ! Automatic auxiliary basis set generation

       CALL section_vals_val_get(dft_section, "AUTO_BASIS", n_rep_val=nrep)

       DO irep = 1, nrep

          CALL section_vals_val_get(dft_section, "AUTO_BASIS", i_rep_val=irep, c_vals=tmpstringlist)

          IF (SIZE(tmpstringlist) == 2) THEN

             CALL uppercase(tmpstringlist(2))

             SELECT CASE (tmpstringlist(2))

             CASE ("X")

                isize = -1

             CASE ("SMALL")

                isize = 0

             CASE ("MEDIUM")

                isize = 1

             CASE ("LARGE")

                isize = 2

             CASE ("HUGE")

                isize = 3

             CASE DEFAULT

                cpwarn("Unknown basis size in AUTO_BASIS keyword:"//trim(tmpstringlist(1)))

             END SELECT

             !

             SELECT CASE (tmpstringlist(1))

             CASE ("X")

             CASE ("RI_AUX")

                dft_control%auto_basis_ri_aux = isize

             CASE ("AUX_FIT")

                dft_control%auto_basis_aux_fit = isize

             CASE ("LRI_AUX")

                dft_control%auto_basis_lri_aux = isize

             CASE ("P_LRI_AUX")

                dft_control%auto_basis_p_lri_aux = isize

             CASE ("RI_HXC")

                dft_control%auto_basis_ri_hxc = isize

             CASE ("RI_XAS")

                dft_control%auto_basis_ri_xas = isize

             CASE ("RI_HFX")

                dft_control%auto_basis_ri_hfx = isize

             CASE DEFAULT

                cpwarn("Unknown basis type in AUTO_BASIS keyword:"//trim(tmpstringlist(1)))

             END SELECT

          ELSE

             CALL cp_abort(__location__, &

                           "AUTO_BASIS keyword in &DFT section has a wrong number of arguments.")

          END IF

       END DO


       !! check if we do wavefunction fitting

       tmp_section => section_vals_get_subs_vals(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD")

       CALL section_vals_get(tmp_section, explicit=is_present)

       dft_control%do_admm = is_present

       dft_control%do_admm_mo = .false.

       dft_control%do_admm_dm = .false.

       IF (is_present) THEN

          do_ot = .false.

          CALL section_vals_val_get(scf_section, "OT%_SECTION_PARAMETERS_", l_val=do_ot)

          CALL admm_control_create(dft_control%admm_control)


          CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%ADMM_TYPE", i_val=admmtype)

          CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%ADMM_PURIFICATION_METHOD", explicit=exopt1)

          CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%METHOD", explicit=exopt2)

          CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%EXCH_SCALING_MODEL", explicit=exopt3)

          dft_control%admm_control%admm_type = admmtype

          SELECT CASE (admmtype)

          CASE (no_admm_type)

             CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%ADMM_PURIFICATION_METHOD", i_val=method_id)

             dft_control%admm_control%purification_method = method_id

             CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%METHOD", i_val=method_id)

             dft_control%admm_control%method = method_id

             CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%EXCH_SCALING_MODEL", i_val=method_id)

             dft_control%admm_control%scaling_model = method_id

          CASE (admm1_type)

             ! METHOD BASIS_PROJECTION

             ! ADMM_PURIFICATION_METHOD choose

             ! EXCH_SCALING_MODEL NONE

             CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%ADMM_PURIFICATION_METHOD", i_val=method_id)

             dft_control%admm_control%purification_method = method_id

             dft_control%admm_control%method = do_admm_basis_projection

             dft_control%admm_control%scaling_model = do_admm_exch_scaling_none

          CASE (admm2_type)

             ! METHOD BASIS_PROJECTION

             ! ADMM_PURIFICATION_METHOD NONE

             ! EXCH_SCALING_MODEL NONE

             dft_control%admm_control%purification_method = do_admm_purify_none

             dft_control%admm_control%method = do_admm_basis_projection

             dft_control%admm_control%scaling_model = do_admm_exch_scaling_none

          CASE (admms_type)

             ! ADMM_PURIFICATION_METHOD NONE

             ! METHOD CHARGE_CONSTRAINED_PROJECTION

             ! EXCH_SCALING_MODEL MERLOT

             dft_control%admm_control%purification_method = do_admm_purify_none

             dft_control%admm_control%method = do_admm_charge_constrained_projection

             dft_control%admm_control%scaling_model = do_admm_exch_scaling_merlot

          CASE (admmp_type)

             ! ADMM_PURIFICATION_METHOD NONE

             ! METHOD BASIS_PROJECTION

             ! EXCH_SCALING_MODEL MERLOT

             dft_control%admm_control%purification_method = do_admm_purify_none

             dft_control%admm_control%method = do_admm_basis_projection

             dft_control%admm_control%scaling_model = do_admm_exch_scaling_merlot

          CASE (admmq_type)

             ! ADMM_PURIFICATION_METHOD NONE

             ! METHOD CHARGE_CONSTRAINED_PROJECTION

             ! EXCH_SCALING_MODEL NONE

             dft_control%admm_control%purification_method = do_admm_purify_none

             dft_control%admm_control%method = do_admm_charge_constrained_projection

             dft_control%admm_control%scaling_model = do_admm_exch_scaling_none

          CASE DEFAULT

             CALL cp_abort(__location__, &

                           "ADMM_TYPE keyword in &AUXILIARY_DENSITY_MATRIX_METHOD section has a wrong value.")

          END SELECT


          CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%EPS_FILTER", &

                                    r_val=dft_control%admm_control%eps_filter)


          CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%EXCH_CORRECTION_FUNC", i_val=method_id)

          dft_control%admm_control%aux_exch_func = method_id


          ! parameters for X functional

          dft_control%admm_control%aux_exch_func_param = .false.

          CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%OPTX_A1", explicit=explicit, &

                                    r_val=dft_control%admm_control%aux_x_param(1))

          IF (explicit) dft_control%admm_control%aux_exch_func_param = .true.

          CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%OPTX_A2", explicit=explicit, &

                                    r_val=dft_control%admm_control%aux_x_param(2))

          IF (explicit) dft_control%admm_control%aux_exch_func_param = .true.

          CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%OPTX_GAMMA", explicit=explicit, &

                                    r_val=dft_control%admm_control%aux_x_param(3))

          IF (explicit) dft_control%admm_control%aux_exch_func_param = .true.


          CALL read_admm_block_list(dft_control%admm_control, dft_section)


          ! check for double assignments

          SELECT CASE (admmtype)

          CASE (admm2_type)

             IF (exopt2) CALL cp_warn(__location__, &

                                      "Value of ADMM_PURIFICATION_METHOD keyword will be overwritten with ADMM_TYPE selections.")

             IF (exopt3) CALL cp_warn(__location__, &

                                      "Value of EXCH_SCALING_MODEL keyword will be overwritten with ADMM_TYPE selections.")

          CASE (admm1_type, admms_type, admmp_type, admmq_type)

             IF (exopt1) CALL cp_warn(__location__, &

                                      "Value of METHOD keyword will be overwritten with ADMM_TYPE selections.")

             IF (exopt2) CALL cp_warn(__location__, &

                                      "Value of METHOD keyword will be overwritten with ADMM_TYPE selections.")

             IF (exopt3) CALL cp_warn(__location__, &

                                      "Value of EXCH_SCALING_MODEL keyword will be overwritten with ADMM_TYPE selections.")

          END SELECT


          !    In the case of charge-constrained projection (e.g. according to Merlot),

          !    there is no purification needed and hence, do_admm_purify_none has to be set.


          IF ((dft_control%admm_control%method == do_admm_blocking_purify_full .OR. &

               dft_control%admm_control%method == do_admm_blocked_projection) &

              .AND. dft_control%admm_control%scaling_model == do_admm_exch_scaling_merlot) THEN

             cpabort("ADMM: Blocking and Merlot scaling are mutually exclusive.")

          END IF


          IF (dft_control%admm_control%method == do_admm_charge_constrained_projection .AND. &

              dft_control%admm_control%purification_method /= do_admm_purify_none) THEN

             CALL cp_abort(__location__, &

                           "ADMM: In the case of METHOD=CHARGE_CONSTRAINED_PROJECTION, "// &

                           "ADMM_PURIFICATION_METHOD=NONE has to be set.")

          END IF


          IF (dft_control%admm_control%purification_method == do_admm_purify_mo_diag .OR. &

              dft_control%admm_control%purification_method == do_admm_purify_mo_no_diag) THEN

             IF (dft_control%admm_control%method /= do_admm_basis_projection) &

                cpabort("ADMM: Chosen purification requires BASIS_PROJECTION")


             IF (.NOT. do_ot) cpabort("ADMM: MO-based purification requires OT.")

          END IF


          IF (dft_control%admm_control%purification_method == do_admm_purify_none_dm .OR. &

              dft_control%admm_control%purification_method == do_admm_purify_mcweeny) THEN

             dft_control%do_admm_dm = .true.

          ELSE

             dft_control%do_admm_mo = .true.

          END IF

       END IF


       ! Set restricted to true, if both OT and ROKS are requested

       !MK in principle dft_control%restricted could be dropped completely like the

       !MK input key by using only dft_control%roks now

       CALL section_vals_val_get(scf_section, "OT%_SECTION_PARAMETERS_", l_val=l_param)

       dft_control%restricted = (dft_control%roks .AND. l_param)


       CALL section_vals_val_get(dft_section, "CHARGE", i_val=dft_control%charge)

       CALL section_vals_val_get(dft_section, "MULTIPLICITY", i_val=dft_control%multiplicity)

       CALL section_vals_val_get(dft_section, "RELAX_MULTIPLICITY", r_val=dft_control%relax_multiplicity)

       IF (dft_control%relax_multiplicity > 0.0_dp) THEN

          IF (.NOT. dft_control%uks) &

             CALL cp_abort(__location__, "The option RELAX_MULTIPLICITY is only valid for "// &

                           "unrestricted Kohn-Sham (UKS) calculations")

       END IF


       ! check for the presence of the low spin roks section

       tmp_section => section_vals_get_subs_vals(dft_section, "LOW_SPIN_ROKS")

       CALL section_vals_get(tmp_section, explicit=dft_control%low_spin_roks)


       dft_control%sic_method_id = sic_none

       dft_control%sic_scaling_a = 1.0_dp

       dft_control%sic_scaling_b = 1.0_dp


       ! DFT+U

       dft_control%dft_plus_u = .false.

       CALL section_vals_val_get(dft_section, "PLUS_U_METHOD", i_val=method_id)

       dft_control%plus_u_method_id = method_id


       ! Smearing in use

       dft_control%smear = .false.


       ! Surface dipole correction

       dft_control%correct_surf_dip = .false.

       CALL section_vals_val_get(dft_section, "SURFACE_DIPOLE_CORRECTION", l_val=dft_control%correct_surf_dip)

       CALL section_vals_val_get(dft_section, "SURF_DIP_DIR", i_val=dft_control%dir_surf_dip)

       dft_control%pos_dir_surf_dip = -1.0_dp

       CALL section_vals_val_get(dft_section, "SURF_DIP_POS", r_val=dft_control%pos_dir_surf_dip)

       ! another logical variable, surf_dip_correct_switch, is introduced for

       ! implementation of "SURF_DIP_SWITCH" [SGh]

       dft_control%switch_surf_dip = .false.

       dft_control%surf_dip_correct_switch = dft_control%correct_surf_dip

       CALL section_vals_val_get(dft_section, "SURF_DIP_SWITCH", l_val=dft_control%switch_surf_dip)

       dft_control%correct_el_density_dip = .false.

       CALL section_vals_val_get(dft_section, "CORE_CORR_DIP", l_val=dft_control%correct_el_density_dip)

       IF (dft_control%correct_el_density_dip) THEN

          IF (dft_control%correct_surf_dip) THEN

             ! Do nothing, move on

          ELSE

             dft_control%correct_el_density_dip = .false.

             cpwarn("CORE_CORR_DIP keyword is activated only if SURFACE_DIPOLE_CORRECTION is TRUE")

          END IF

       END IF


       CALL section_vals_val_get(dft_section, "BASIS_SET_FILE_NAME", &

                                 c_val=basis_set_file_name)

       CALL section_vals_val_get(dft_section, "POTENTIAL_FILE_NAME", &

                                 c_val=potential_file_name)


       ! Read the input section

       tmp_section => section_vals_get_subs_vals(dft_section, "sic")

       CALL section_vals_val_get(tmp_section, "SIC_METHOD", &

                                 i_val=dft_control%sic_method_id)

       CALL section_vals_val_get(tmp_section, "ORBITAL_SET", &

                                 i_val=dft_control%sic_list_id)

       CALL section_vals_val_get(tmp_section, "SIC_SCALING_A", &

                                 r_val=dft_control%sic_scaling_a)

       CALL section_vals_val_get(tmp_section, "SIC_SCALING_B", &

                                 r_val=dft_control%sic_scaling_b)


       ! Determine if this is a TDDFPT run

       CALL section_vals_val_get(dft_section, "EXCITATIONS", i_val=excitations)

       dft_control%do_tddfpt_calculation = (excitations == tddfpt_excitations)

       IF (dft_control%do_tddfpt_calculation) THEN

          CALL tddfpt_control_create(dft_control%tddfpt_control)

       END IF


       do_rtp = .false.

       tmp_section => section_vals_get_subs_vals(dft_section, "REAL_TIME_PROPAGATION")

       CALL section_vals_get(tmp_section, explicit=is_present)

       IF (is_present) THEN

          CALL read_rtp_section(dft_control, tmp_section)

          do_rtp = .true.

       END IF


       ! Read the input section

       tmp_section => section_vals_get_subs_vals(dft_section, "XAS")

       CALL section_vals_get(tmp_section, explicit=dft_control%do_xas_calculation)

       IF (dft_control%do_xas_calculation) THEN

          ! Override with section parameter

          CALL section_vals_val_get(tmp_section, "_SECTION_PARAMETERS_", &

                                    l_val=dft_control%do_xas_calculation)

       END IF


       tmp_section => section_vals_get_subs_vals(dft_section, "XAS_TDP")

       CALL section_vals_get(tmp_section, explicit=dft_control%do_xas_tdp_calculation)

       IF (dft_control%do_xas_tdp_calculation) THEN

          ! Override with section parameter

          CALL section_vals_val_get(tmp_section, "_SECTION_PARAMETERS_", &

                                    l_val=dft_control%do_xas_tdp_calculation)

       END IF


       ! Read the finite field input section

       dft_control%apply_efield = .false.

       dft_control%apply_efield_field = .false. !this is for RTP

       dft_control%apply_vector_potential = .false. !this is for RTP

       tmp_section => section_vals_get_subs_vals(dft_section, "EFIELD")

       CALL section_vals_get(tmp_section, n_repetition=nrep, explicit=is_present)

       IF (is_present) THEN

          ALLOCATE (dft_control%efield_fields(nrep))

          CALL read_efield_sections(dft_control, tmp_section)

          IF (do_rtp) THEN

             IF (.NOT. dft_control%rtp_control%velocity_gauge) THEN

                dft_control%apply_efield_field = .true.

             ELSE

                dft_control%apply_vector_potential = .true.

                ! Use this input value of vector potential to (re)start RTP

                dft_control%rtp_control%vec_pot = dft_control%efield_fields(1)%efield%vec_pot_initial

             END IF

          ELSE

             dft_control%apply_efield = .true.

             cpassert(nrep == 1)

          END IF

       END IF


       ! Read the finite field input section for periodic fields

       tmp_section => section_vals_get_subs_vals(dft_section, "PERIODIC_EFIELD")

       CALL section_vals_get(tmp_section, explicit=dft_control%apply_period_efield)

       IF (dft_control%apply_period_efield) THEN

          ALLOCATE (dft_control%period_efield)

          CALL section_vals_val_get(tmp_section, "POLARISATION", r_vals=pol)

          dft_control%period_efield%polarisation(1:3) = pol(1:3)

          CALL section_vals_val_get(tmp_section, "D_FILTER", r_vals=pol)

          dft_control%period_efield%d_filter(1:3) = pol(1:3)

          CALL section_vals_val_get(tmp_section, "INTENSITY", &

                                    r_val=dft_control%period_efield%strength)

          dft_control%period_efield%displacement_field = .false.

          CALL section_vals_val_get(tmp_section, "DISPLACEMENT_FIELD", &

                                    l_val=dft_control%period_efield%displacement_field)

          ! periodic fields don't work with RTP

          cpassert(.NOT. do_rtp)

          IF (dft_control%period_efield%displacement_field) THEN

             CALL cite_reference(stengel2009)

          ELSE

             CALL cite_reference(souza2002)

             CALL cite_reference(umari2002)

          END IF

       END IF


       ! Read the external potential input section

       tmp_section => section_vals_get_subs_vals(dft_section, "EXTERNAL_POTENTIAL")

       CALL section_vals_get(tmp_section, explicit=dft_control%apply_external_potential)

       IF (dft_control%apply_external_potential) THEN

          CALL expot_control_create(dft_control%expot_control)

          CALL section_vals_val_get(tmp_section, "READ_FROM_CUBE", &

                                    l_val=dft_control%expot_control%read_from_cube)

          CALL section_vals_val_get(tmp_section, "STATIC", &

                                    l_val=dft_control%expot_control%static)

          CALL section_vals_val_get(tmp_section, "SCALING_FACTOR", &

                                    r_val=dft_control%expot_control%scaling_factor)

          ! External potential using Maxwell equation

          maxwell_section => section_vals_get_subs_vals(tmp_section, "MAXWELL")

          CALL section_vals_get(maxwell_section, explicit=is_present)

          IF (is_present) THEN

             dft_control%expot_control%maxwell_solver = .true.

             CALL maxwell_control_create(dft_control%maxwell_control)

             ! read the input values from Maxwell section

             CALL section_vals_val_get(maxwell_section, "TEST_REAL", &

                                       r_val=dft_control%maxwell_control%real_test)

             CALL section_vals_val_get(maxwell_section, "TEST_INTEGER", &

                                       i_val=dft_control%maxwell_control%int_test)

             CALL section_vals_val_get(maxwell_section, "TEST_LOGICAL", &

                                       l_val=dft_control%maxwell_control%log_test)

          ELSE

             dft_control%expot_control%maxwell_solver = .false.

          END IF

       END IF


       ! Read the SCCS input section if present

       sccs_section => section_vals_get_subs_vals(dft_section, "SCCS")

       CALL section_vals_get(sccs_section, explicit=is_present)

       IF (is_present) THEN

          ! Check section parameter if SCCS is activated

          CALL section_vals_val_get(sccs_section, "_SECTION_PARAMETERS_", &

                                    l_val=dft_control%do_sccs)

          IF (dft_control%do_sccs) THEN

             ALLOCATE (dft_control%sccs_control)

             CALL section_vals_val_get(sccs_section, "RELATIVE_PERMITTIVITY", &

                                       r_val=dft_control%sccs_control%epsilon_solvent)

             CALL section_vals_val_get(sccs_section, "ALPHA", &

                                       r_val=dft_control%sccs_control%alpha_solvent)

             CALL section_vals_val_get(sccs_section, "BETA", &

                                       r_val=dft_control%sccs_control%beta_solvent)

             CALL section_vals_val_get(sccs_section, "DELTA_RHO", &

                                       r_val=dft_control%sccs_control%delta_rho)

             CALL section_vals_val_get(sccs_section, "DERIVATIVE_METHOD", &

                                       i_val=dft_control%sccs_control%derivative_method)

             CALL section_vals_val_get(sccs_section, "METHOD", &

                                       i_val=dft_control%sccs_control%method_id)

             CALL section_vals_val_get(sccs_section, "EPS_SCCS", &

                                       r_val=dft_control%sccs_control%eps_sccs)

             CALL section_vals_val_get(sccs_section, "EPS_SCF", &

                                       r_val=dft_control%sccs_control%eps_scf)

             CALL section_vals_val_get(sccs_section, "GAMMA", &

                                       r_val=dft_control%sccs_control%gamma_solvent)

             CALL section_vals_val_get(sccs_section, "MAX_ITER", &

                                       i_val=dft_control%sccs_control%max_iter)

             CALL section_vals_val_get(sccs_section, "MIXING", &

                                       r_val=dft_control%sccs_control%mixing)

             SELECT CASE (dft_control%sccs_control%method_id)

             CASE (sccs_andreussi)

                tmp_section => section_vals_get_subs_vals(sccs_section, "ANDREUSSI")

                CALL section_vals_val_get(tmp_section, "RHO_MAX", &

                                          r_val=dft_control%sccs_control%rho_max)

                CALL section_vals_val_get(tmp_section, "RHO_MIN", &

                                          r_val=dft_control%sccs_control%rho_min)

                IF (dft_control%sccs_control%rho_max < dft_control%sccs_control%rho_min) THEN

                   CALL cp_abort(__location__, &

                                 "The SCCS parameter RHO_MAX is smaller than RHO_MIN. "// &

                                 "Please, check your input!")

                END IF

                CALL cite_reference(andreussi2012)

             CASE (sccs_fattebert_gygi)

                tmp_section => section_vals_get_subs_vals(sccs_section, "FATTEBERT-GYGI")

                CALL section_vals_val_get(tmp_section, "BETA", &

                                          r_val=dft_control%sccs_control%beta)

                IF (dft_control%sccs_control%beta < 0.5_dp) THEN

                   CALL cp_abort(__location__, &

                                 "A value smaller than 0.5 for the SCCS parameter beta "// &

                                 "causes numerical problems. Please, check your input!")

                END IF

                CALL section_vals_val_get(tmp_section, "RHO_ZERO", &

                                          r_val=dft_control%sccs_control%rho_zero)

                CALL cite_reference(fattebert2002)

             CASE DEFAULT

                cpabort("Invalid SCCS model specified. Please, check your input!")

             END SELECT

             CALL cite_reference(yin2017)

          END IF

       END IF


       ! ZMP added input sections

       ! Read the external density input section

       tmp_section => section_vals_get_subs_vals(dft_section, "EXTERNAL_DENSITY")

       CALL section_vals_get(tmp_section, explicit=dft_control%apply_external_density)


       ! Read the external vxc input section

       tmp_section => section_vals_get_subs_vals(dft_section, "EXTERNAL_VXC")

       CALL section_vals_get(tmp_section, explicit=dft_control%apply_external_vxc)


    END SUBROUTINE read_dft_control


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

 !> \brief ...

 !> \param qs_control ...

 !> \param dft_section ...

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

    SUBROUTINE read_mgrid_section(qs_control, dft_section)


       TYPE(qs_control_type), INTENT(INOUT)               :: qs_control

       TYPE(section_vals_type), POINTER                   :: dft_section


       CHARACTER(len=*), PARAMETER :: routinen = 'read_mgrid_section'


       INTEGER                                            :: handle, igrid_level, ngrid_level

       LOGICAL                                            :: explicit, multigrid_set

       REAL(dp)                                           :: cutoff

       REAL(dp), DIMENSION(:), POINTER                    :: cutofflist

       TYPE(section_vals_type), POINTER                   :: mgrid_section


       CALL timeset(routinen, handle)


       NULLIFY (mgrid_section, cutofflist)

       mgrid_section => section_vals_get_subs_vals(dft_section, "MGRID")


       CALL section_vals_val_get(mgrid_section, "NGRIDS", i_val=ngrid_level)

       CALL section_vals_val_get(mgrid_section, "MULTIGRID_SET", l_val=multigrid_set)

       CALL section_vals_val_get(mgrid_section, "CUTOFF", r_val=cutoff)

       CALL section_vals_val_get(mgrid_section, "PROGRESSION_FACTOR", r_val=qs_control%progression_factor)

       CALL section_vals_val_get(mgrid_section, "COMMENSURATE", l_val=qs_control%commensurate_mgrids)

       CALL section_vals_val_get(mgrid_section, "REALSPACE", l_val=qs_control%realspace_mgrids)

       CALL section_vals_val_get(mgrid_section, "REL_CUTOFF", r_val=qs_control%relative_cutoff)

       CALL section_vals_val_get(mgrid_section, "SKIP_LOAD_BALANCE_DISTRIBUTED", &

                                 l_val=qs_control%skip_load_balance_distributed)


       ! For SE and DFTB possibly override with new defaults

       IF (qs_control%semi_empirical .OR. qs_control%dftb .OR. qs_control%xtb) THEN

          ngrid_level = 1

          multigrid_set = .false.

          ! Override default cutoff value unless user specified an explicit argument..

          CALL section_vals_val_get(mgrid_section, "CUTOFF", explicit=explicit, r_val=cutoff)

          IF (.NOT. explicit) cutoff = 1.0_dp

       END IF


       ALLOCATE (qs_control%e_cutoff(ngrid_level))

       qs_control%cutoff = cutoff


       IF (multigrid_set) THEN

          ! Read the values from input

          IF (qs_control%commensurate_mgrids) THEN

             cpabort("Do not specify cutoffs for the commensurate grids (NYI)")

          END IF


          CALL section_vals_val_get(mgrid_section, "MULTIGRID_CUTOFF", r_vals=cutofflist)

          IF (ASSOCIATED(cutofflist)) THEN

             IF (SIZE(cutofflist, 1) /= ngrid_level) THEN

                cpabort("Number of multi-grids requested and number of cutoff values do not match")

             END IF

             DO igrid_level = 1, ngrid_level

                qs_control%e_cutoff(igrid_level) = cutofflist(igrid_level)

             END DO

          END IF

          ! set cutoff to smallest value in multgrid available with >= cutoff

          DO igrid_level = ngrid_level, 1, -1

             IF (qs_control%cutoff <= qs_control%e_cutoff(igrid_level)) THEN

                qs_control%cutoff = qs_control%e_cutoff(igrid_level)

                EXIT

             END IF

             ! set largest grid value to cutoff

             IF (igrid_level == 1) THEN

                qs_control%cutoff = qs_control%e_cutoff(1)

             END IF

          END DO

       ELSE

          IF (qs_control%commensurate_mgrids) qs_control%progression_factor = 4.0_dp

          qs_control%e_cutoff(1) = qs_control%cutoff

          DO igrid_level = 2, ngrid_level

             qs_control%e_cutoff(igrid_level) = qs_control%e_cutoff(igrid_level - 1)/ &

                                                qs_control%progression_factor

          END DO

       END IF

       ! check that multigrids are ordered

       DO igrid_level = 2, ngrid_level

          IF (qs_control%e_cutoff(igrid_level) > qs_control%e_cutoff(igrid_level - 1)) THEN

             cpabort("The cutoff values for the multi-grids are not ordered from large to small")

          ELSE IF (qs_control%e_cutoff(igrid_level) == qs_control%e_cutoff(igrid_level - 1)) THEN

             cpabort("The same cutoff value was specified for two multi-grids")

          END IF

       END DO

       CALL timestop(handle)

    END SUBROUTINE read_mgrid_section


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

 !> \brief ...

 !> \param qs_control ...

 !> \param qs_section ...

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

    SUBROUTINE read_qs_section(qs_control, qs_section)


       TYPE(qs_control_type), INTENT(INOUT)               :: qs_control

       TYPE(section_vals_type), POINTER                   :: qs_section


       CHARACTER(len=*), PARAMETER                        :: routinen = 'read_qs_section'


       CHARACTER(LEN=default_string_length), &

          DIMENSION(:), POINTER                           :: clist

       INTEGER                                            :: handle, itmp, j, jj, k, n_rep, n_var, &

                                                             ngauss, ngp, nrep

       INTEGER, DIMENSION(:), POINTER                     :: tmplist

       LOGICAL                                            :: explicit, was_present

       REAL(dp)                                           :: tmp, tmpsqrt, value

       REAL(dp), POINTER                                  :: scal(:)

       TYPE(section_vals_type), POINTER :: cdft_control_section, ddapc_restraint_section, &

          dftb_parameter, dftb_section, genpot_section, lri_optbas_section, mull_section, &

          nonbonded_section, s2_restraint_section, se_section, xtb_parameter, xtb_section


       CALL timeset(routinen, handle)


       was_present = .false.

       NULLIFY (mull_section, ddapc_restraint_section, s2_restraint_section, &

                se_section, dftb_section, xtb_section, dftb_parameter, xtb_parameter, lri_optbas_section, &

                cdft_control_section, genpot_section)


       mull_section => section_vals_get_subs_vals(qs_section, "MULLIKEN_RESTRAINT")

       ddapc_restraint_section => section_vals_get_subs_vals(qs_section, "DDAPC_RESTRAINT")

       s2_restraint_section => section_vals_get_subs_vals(qs_section, "S2_RESTRAINT")

       se_section => section_vals_get_subs_vals(qs_section, "SE")

       dftb_section => section_vals_get_subs_vals(qs_section, "DFTB")

       xtb_section => section_vals_get_subs_vals(qs_section, "xTB")

       dftb_parameter => section_vals_get_subs_vals(dftb_section, "PARAMETER")

       xtb_parameter => section_vals_get_subs_vals(xtb_section, "PARAMETER")

       lri_optbas_section => section_vals_get_subs_vals(qs_section, "OPTIMIZE_LRI_BASIS")

       cdft_control_section => section_vals_get_subs_vals(qs_section, "CDFT")

       nonbonded_section => section_vals_get_subs_vals(xtb_section, "NONBONDED")

       genpot_section => section_vals_get_subs_vals(nonbonded_section, "GENPOT")


       ! Setup all defaults values and overwrite input parameters

       ! EPS_DEFAULT should set the target accuracy in the total energy (~per electron) or a closely related value

       CALL section_vals_val_get(qs_section, "EPS_DEFAULT", r_val=value)

       tmpsqrt = sqrt(value) ! a trick to work around a NAG 5.1 optimizer bug


       ! random choice ?

       qs_control%eps_core_charge = value/100.0_dp

       ! correct if all Gaussians would have the same radius (overlap will be smaller than eps_pgf_orb**2).

       ! Can be significantly in error if not... requires fully new screening/pairlist procedures

       qs_control%eps_pgf_orb = tmpsqrt

       qs_control%eps_kg_orb = qs_control%eps_pgf_orb

       ! consistent since also a kind of overlap

       qs_control%eps_ppnl = qs_control%eps_pgf_orb/100.0_dp

       ! accuracy is basically set by the overlap, this sets an empirical shift

       qs_control%eps_ppl = 1.0e-2_dp

       !

       qs_control%gapw_control%eps_cpc = value

       ! expexted error in the density

       qs_control%eps_rho_gspace = value

       qs_control%eps_rho_rspace = value

       ! error in the gradient, can be the sqrt of the error in the energy, ignored if map_consistent

       qs_control%eps_gvg_rspace = tmpsqrt

       !

       CALL section_vals_val_get(qs_section, "EPS_CORE_CHARGE", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_CORE_CHARGE", r_val=qs_control%eps_core_charge)

       END IF

       CALL section_vals_val_get(qs_section, "EPS_GVG_RSPACE", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_GVG_RSPACE", r_val=qs_control%eps_gvg_rspace)

       END IF

       CALL section_vals_val_get(qs_section, "EPS_PGF_ORB", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_PGF_ORB", r_val=qs_control%eps_pgf_orb)

       END IF

       CALL section_vals_val_get(qs_section, "EPS_KG_ORB", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_KG_ORB", r_val=tmp)

          qs_control%eps_kg_orb = sqrt(tmp)

       END IF

       CALL section_vals_val_get(qs_section, "EPS_PPL", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_PPL", r_val=qs_control%eps_ppl)

       END IF

       CALL section_vals_val_get(qs_section, "EPS_PPNL", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_PPNL", r_val=qs_control%eps_ppnl)

       END IF

       CALL section_vals_val_get(qs_section, "EPS_RHO", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_RHO", r_val=qs_control%eps_rho_gspace)

          qs_control%eps_rho_rspace = qs_control%eps_rho_gspace

       END IF

       CALL section_vals_val_get(qs_section, "EPS_RHO_RSPACE", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_RHO_RSPACE", r_val=qs_control%eps_rho_rspace)

       END IF

       CALL section_vals_val_get(qs_section, "EPS_RHO_GSPACE", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_RHO_GSPACE", r_val=qs_control%eps_rho_gspace)

       END IF

       CALL section_vals_val_get(qs_section, "EPS_FILTER_MATRIX", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_FILTER_MATRIX", r_val=qs_control%eps_filter_matrix)

       END IF

       CALL section_vals_val_get(qs_section, "EPS_CPC", n_rep_val=n_rep)

       IF (n_rep /= 0) THEN

          CALL section_vals_val_get(qs_section, "EPS_CPC", r_val=qs_control%gapw_control%eps_cpc)

       END IF


       CALL section_vals_val_get(qs_section, "EPSFIT", r_val=qs_control%gapw_control%eps_fit)

       CALL section_vals_val_get(qs_section, "EPSISO", r_val=qs_control%gapw_control%eps_iso)

       CALL section_vals_val_get(qs_section, "EPSSVD", r_val=qs_control%gapw_control%eps_svd)

       CALL section_vals_val_get(qs_section, "EPSRHO0", r_val=qs_control%gapw_control%eps_Vrho0)

       CALL section_vals_val_get(qs_section, "ALPHA0_HARD", r_val=qs_control%gapw_control%alpha0_hard)

       qs_control%gapw_control%lrho1_eq_lrho0 = .false.

       qs_control%gapw_control%alpha0_hard_from_input = .false.

       IF (qs_control%gapw_control%alpha0_hard /= 0.0_dp) qs_control%gapw_control%alpha0_hard_from_input = .true.

       CALL section_vals_val_get(qs_section, "FORCE_PAW", l_val=qs_control%gapw_control%force_paw)

       CALL section_vals_val_get(qs_section, "MAX_RAD_LOCAL", r_val=qs_control%gapw_control%max_rad_local)


       CALL section_vals_val_get(qs_section, "MIN_PAIR_LIST_RADIUS", r_val=qs_control%pairlist_radius)


       CALL section_vals_val_get(qs_section, "LS_SCF", l_val=qs_control%do_ls_scf)

       CALL section_vals_val_get(qs_section, "ALMO_SCF", l_val=qs_control%do_almo_scf)

       CALL section_vals_val_get(qs_section, "KG_METHOD", l_val=qs_control%do_kg)


       ! Logicals

       CALL section_vals_val_get(qs_section, "REF_EMBED_SUBSYS", l_val=qs_control%ref_embed_subsys)

       CALL section_vals_val_get(qs_section, "CLUSTER_EMBED_SUBSYS", l_val=qs_control%cluster_embed_subsys)

       CALL section_vals_val_get(qs_section, "HIGH_LEVEL_EMBED_SUBSYS", l_val=qs_control%high_level_embed_subsys)

       CALL section_vals_val_get(qs_section, "DFET_EMBEDDED", l_val=qs_control%dfet_embedded)

       CALL section_vals_val_get(qs_section, "DMFET_EMBEDDED", l_val=qs_control%dmfet_embedded)


       ! Integers gapw

       CALL section_vals_val_get(qs_section, "LMAXN1", i_val=qs_control%gapw_control%lmax_sphere)

       CALL section_vals_val_get(qs_section, "LMAXN0", i_val=qs_control%gapw_control%lmax_rho0)

       CALL section_vals_val_get(qs_section, "LADDN0", i_val=qs_control%gapw_control%ladd_rho0)

       CALL section_vals_val_get(qs_section, "QUADRATURE", i_val=qs_control%gapw_control%quadrature)

       ! GAPW 1c basis

       CALL section_vals_val_get(qs_section, "GAPW_1C_BASIS", i_val=qs_control%gapw_control%basis_1c)

       IF (qs_control%gapw_control%basis_1c /= gapw_1c_orb) THEN

          qs_control%gapw_control%eps_svd = max(qs_control%gapw_control%eps_svd, 1.e-12_dp)

       END IF


       ! Integers grids

       CALL section_vals_val_get(qs_section, "PW_GRID", i_val=itmp)

       SELECT CASE (itmp)

       CASE (do_pwgrid_spherical)

          qs_control%pw_grid_opt%spherical = .true.

          qs_control%pw_grid_opt%fullspace = .false.

       CASE (do_pwgrid_ns_fullspace)

          qs_control%pw_grid_opt%spherical = .false.

          qs_control%pw_grid_opt%fullspace = .true.

       CASE (do_pwgrid_ns_halfspace)

          qs_control%pw_grid_opt%spherical = .false.

          qs_control%pw_grid_opt%fullspace = .false.

       END SELECT


       !   Method for PPL calculation

       CALL section_vals_val_get(qs_section, "CORE_PPL", i_val=itmp)

       qs_control%do_ppl_method = itmp


       CALL section_vals_val_get(qs_section, "PW_GRID_LAYOUT", i_vals=tmplist)

       qs_control%pw_grid_opt%distribution_layout = tmplist

       CALL section_vals_val_get(qs_section, "PW_GRID_BLOCKED", i_val=qs_control%pw_grid_opt%blocked)


       !Integers extrapolation

       CALL section_vals_val_get(qs_section, "EXTRAPOLATION", i_val=qs_control%wf_interpolation_method_nr)

       CALL section_vals_val_get(qs_section, "EXTRAPOLATION_ORDER", i_val=qs_control%wf_extrapolation_order)


       !Method

       CALL section_vals_val_get(qs_section, "METHOD", i_val=qs_control%method_id)

       qs_control%gapw = .false.

       qs_control%gapw_xc = .false.

       qs_control%gpw = .false.

       qs_control%pao = .false.

       qs_control%dftb = .false.

       qs_control%xtb = .false.

       qs_control%semi_empirical = .false.

       qs_control%ofgpw = .false.

       qs_control%lrigpw = .false.

       qs_control%rigpw = .false.

       SELECT CASE (qs_control%method_id)

       CASE (do_method_gapw)

          CALL cite_reference(lippert1999)

          CALL cite_reference(krack2000)

          qs_control%gapw = .true.

       CASE (do_method_gapw_xc)

          qs_control%gapw_xc = .true.

       CASE (do_method_gpw)

          CALL cite_reference(lippert1997)

          CALL cite_reference(vandevondele2005a)

          qs_control%gpw = .true.

       CASE (do_method_ofgpw)

          qs_control%ofgpw = .true.

       CASE (do_method_lrigpw)

          qs_control%lrigpw = .true.

       CASE (do_method_rigpw)

          qs_control%rigpw = .true.

       CASE (do_method_dftb)

          qs_control%dftb = .true.

          CALL cite_reference(porezag1995)

          CALL cite_reference(seifert1996)

       CASE (do_method_xtb)

          qs_control%xtb = .true.

          CALL cite_reference(grimme2017)

       CASE (do_method_mndo)

          CALL cite_reference(dewar1977)

          qs_control%semi_empirical = .true.

       CASE (do_method_am1)

          CALL cite_reference(dewar1985)

          qs_control%semi_empirical = .true.

       CASE (do_method_pm3)

          CALL cite_reference(stewart1989)

          qs_control%semi_empirical = .true.

       CASE (do_method_pnnl)

          CALL cite_reference(schenter2008)

          qs_control%semi_empirical = .true.

       CASE (do_method_pm6)

          CALL cite_reference(stewart2007)

          qs_control%semi_empirical = .true.

       CASE (do_method_pm6fm)

          CALL cite_reference(vanvoorhis2015)

          qs_control%semi_empirical = .true.

       CASE (do_method_pdg)

          CALL cite_reference(repasky2002)

          qs_control%semi_empirical = .true.

       CASE (do_method_rm1)

          CALL cite_reference(rocha2006)

          qs_control%semi_empirical = .true.

       CASE (do_method_mndod)

          CALL cite_reference(dewar1977)

          CALL cite_reference(thiel1992)

          qs_control%semi_empirical = .true.

       END SELECT


       CALL section_vals_get(mull_section, explicit=qs_control%mulliken_restraint)


       IF (qs_control%mulliken_restraint) THEN

          CALL section_vals_val_get(mull_section, "STRENGTH", r_val=qs_control%mulliken_restraint_control%strength)

          CALL section_vals_val_get(mull_section, "TARGET", r_val=qs_control%mulliken_restraint_control%target)

          CALL section_vals_val_get(mull_section, "ATOMS", n_rep_val=n_rep)

          jj = 0

          DO k = 1, n_rep

             CALL section_vals_val_get(mull_section, "ATOMS", i_rep_val=k, i_vals=tmplist)

             jj = jj + SIZE(tmplist)

          END DO

          qs_control%mulliken_restraint_control%natoms = jj

          IF (qs_control%mulliken_restraint_control%natoms < 1) &

             cpabort("Need at least 1 atom to use mulliken constraints")

          ALLOCATE (qs_control%mulliken_restraint_control%atoms(qs_control%mulliken_restraint_control%natoms))

          jj = 0

          DO k = 1, n_rep

             CALL section_vals_val_get(mull_section, "ATOMS", i_rep_val=k, i_vals=tmplist)

             DO j = 1, SIZE(tmplist)

                jj = jj + 1

                qs_control%mulliken_restraint_control%atoms(jj) = tmplist(j)

             END DO

          END DO

       END IF

       CALL section_vals_get(ddapc_restraint_section, n_repetition=nrep, explicit=qs_control%ddapc_restraint)

       IF (qs_control%ddapc_restraint) THEN

          ALLOCATE (qs_control%ddapc_restraint_control(nrep))

          CALL read_ddapc_section(qs_control, qs_section=qs_section)

          qs_control%ddapc_restraint_is_spin = .false.

          qs_control%ddapc_explicit_potential = .false.

       END IF


       CALL section_vals_get(s2_restraint_section, explicit=qs_control%s2_restraint)

       IF (qs_control%s2_restraint) THEN

          CALL section_vals_val_get(s2_restraint_section, "STRENGTH", &

                                    r_val=qs_control%s2_restraint_control%strength)

          CALL section_vals_val_get(s2_restraint_section, "TARGET", &

                                    r_val=qs_control%s2_restraint_control%target)

          CALL section_vals_val_get(s2_restraint_section, "FUNCTIONAL_FORM", &

                                    i_val=qs_control%s2_restraint_control%functional_form)

       END IF


       CALL section_vals_get(cdft_control_section, explicit=qs_control%cdft)

       IF (qs_control%cdft) THEN

          CALL read_cdft_control_section(qs_control, cdft_control_section)

       END IF


       ! Semi-empirical code

       IF (qs_control%semi_empirical) THEN

          CALL section_vals_val_get(se_section, "ORTHOGONAL_BASIS", &

                                    l_val=qs_control%se_control%orthogonal_basis)

          CALL section_vals_val_get(se_section, "DELTA", &

                                    r_val=qs_control%se_control%delta)

          CALL section_vals_val_get(se_section, "ANALYTICAL_GRADIENTS", &

                                    l_val=qs_control%se_control%analytical_gradients)

          CALL section_vals_val_get(se_section, "FORCE_KDSO-D_EXCHANGE", &

                                    l_val=qs_control%se_control%force_kdsod_EX)

          ! Integral Screening

          CALL section_vals_val_get(se_section, "INTEGRAL_SCREENING", &

                                    i_val=qs_control%se_control%integral_screening)

          IF (qs_control%method_id == do_method_pnnl) THEN

             IF (qs_control%se_control%integral_screening /= do_se_is_slater) &

                CALL cp_warn(__location__, &

                             "PNNL semi-empirical parameterization supports only the Slater type "// &

                             "integral scheme. Revert to Slater and continue the calculation.")

             qs_control%se_control%integral_screening = do_se_is_slater

          END IF

          ! Global Arrays variable

          CALL section_vals_val_get(se_section, "GA%NCELLS", &

                                    i_val=qs_control%se_control%ga_ncells)

          ! Long-Range correction

          CALL section_vals_val_get(se_section, "LR_CORRECTION%CUTOFF", &

                                    r_val=qs_control%se_control%cutoff_lrc)

          qs_control%se_control%taper_lrc = qs_control%se_control%cutoff_lrc

          CALL section_vals_val_get(se_section, "LR_CORRECTION%RC_TAPER", &

                                    explicit=explicit)

          IF (explicit) THEN

             CALL section_vals_val_get(se_section, "LR_CORRECTION%RC_TAPER", &

                                       r_val=qs_control%se_control%taper_lrc)

          END IF

          CALL section_vals_val_get(se_section, "LR_CORRECTION%RC_RANGE", &

                                    r_val=qs_control%se_control%range_lrc)

          ! Coulomb

          CALL section_vals_val_get(se_section, "COULOMB%CUTOFF", &

                                    r_val=qs_control%se_control%cutoff_cou)

          qs_control%se_control%taper_cou = qs_control%se_control%cutoff_cou

          CALL section_vals_val_get(se_section, "COULOMB%RC_TAPER", &

                                    explicit=explicit)

          IF (explicit) THEN

             CALL section_vals_val_get(se_section, "COULOMB%RC_TAPER", &

                                       r_val=qs_control%se_control%taper_cou)

          END IF

          CALL section_vals_val_get(se_section, "COULOMB%RC_RANGE", &

                                    r_val=qs_control%se_control%range_cou)

          ! Exchange

          CALL section_vals_val_get(se_section, "EXCHANGE%CUTOFF", &

                                    r_val=qs_control%se_control%cutoff_exc)

          qs_control%se_control%taper_exc = qs_control%se_control%cutoff_exc

          CALL section_vals_val_get(se_section, "EXCHANGE%RC_TAPER", &

                                    explicit=explicit)

          IF (explicit) THEN

             CALL section_vals_val_get(se_section, "EXCHANGE%RC_TAPER", &

                                       r_val=qs_control%se_control%taper_exc)

          END IF

          CALL section_vals_val_get(se_section, "EXCHANGE%RC_RANGE", &

                                    r_val=qs_control%se_control%range_exc)

          ! Screening (only if the integral scheme is of dumped type)

          IF (qs_control%se_control%integral_screening == do_se_is_kdso_d) THEN

             CALL section_vals_val_get(se_section, "SCREENING%RC_TAPER", &

                                       r_val=qs_control%se_control%taper_scr)

             CALL section_vals_val_get(se_section, "SCREENING%RC_RANGE", &

                                       r_val=qs_control%se_control%range_scr)

          END IF

          ! Periodic Type Calculation

          CALL section_vals_val_get(se_section, "PERIODIC", &

                                    i_val=qs_control%se_control%periodic_type)

          SELECT CASE (qs_control%se_control%periodic_type)

          CASE (do_se_lr_none)

             qs_control%se_control%do_ewald = .false.

             qs_control%se_control%do_ewald_r3 = .false.

             qs_control%se_control%do_ewald_gks = .false.

          CASE (do_se_lr_ewald)

             qs_control%se_control%do_ewald = .true.

             qs_control%se_control%do_ewald_r3 = .false.

             qs_control%se_control%do_ewald_gks = .false.

          CASE (do_se_lr_ewald_gks)

             qs_control%se_control%do_ewald = .false.

             qs_control%se_control%do_ewald_r3 = .false.

             qs_control%se_control%do_ewald_gks = .true.

             IF (qs_control%method_id /= do_method_pnnl) &

                CALL cp_abort(__location__, &

                              "A periodic semi-empirical calculation was requested with a long-range  "// &

                              "summation on the single integral evaluation. This scheme is supported  "// &

                              "only by the PNNL parameterization.")

          CASE (do_se_lr_ewald_r3)

             qs_control%se_control%do_ewald = .true.

             qs_control%se_control%do_ewald_r3 = .true.

             qs_control%se_control%do_ewald_gks = .false.

             IF (qs_control%se_control%integral_screening /= do_se_is_kdso) &

                CALL cp_abort(__location__, &

                              "A periodic semi-empirical calculation was requested with a long-range  "// &

                              "summation for the slowly convergent part 1/R^3, which is not congruent "// &

                              "with the integral screening chosen. The only integral screening supported "// &

                              "by this periodic type calculation is the standard Klopman-Dewar-Sabelli-Ohno.")

          END SELECT


          ! dispersion pair potentials

          CALL section_vals_val_get(se_section, "DISPERSION", &

                                    l_val=qs_control%se_control%dispersion)

          CALL section_vals_val_get(se_section, "DISPERSION_RADIUS", &

                                    r_val=qs_control%se_control%rcdisp)

          CALL section_vals_val_get(se_section, "COORDINATION_CUTOFF", &

                                    r_val=qs_control%se_control%epscn)

          CALL section_vals_val_get(se_section, "D3_SCALING", r_vals=scal)

          qs_control%se_control%sd3(1) = scal(1)

          qs_control%se_control%sd3(2) = scal(2)

          qs_control%se_control%sd3(3) = scal(3)

          CALL section_vals_val_get(se_section, "DISPERSION_PARAMETER_FILE", &

                                    c_val=qs_control%se_control%dispersion_parameter_file)


          ! Stop the execution for non-implemented features

          IF (qs_control%se_control%periodic_type == do_se_lr_ewald_r3) THEN

             cpabort("EWALD_R3 not implemented yet!")

          END IF


          IF (qs_control%method_id == do_method_mndo .OR. &

              qs_control%method_id == do_method_am1 .OR. &

              qs_control%method_id == do_method_mndod .OR. &

              qs_control%method_id == do_method_pdg .OR. &

              qs_control%method_id == do_method_pm3 .OR. &

              qs_control%method_id == do_method_pm6 .OR. &

              qs_control%method_id == do_method_pm6fm .OR. &

              qs_control%method_id == do_method_pnnl .OR. &

              qs_control%method_id == do_method_rm1) THEN

             qs_control%se_control%orthogonal_basis = .true.

          END IF

       END IF


       ! DFTB code

       IF (qs_control%dftb) THEN

          CALL section_vals_val_get(dftb_section, "ORTHOGONAL_BASIS", &

                                    l_val=qs_control%dftb_control%orthogonal_basis)

          CALL section_vals_val_get(dftb_section, "SELF_CONSISTENT", &

                                    l_val=qs_control%dftb_control%self_consistent)

          CALL section_vals_val_get(dftb_section, "DISPERSION", &

                                    l_val=qs_control%dftb_control%dispersion)

          CALL section_vals_val_get(dftb_section, "DIAGONAL_DFTB3", &

                                    l_val=qs_control%dftb_control%dftb3_diagonal)

          CALL section_vals_val_get(dftb_section, "HB_SR_GAMMA", &

                                    l_val=qs_control%dftb_control%hb_sr_damp)

          CALL section_vals_val_get(dftb_section, "EPS_DISP", &

                                    r_val=qs_control%dftb_control%eps_disp)

          CALL section_vals_val_get(dftb_section, "DO_EWALD", explicit=explicit)

          IF (explicit) THEN

             CALL section_vals_val_get(dftb_section, "DO_EWALD", &

                                       l_val=qs_control%dftb_control%do_ewald)

          ELSE

             qs_control%dftb_control%do_ewald = (qs_control%periodicity /= 0)

          END IF

          CALL section_vals_val_get(dftb_parameter, "PARAM_FILE_PATH", &

                                    c_val=qs_control%dftb_control%sk_file_path)

          CALL section_vals_val_get(dftb_parameter, "PARAM_FILE_NAME", &

                                    c_val=qs_control%dftb_control%sk_file_list)

          CALL section_vals_val_get(dftb_parameter, "HB_SR_PARAM", &

                                    r_val=qs_control%dftb_control%hb_sr_para)

          CALL section_vals_val_get(dftb_parameter, "SK_FILE", n_rep_val=n_var)

          ALLOCATE (qs_control%dftb_control%sk_pair_list(3, n_var))

          DO k = 1, n_var

             CALL section_vals_val_get(dftb_parameter, "SK_FILE", i_rep_val=k, &

                                       c_vals=clist)

             qs_control%dftb_control%sk_pair_list(1:3, k) = clist(1:3)

          END DO

          ! Dispersion type

          CALL section_vals_val_get(dftb_parameter, "DISPERSION_TYPE", &

                                    i_val=qs_control%dftb_control%dispersion_type)

          CALL section_vals_val_get(dftb_parameter, "UFF_FORCE_FIELD", &

                                    c_val=qs_control%dftb_control%uff_force_field)

          ! D3 Dispersion

          CALL section_vals_val_get(dftb_parameter, "DISPERSION_RADIUS", &

                                    r_val=qs_control%dftb_control%rcdisp)

          CALL section_vals_val_get(dftb_parameter, "COORDINATION_CUTOFF", &

                                    r_val=qs_control%dftb_control%epscn)

          CALL section_vals_val_get(dftb_parameter, "D2_EXP_PRE", &

                                    r_val=qs_control%dftb_control%exp_pre)

          CALL section_vals_val_get(dftb_parameter, "D2_SCALING", &

                                    r_val=qs_control%dftb_control%scaling)

          CALL section_vals_val_get(dftb_parameter, "D3_SCALING", r_vals=scal)

          qs_control%dftb_control%sd3(1) = scal(1)

          qs_control%dftb_control%sd3(2) = scal(2)

          qs_control%dftb_control%sd3(3) = scal(3)

          CALL section_vals_val_get(dftb_parameter, "D3BJ_SCALING", r_vals=scal)

          qs_control%dftb_control%sd3bj(1) = scal(1)

          qs_control%dftb_control%sd3bj(2) = scal(2)

          qs_control%dftb_control%sd3bj(3) = scal(3)

          qs_control%dftb_control%sd3bj(4) = scal(4)

          CALL section_vals_val_get(dftb_parameter, "DISPERSION_PARAMETER_FILE", &

                                    c_val=qs_control%dftb_control%dispersion_parameter_file)


          IF (qs_control%dftb_control%dispersion) CALL cite_reference(zhechkov2005)

          IF (qs_control%dftb_control%self_consistent) CALL cite_reference(elstner1998)

          IF (qs_control%dftb_control%hb_sr_damp) CALL cite_reference(hu2007)

       END IF


       ! xTB code

       IF (qs_control%xtb) THEN

          CALL section_vals_val_get(xtb_section, "DO_EWALD", explicit=explicit)

          IF (explicit) THEN

             CALL section_vals_val_get(xtb_section, "DO_EWALD", &

                                       l_val=qs_control%xtb_control%do_ewald)

          ELSE

             qs_control%xtb_control%do_ewald = (qs_control%periodicity /= 0)

          END IF

          CALL section_vals_val_get(xtb_section, "STO_NG", i_val=ngauss)

          qs_control%xtb_control%sto_ng = ngauss

          CALL section_vals_val_get(xtb_section, "HYDROGEN_STO_NG", i_val=ngauss)

          qs_control%xtb_control%h_sto_ng = ngauss

          CALL section_vals_val_get(xtb_parameter, "PARAM_FILE_PATH", &

                                    c_val=qs_control%xtb_control%parameter_file_path)

          CALL section_vals_val_get(xtb_parameter, "PARAM_FILE_NAME", &

                                    c_val=qs_control%xtb_control%parameter_file_name)

          ! D3 Dispersion

          CALL section_vals_val_get(xtb_parameter, "DISPERSION_RADIUS", &

                                    r_val=qs_control%xtb_control%rcdisp)

          CALL section_vals_val_get(xtb_parameter, "COORDINATION_CUTOFF", &

                                    r_val=qs_control%xtb_control%epscn)

          CALL section_vals_val_get(xtb_parameter, "D3BJ_SCALING", r_vals=scal)

          qs_control%xtb_control%s6 = scal(1)

          qs_control%xtb_control%s8 = scal(2)

          CALL section_vals_val_get(xtb_parameter, "D3BJ_PARAM", r_vals=scal)

          qs_control%xtb_control%a1 = scal(1)

          qs_control%xtb_control%a2 = scal(2)

          CALL section_vals_val_get(xtb_parameter, "DISPERSION_PARAMETER_FILE", &

                                    c_val=qs_control%xtb_control%dispersion_parameter_file)

          ! global parameters

          CALL section_vals_val_get(xtb_parameter, "HUCKEL_CONSTANTS", r_vals=scal)

          qs_control%xtb_control%ks = scal(1)

          qs_control%xtb_control%kp = scal(2)

          qs_control%xtb_control%kd = scal(3)

          qs_control%xtb_control%ksp = scal(4)

          qs_control%xtb_control%k2sh = scal(5)

          CALL section_vals_val_get(xtb_parameter, "COULOMB_CONSTANTS", r_vals=scal)

          qs_control%xtb_control%kg = scal(1)

          qs_control%xtb_control%kf = scal(2)

          CALL section_vals_val_get(xtb_parameter, "CN_CONSTANTS", r_vals=scal)

          qs_control%xtb_control%kcns = scal(1)

          qs_control%xtb_control%kcnp = scal(2)

          qs_control%xtb_control%kcnd = scal(3)

          CALL section_vals_val_get(xtb_parameter, "EN_CONSTANT", r_vals=scal)

          qs_control%xtb_control%ken = scal(1)

          ! XB

          CALL section_vals_val_get(xtb_section, "USE_HALOGEN_CORRECTION", &

                                    l_val=qs_control%xtb_control%xb_interaction)

          CALL section_vals_val_get(xtb_parameter, "HALOGEN_BINDING", r_vals=scal)

          qs_control%xtb_control%kxr = scal(1)

          qs_control%xtb_control%kx2 = scal(2)

          ! NONBONDED interactions

          CALL section_vals_val_get(xtb_section, "DO_NONBONDED", &

                                    l_val=qs_control%xtb_control%do_nonbonded)

          CALL section_vals_get(nonbonded_section, explicit=explicit)

          IF (explicit .AND. qs_control%xtb_control%do_nonbonded) THEN

             CALL section_vals_get(genpot_section, explicit=explicit, n_repetition=ngp)

             IF (explicit) THEN

                CALL pair_potential_reallocate(qs_control%xtb_control%nonbonded, 1, ngp, gp=.true.)

                CALL read_gp_section(qs_control%xtb_control%nonbonded, genpot_section, 0)

             END IF

          END IF !nonbonded

          ! SR Coulomb

          CALL section_vals_val_get(xtb_section, "OLD_COULOMB_DAMPING", &

                                    l_val=qs_control%xtb_control%old_coulomb_damping)

          CALL section_vals_val_get(xtb_parameter, "COULOMB_SR_CUT", r_vals=scal)

          qs_control%xtb_control%coulomb_sr_cut = scal(1)

          CALL section_vals_val_get(xtb_parameter, "COULOMB_SR_EPS", r_vals=scal)

          qs_control%xtb_control%coulomb_sr_eps = scal(1)

          ! XB_radius

          CALL section_vals_val_get(xtb_parameter, "XB_RADIUS", r_val=qs_control%xtb_control%xb_radius)

          ! Kab

          CALL section_vals_val_get(xtb_parameter, "KAB_PARAM", n_rep_val=n_rep)

          ! For debug purposes

          CALL section_vals_val_get(xtb_section, "COULOMB_INTERACTION", &

                                    l_val=qs_control%xtb_control%coulomb_interaction)

          CALL section_vals_val_get(xtb_section, "COULOMB_LR", &

                                    l_val=qs_control%xtb_control%coulomb_lr)

          CALL section_vals_val_get(xtb_section, "TB3_INTERACTION", &

                                    l_val=qs_control%xtb_control%tb3_interaction)

          ! Check for bad atomic charges

          CALL section_vals_val_get(xtb_section, "CHECK_ATOMIC_CHARGES", &

                                    l_val=qs_control%xtb_control%check_atomic_charges)


          qs_control%xtb_control%kab_nval = n_rep

          IF (n_rep > 0) THEN

             ALLOCATE (qs_control%xtb_control%kab_param(3, n_rep))

             ALLOCATE (qs_control%xtb_control%kab_types(2, n_rep))

             ALLOCATE (qs_control%xtb_control%kab_vals(n_rep))

             DO j = 1, n_rep

                CALL section_vals_val_get(xtb_parameter, "KAB_PARAM", i_rep_val=j, c_vals=clist)

                qs_control%xtb_control%kab_param(1, j) = clist(1)

                CALL get_ptable_info(clist(1), &

                                     ielement=qs_control%xtb_control%kab_types(1, j))

                qs_control%xtb_control%kab_param(2, j) = clist(2)

                CALL get_ptable_info(clist(2), &

                                     ielement=qs_control%xtb_control%kab_types(2, j))

                qs_control%xtb_control%kab_param(3, j) = clist(3)

                READ (clist(3), '(F10.0)') qs_control%xtb_control%kab_vals(j)

             END DO

          END IF

       END IF


       ! Optimize LRI basis set

       CALL section_vals_get(lri_optbas_section, explicit=qs_control%lri_optbas)


       CALL timestop(handle)

    END SUBROUTINE read_qs_section


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

 !> \brief ...

 !> \param t_control ...

 !> \param dft_section ...

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

    SUBROUTINE read_tddfpt_control(t_control, dft_section)

       TYPE(tddfpt_control_type)                          :: t_control

       TYPE(section_vals_type), POINTER                   :: dft_section


       LOGICAL                                            :: kenergy_den

       TYPE(section_vals_type), POINTER                   :: sic_section, t_section


       kenergy_den = .false.

       NULLIFY (sic_section, t_section)

       t_section => section_vals_get_subs_vals(dft_section, "TDDFPT")


       CALL section_vals_val_get(t_section, "CONVERGENCE", r_val=t_control%tolerance)

       CALL section_vals_val_get(t_section, "NEV", i_val=t_control%n_ev)

       CALL section_vals_val_get(t_section, "MAX_KV", i_val=t_control%max_kv)

       CALL section_vals_val_get(t_section, "RESTARTS", i_val=t_control%n_restarts)

       CALL section_vals_val_get(t_section, "NREORTHO", i_val=t_control%n_reortho)

       CALL section_vals_val_get(t_section, "RES_ETYPE", i_val=t_control%res_etype)

       CALL section_vals_val_get(t_section, "DIAG_METHOD", i_val=t_control%diag_method)

       CALL section_vals_val_get(t_section, "KERNEL", l_val=t_control%do_kernel)

       CALL section_vals_val_get(t_section, "LSD_SINGLETS", l_val=t_control%lsd_singlets)

       CALL section_vals_val_get(t_section, "INVERT_S", l_val=t_control%invert_S)

       CALL section_vals_val_get(t_section, "PRECOND", l_val=t_control%precond)

       CALL section_vals_val_get(t_section, "OE_CORR", i_val=t_control%oe_corr)


       t_control%use_kinetic_energy_density = .false.

       sic_section => section_vals_get_subs_vals(t_section, "SIC")

       CALL section_vals_val_get(sic_section, "SIC_METHOD", i_val=t_control%sic_method_id)

       CALL section_vals_val_get(sic_section, "ORBITAL_SET", i_val=t_control%sic_list_id)

       CALL section_vals_val_get(sic_section, "SIC_SCALING_A", r_val=t_control%sic_scaling_a)

       CALL section_vals_val_get(sic_section, "SIC_SCALING_B", r_val=t_control%sic_scaling_b)


    END SUBROUTINE read_tddfpt_control


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

 !> \brief Read TDDFPT-related input parameters.

 !> \param t_control  TDDFPT control parameters

 !> \param t_section  TDDFPT input section

 !> \param qs_control Quickstep control parameters

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

    SUBROUTINE read_tddfpt2_control(t_control, t_section, qs_control)

       TYPE(tddfpt2_control_type), POINTER                :: t_control

       TYPE(section_vals_type), POINTER                   :: t_section

       TYPE(qs_control_type), POINTER                     :: qs_control


       CHARACTER(LEN=*), PARAMETER :: routinen = 'read_tddfpt2_control'


       CHARACTER(LEN=default_string_length), &

          DIMENSION(:), POINTER                           :: tmpstringlist

       INTEGER                                            :: handle, irep, isize, nrep

       INTEGER, ALLOCATABLE, DIMENSION(:)                 :: inds

       LOGICAL                                            :: do_ewald, do_exchange, expl, explicit, &

                                                             multigrid_set

       REAL(kind=dp)                                      :: filter, fval, hfx

       TYPE(section_vals_type), POINTER                   :: dipole_section, mgrid_section, &

                                                             soc_section, stda_section, xc_func, &

                                                             xc_section


       CALL timeset(routinen, handle)


       CALL section_vals_val_get(t_section, "_SECTION_PARAMETERS_", l_val=t_control%enabled)


       CALL section_vals_val_get(t_section, "NSTATES", i_val=t_control%nstates)

       CALL section_vals_val_get(t_section, "MAX_ITER", i_val=t_control%niters)

       CALL section_vals_val_get(t_section, "MAX_KV", i_val=t_control%nkvs)

       CALL section_vals_val_get(t_section, "NLUMO", i_val=t_control%nlumo)

       CALL section_vals_val_get(t_section, "NPROC_STATE", i_val=t_control%nprocs)

       CALL section_vals_val_get(t_section, "KERNEL", i_val=t_control%kernel)

       CALL section_vals_val_get(t_section, "OE_CORR", i_val=t_control%oe_corr)

       CALL section_vals_val_get(t_section, "EV_SHIFT", r_val=t_control%ev_shift)

       CALL section_vals_val_get(t_section, "EOS_SHIFT", r_val=t_control%eos_shift)


       CALL section_vals_val_get(t_section, "CONVERGENCE", r_val=t_control%conv)

       CALL section_vals_val_get(t_section, "MIN_AMPLITUDE", r_val=t_control%min_excitation_amplitude)

       CALL section_vals_val_get(t_section, "ORTHOGONAL_EPS", r_val=t_control%orthogonal_eps)


       CALL section_vals_val_get(t_section, "RESTART", l_val=t_control%is_restart)

       CALL section_vals_val_get(t_section, "RKS_TRIPLETS", l_val=t_control%rks_triplets)

       CALL section_vals_val_get(t_section, "DO_LRIGPW", l_val=t_control%do_lrigpw)

       CALL section_vals_val_get(t_section, "ADMM_KERNEL_CORRECTION_SYMMETRIC", l_val=t_control%admm_symm)

       CALL section_vals_val_get(t_section, "ADMM_KERNEL_XC_CORRECTION", l_val=t_control%admm_xc_correction)


       ! read automatically generated auxiliary basis for LRI

       CALL section_vals_val_get(t_section, "AUTO_BASIS", n_rep_val=nrep)

       DO irep = 1, nrep

          CALL section_vals_val_get(t_section, "AUTO_BASIS", i_rep_val=irep, c_vals=tmpstringlist)

          IF (SIZE(tmpstringlist) == 2) THEN

             CALL uppercase(tmpstringlist(2))

             SELECT CASE (tmpstringlist(2))

             CASE ("X")

                isize = -1

             CASE ("SMALL")

                isize = 0

             CASE ("MEDIUM")

                isize = 1

             CASE ("LARGE")

                isize = 2

             CASE ("HUGE")

                isize = 3

             CASE DEFAULT

                cpabort("Unknown basis size in AUTO_BASIS keyword:"//trim(tmpstringlist(1)))

             END SELECT

             !

             SELECT CASE (tmpstringlist(1))

             CASE ("X")

             CASE ("P_LRI_AUX")

                t_control%auto_basis_p_lri_aux = isize

             CASE DEFAULT

                cpabort("Unknown basis type in AUTO_BASIS keyword:"//trim(tmpstringlist(1)))

             END SELECT

          ELSE

             CALL cp_abort(__location__, &

                           "AUTO_BASIS keyword in &PROPERTIES &TDDFT section has a wrong number of arguments.")

          END IF

       END DO


       IF (t_control%conv < 0) &

          t_control%conv = abs(t_control%conv)


       ! DIPOLE_MOMENTS subsection

       dipole_section => section_vals_get_subs_vals(t_section, "DIPOLE_MOMENTS")

       CALL section_vals_val_get(dipole_section, "DIPOLE_FORM", explicit=explicit)

       IF (explicit) THEN

          CALL section_vals_val_get(dipole_section, "DIPOLE_FORM", i_val=t_control%dipole_form)

       ELSE

          t_control%dipole_form = 0

       END IF

       CALL section_vals_val_get(dipole_section, "REFERENCE", i_val=t_control%dipole_reference)

       CALL section_vals_val_get(dipole_section, "REFERENCE_POINT", explicit=explicit)

       IF (explicit) THEN

          CALL section_vals_val_get(dipole_section, "REFERENCE_POINT", r_vals=t_control%dipole_ref_point)

       ELSE

          NULLIFY (t_control%dipole_ref_point)

          IF (t_control%dipole_form == tddfpt_dipole_length .AND. t_control%dipole_reference == use_mom_ref_user) THEN

             cpabort("User-defined reference point should be given explicitly")

          END IF

       END IF


       !SOC subsection

       soc_section => section_vals_get_subs_vals(t_section, "SOC")

       CALL section_vals_get(soc_section, explicit=explicit)

       IF (explicit) THEN

          t_control%do_soc = .true.

       END IF


       ! MGRID subsection

       mgrid_section => section_vals_get_subs_vals(t_section, "MGRID")

       CALL section_vals_get(mgrid_section, explicit=t_control%mgrid_is_explicit)


       IF (t_control%mgrid_is_explicit) THEN

          CALL section_vals_val_get(mgrid_section, "NGRIDS", i_val=t_control%mgrid_ngrids, explicit=explicit)

          IF (.NOT. explicit) t_control%mgrid_ngrids = SIZE(qs_control%e_cutoff)


          CALL section_vals_val_get(mgrid_section, "CUTOFF", r_val=t_control%mgrid_cutoff, explicit=explicit)

          IF (.NOT. explicit) t_control%mgrid_cutoff = qs_control%cutoff


          CALL section_vals_val_get(mgrid_section, "PROGRESSION_FACTOR", &

                                    r_val=t_control%mgrid_progression_factor, explicit=explicit)

          IF (explicit) THEN

             IF (t_control%mgrid_progression_factor <= 1.0_dp) &

                CALL cp_abort(__location__, &

                              "Progression factor should be greater then 1.0 to ensure multi-grid ordering")

          ELSE

             t_control%mgrid_progression_factor = qs_control%progression_factor

          END IF


          CALL section_vals_val_get(mgrid_section, "COMMENSURATE", l_val=t_control%mgrid_commensurate_mgrids, explicit=explicit)

          IF (.NOT. explicit) t_control%mgrid_commensurate_mgrids = qs_control%commensurate_mgrids

          IF (t_control%mgrid_commensurate_mgrids) THEN

             IF (explicit) THEN

                t_control%mgrid_progression_factor = 4.0_dp

             ELSE

                t_control%mgrid_progression_factor = qs_control%progression_factor

             END IF

          END IF


          CALL section_vals_val_get(mgrid_section, "REL_CUTOFF", r_val=t_control%mgrid_relative_cutoff, explicit=explicit)

          IF (.NOT. explicit) t_control%mgrid_relative_cutoff = qs_control%relative_cutoff


          CALL section_vals_val_get(mgrid_section, "MULTIGRID_SET", l_val=multigrid_set, explicit=explicit)

          IF (.NOT. explicit) multigrid_set = .false.

          IF (multigrid_set) THEN

             CALL section_vals_val_get(mgrid_section, "MULTIGRID_CUTOFF", r_vals=t_control%mgrid_e_cutoff)

          ELSE

             NULLIFY (t_control%mgrid_e_cutoff)

          END IF


          CALL section_vals_val_get(mgrid_section, "REALSPACE", l_val=t_control%mgrid_realspace_mgrids, explicit=explicit)

          IF (.NOT. explicit) t_control%mgrid_realspace_mgrids = qs_control%realspace_mgrids


          CALL section_vals_val_get(mgrid_section, "SKIP_LOAD_BALANCE_DISTRIBUTED", &

                                    l_val=t_control%mgrid_skip_load_balance, explicit=explicit)

          IF (.NOT. explicit) t_control%mgrid_skip_load_balance = qs_control%skip_load_balance_distributed


          IF (ASSOCIATED(t_control%mgrid_e_cutoff)) THEN

             IF (SIZE(t_control%mgrid_e_cutoff) /= t_control%mgrid_ngrids) &

                cpabort("Inconsistent values for number of multi-grids")


             ! sort multi-grids in descending order according to their cutoff values

             t_control%mgrid_e_cutoff = -t_control%mgrid_e_cutoff

             ALLOCATE (inds(t_control%mgrid_ngrids))

             CALL sort(t_control%mgrid_e_cutoff, t_control%mgrid_ngrids, inds)

             DEALLOCATE (inds)

             t_control%mgrid_e_cutoff = -t_control%mgrid_e_cutoff

          END IF

       END IF


       ! expand XC subsection (if given explicitly)

       xc_section => section_vals_get_subs_vals(t_section, "XC")

       xc_func => section_vals_get_subs_vals(xc_section, "XC_FUNCTIONAL")

       CALL section_vals_get(xc_func, explicit=explicit)

       IF (explicit) &

          CALL xc_functionals_expand(xc_func, xc_section)


       ! sTDA subsection

       stda_section => section_vals_get_subs_vals(t_section, "STDA")

       IF (t_control%kernel == tddfpt_kernel_stda) THEN

          t_control%stda_control%hfx_fraction = 0.0_dp

          t_control%stda_control%do_exchange = .true.

          t_control%stda_control%eps_td_filter = 1.e-10_dp

          t_control%stda_control%mn_alpha = -99.0_dp

          t_control%stda_control%mn_beta = -99.0_dp

          ! set default for Ewald method (on/off) dependent on periodicity

          SELECT CASE (qs_control%periodicity)

          CASE (0)

             t_control%stda_control%do_ewald = .false.

          CASE (1)

             t_control%stda_control%do_ewald = .true.

          CASE (2)

             t_control%stda_control%do_ewald = .true.

          CASE (3)

             t_control%stda_control%do_ewald = .true.

          CASE DEFAULT

             cpabort("Illegal value for periodiciy")

          END SELECT

          CALL section_vals_get(stda_section, explicit=explicit)

          IF (explicit) THEN

             CALL section_vals_val_get(stda_section, "HFX_FRACTION", r_val=hfx, explicit=expl)

             IF (expl) t_control%stda_control%hfx_fraction = hfx

             CALL section_vals_val_get(stda_section, "EPS_TD_FILTER", r_val=filter, explicit=expl)

             IF (expl) t_control%stda_control%eps_td_filter = filter

             CALL section_vals_val_get(stda_section, "DO_EWALD", l_val=do_ewald, explicit=expl)

             IF (expl) t_control%stda_control%do_ewald = do_ewald

             CALL section_vals_val_get(stda_section, "DO_EXCHANGE", l_val=do_exchange, explicit=expl)

             IF (expl) t_control%stda_control%do_exchange = do_exchange

             CALL section_vals_val_get(stda_section, "MATAGA_NISHIMOTO_CEXP", r_val=fval)

             t_control%stda_control%mn_alpha = fval

             CALL section_vals_val_get(stda_section, "MATAGA_NISHIMOTO_XEXP", r_val=fval)

             t_control%stda_control%mn_beta = fval

          END IF

          CALL section_vals_val_get(stda_section, "COULOMB_SR_CUT", r_val=fval)

          t_control%stda_control%coulomb_sr_cut = fval

          CALL section_vals_val_get(stda_section, "COULOMB_SR_EPS", r_val=fval)

          t_control%stda_control%coulomb_sr_eps = fval

       END IF


       CALL timestop(handle)

    END SUBROUTINE read_tddfpt2_control


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

 !> \brief Write the DFT control parameters to the output unit.

 !> \param dft_control ...

 !> \param dft_section ...

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

    SUBROUTINE write_dft_control(dft_control, dft_section)

       TYPE(dft_control_type), POINTER                    :: dft_control

       TYPE(section_vals_type), POINTER                   :: dft_section


       CHARACTER(len=*), PARAMETER                        :: routinen = 'write_dft_control'


       CHARACTER(LEN=20)                                  :: tmpstr

       INTEGER                                            :: handle, output_unit

       REAL(kind=dp)                                      :: density_cut, density_smooth_cut_range, &

                                                             gradient_cut, tau_cut

       TYPE(cp_logger_type), POINTER                      :: logger

       TYPE(enumeration_type), POINTER                    :: enum

       TYPE(keyword_type), POINTER                        :: keyword

       TYPE(section_type), POINTER                        :: section

       TYPE(section_vals_type), POINTER                   :: xc_section


       IF (dft_control%qs_control%semi_empirical) RETURN

       IF (dft_control%qs_control%dftb) RETURN

       IF (dft_control%qs_control%xtb) THEN

          CALL write_xtb_control(dft_control%qs_control%xtb_control, dft_section)

          RETURN

       END IF

       CALL timeset(routinen, handle)


       NULLIFY (logger)

       logger => cp_get_default_logger()


       output_unit = cp_print_key_unit_nr(logger, dft_section, &

                                          "PRINT%DFT_CONTROL_PARAMETERS", extension=".Log")


       IF (output_unit > 0) THEN


          xc_section => section_vals_get_subs_vals(dft_section, "XC")


          IF (dft_control%uks) THEN

             WRITE (unit=output_unit, fmt="(/,T2,A,T78,A)") &

                "DFT| Spin unrestricted (spin-polarized) Kohn-Sham calculation", "UKS"

          ELSE IF (dft_control%roks) THEN

             WRITE (unit=output_unit, fmt="(/,T2,A,T77,A)") &

                "DFT| Spin restricted open Kohn-Sham calculation", "ROKS"

          ELSE

             WRITE (unit=output_unit, fmt="(/,T2,A,T78,A)") &

                "DFT| Spin restricted Kohn-Sham (RKS) calculation", "RKS"

          END IF


          WRITE (unit=output_unit, fmt="(T2,A,T76,I5)") &

             "DFT| Multiplicity", dft_control%multiplicity

          WRITE (unit=output_unit, fmt="(T2,A,T76,I5)") &

             "DFT| Number of spin states", dft_control%nspins


          WRITE (unit=output_unit, fmt="(T2,A,T76,I5)") &

             "DFT| Charge", dft_control%charge


          IF (dft_control%sic_method_id .NE. sic_none) CALL cite_reference(vandevondele2005b)

          SELECT CASE (dft_control%sic_method_id)

          CASE (sic_none)

             tmpstr = "NO"

          CASE (sic_mauri_spz)

             tmpstr = "SPZ/MAURI SIC"

          CASE (sic_mauri_us)

             tmpstr = "US/MAURI SIC"

          CASE (sic_ad)

             tmpstr = "AD SIC"

          CASE (sic_eo)

             tmpstr = "Explicit Orbital SIC"

          CASE DEFAULT

             ! fix throughout the cp2k for this option

             cpabort("SIC option unknown")

          END SELECT


          WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &

             "DFT| Self-interaction correction (SIC)", adjustr(trim(tmpstr))


          IF (dft_control%sic_method_id /= sic_none) THEN

             WRITE (unit=output_unit, fmt="(T2,A,T66,ES15.6)") &

                "DFT| SIC scaling parameter a", dft_control%sic_scaling_a, &

                "DFT| SIC scaling parameter b", dft_control%sic_scaling_b

          END IF


          IF (dft_control%sic_method_id == sic_eo) THEN

             IF (dft_control%sic_list_id == sic_list_all) THEN

                WRITE (unit=output_unit, fmt="(T2,A,T66,A)") &

                   "DFT| SIC orbitals", "ALL"

             END IF

             IF (dft_control%sic_list_id == sic_list_unpaired) THEN

                WRITE (unit=output_unit, fmt="(T2,A,T66,A)") &

                   "DFT| SIC orbitals", "UNPAIRED"

             END IF

          END IF


          CALL section_vals_val_get(xc_section, "density_cutoff", r_val=density_cut)

          CALL section_vals_val_get(xc_section, "gradient_cutoff", r_val=gradient_cut)

          CALL section_vals_val_get(xc_section, "tau_cutoff", r_val=tau_cut)

          CALL section_vals_val_get(xc_section, "density_smooth_cutoff_range", r_val=density_smooth_cut_range)


          WRITE (unit=output_unit, fmt="(T2,A,T66,ES15.6)") &

             "DFT| Cutoffs: density ", density_cut, &

             "DFT|          gradient", gradient_cut, &

             "DFT|          tau     ", tau_cut, &

             "DFT|          cutoff_smoothing_range", density_smooth_cut_range

          CALL section_vals_val_get(xc_section, "XC_GRID%XC_SMOOTH_RHO", &

                                    c_val=tmpstr)

          WRITE (output_unit, '( A, T61, A )') &

             " DFT| XC density smoothing ", adjustr(tmpstr)

          CALL section_vals_val_get(xc_section, "XC_GRID%XC_DERIV", &

                                    c_val=tmpstr)

          WRITE (output_unit, '( A, T61, A )') &

             " DFT| XC derivatives ", adjustr(tmpstr)

          IF (dft_control%dft_plus_u) THEN

             NULLIFY (enum, keyword, section)

             CALL create_dft_section(section)

             keyword => section_get_keyword(section, "PLUS_U_METHOD")

             CALL keyword_get(keyword, enum=enum)

             WRITE (unit=output_unit, fmt="(/,T2,A,T41,A40)") &

                "DFT+U| Method", adjustr(trim(enum_i2c(enum, dft_control%plus_u_method_id)))

             WRITE (unit=output_unit, fmt="(T2,A)") &

                "DFT+U| Check atomic kind information for details"

             CALL section_release(section)

          END IF


          WRITE (unit=output_unit, fmt="(A)") ""

          CALL xc_write(output_unit, xc_section, dft_control%lsd)


          IF (dft_control%apply_period_efield) THEN

             WRITE (unit=output_unit, fmt="(A)") ""

             IF (dft_control%period_efield%displacement_field) THEN

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "PERIODIC_EFIELD| Use displacement field formulation"

                WRITE (unit=output_unit, fmt="(T2,A,T66,1X,ES14.6)") &

                   "PERIODIC_EFIELD| Displacement field filter: x", &

                   dft_control%period_efield%d_filter(1), &

                   "PERIODIC_EFIELD|                            y", &

                   dft_control%period_efield%d_filter(2), &

                   "PERIODIC_EFIELD|                            z", &

                   dft_control%period_efield%d_filter(3)

             END IF

             WRITE (unit=output_unit, fmt="(T2,A,T66,1X,ES14.6)") &

                "PERIODIC_EFIELD| Polarisation vector:       x", &

                dft_control%period_efield%polarisation(1), &

                "PERIODIC_EFIELD|                            y", &

                dft_control%period_efield%polarisation(2), &

                "PERIODIC_EFIELD|                            z", &

                dft_control%period_efield%polarisation(3), &

                "PERIODIC_EFIELD| Intensity [a.u.]:", &

                dft_control%period_efield%strength

             IF (sqrt(dot_product(dft_control%period_efield%polarisation, &

                                  dft_control%period_efield%polarisation)) < epsilon(0.0_dp)) THEN

                cpabort("Invalid (too small) polarisation vector specified for PERIODIC_EFIELD")

             END IF

          END IF


          IF (dft_control%do_sccs) THEN

             WRITE (unit=output_unit, fmt="(/,T2,A)") &

                "SCCS| Self-consistent continuum solvation model"

             WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &

                "SCCS| Relative permittivity of the solvent (medium)", &

                dft_control%sccs_control%epsilon_solvent, &

                "SCCS| Absolute permittivity [a.u.]", &

                dft_control%sccs_control%epsilon_solvent/fourpi

             SELECT CASE (dft_control%sccs_control%method_id)

             CASE (sccs_andreussi)

                WRITE (unit=output_unit, fmt="(T2,A,/,(T2,A,T61,ES20.6))") &

                   "SCCS| Dielectric function proposed by Andreussi et al.", &

                   "SCCS|  rho_max", dft_control%sccs_control%rho_max, &

                   "SCCS|  rho_min", dft_control%sccs_control%rho_min

             CASE (sccs_fattebert_gygi)

                WRITE (unit=output_unit, fmt="(T2,A,/,(T2,A,T61,ES20.6))") &

                   "SCCS| Dielectric function proposed by Fattebert and Gygi", &

                   "SCCS|  beta", dft_control%sccs_control%beta, &

                   "SCCS|  rho_zero", dft_control%sccs_control%rho_zero

             CASE DEFAULT

                cpabort("Invalid SCCS model specified. Please, check your input!")

             END SELECT

             SELECT CASE (dft_control%sccs_control%derivative_method)

             CASE (sccs_derivative_fft)

                WRITE (unit=output_unit, fmt="(T2,A,T46,A35)") &

                   "SCCS| Numerical derivative calculation", &

                   adjustr("FFT")

             CASE (sccs_derivative_cd3)

                WRITE (unit=output_unit, fmt="(T2,A,T46,A35)") &

                   "SCCS| Numerical derivative calculation", &

                   adjustr("3-point stencil central differences")

             CASE (sccs_derivative_cd5)

                WRITE (unit=output_unit, fmt="(T2,A,T46,A35)") &

                   "SCCS| Numerical derivative calculation", &

                   adjustr("5-point stencil central differences")

             CASE (sccs_derivative_cd7)

                WRITE (unit=output_unit, fmt="(T2,A,T46,A35)") &

                   "SCCS| Numerical derivative calculation", &

                   adjustr("7-point stencil central differences")

             CASE DEFAULT

                CALL cp_abort(__location__, &

                              "Invalid derivative method specified for SCCS model. "// &

                              "Please, check your input!")

             END SELECT

             WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &

                "SCCS| Repulsion parameter alpha [mN/m] = [dyn/cm]", &

                cp_unit_from_cp2k(dft_control%sccs_control%alpha_solvent, "mN/m")

             WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &

                "SCCS| Dispersion parameter beta [GPa]", &

                cp_unit_from_cp2k(dft_control%sccs_control%beta_solvent, "GPa")

             WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &

                "SCCS| Surface tension gamma [mN/m] = [dyn/cm]", &

                cp_unit_from_cp2k(dft_control%sccs_control%gamma_solvent, "mN/m")

             WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &

                "SCCS| Mixing parameter applied during the iteration cycle", &

                dft_control%sccs_control%mixing

             WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &

                "SCCS| Tolerance for the convergence of the SCCS iteration cycle", &

                dft_control%sccs_control%eps_sccs

             WRITE (unit=output_unit, fmt="(T2,A,T61,I20)") &

                "SCCS| Maximum number of iteration steps", &

                dft_control%sccs_control%max_iter

             WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &

                "SCCS| SCF convergence threshold for starting the SCCS iteration", &

                dft_control%sccs_control%eps_scf

             WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &

                "SCCS| Numerical increment for the cavity surface calculation", &

                dft_control%sccs_control%delta_rho

          END IF


          WRITE (unit=output_unit, fmt="(A)") ""


       END IF


       CALL cp_print_key_finished_output(output_unit, logger, dft_section, &

                                         "PRINT%DFT_CONTROL_PARAMETERS")


       CALL timestop(handle)


    END SUBROUTINE write_dft_control


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

 !> \brief Write the ADMM control parameters to the output unit.

 !> \param admm_control ...

 !> \param dft_section ...

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

    SUBROUTINE write_admm_control(admm_control, dft_section)

       TYPE(admm_control_type), POINTER                   :: admm_control

       TYPE(section_vals_type), POINTER                   :: dft_section


       INTEGER                                            :: iounit

       TYPE(cp_logger_type), POINTER                      :: logger


       NULLIFY (logger)

       logger => cp_get_default_logger()


       iounit = cp_print_key_unit_nr(logger, dft_section, &

                                     "PRINT%DFT_CONTROL_PARAMETERS", extension=".Log")


       IF (iounit > 0) THEN


          SELECT CASE (admm_control%admm_type)

          CASE (no_admm_type)

             WRITE (unit=iounit, fmt="(/,T2,A,T77,A)") "ADMM| Specific ADMM type specified", "NONE"

          CASE (admm1_type)

             WRITE (unit=iounit, fmt="(/,T2,A,T76,A)") "ADMM| Specific ADMM type specified", "ADMM1"

          CASE (admm2_type)

             WRITE (unit=iounit, fmt="(/,T2,A,T76,A)") "ADMM| Specific ADMM type specified", "ADMM2"

          CASE (admms_type)

             WRITE (unit=iounit, fmt="(/,T2,A,T76,A)") "ADMM| Specific ADMM type specified", "ADMMS"

          CASE (admmp_type)

             WRITE (unit=iounit, fmt="(/,T2,A,T76,A)") "ADMM| Specific ADMM type specified", "ADMMP"

          CASE (admmq_type)

             WRITE (unit=iounit, fmt="(/,T2,A,T76,A)") "ADMM| Specific ADMM type specified", "ADMMQ"

          CASE DEFAULT

             cpabort("admm_type")

          END SELECT


          SELECT CASE (admm_control%purification_method)

          CASE (do_admm_purify_none)

             WRITE (unit=iounit, fmt="(T2,A,T77,A)") "ADMM| Density matrix purification method", "NONE"

          CASE (do_admm_purify_cauchy)

             WRITE (unit=iounit, fmt="(T2,A,T75,A)") "ADMM| Density matrix purification method", "Cauchy"

          CASE (do_admm_purify_cauchy_subspace)

             WRITE (unit=iounit, fmt="(T2,A,T66,A)") "ADMM| Density matrix purification method", "Cauchy subspace"

          CASE (do_admm_purify_mo_diag)

             WRITE (unit=iounit, fmt="(T2,A,T63,A)") "ADMM| Density matrix purification method", "MO diagonalization"

          CASE (do_admm_purify_mo_no_diag)

             WRITE (unit=iounit, fmt="(T2,A,T71,A)") "ADMM| Density matrix purification method", "MO no diag"

          CASE (do_admm_purify_mcweeny)

             WRITE (unit=iounit, fmt="(T2,A,T74,A)") "ADMM| Density matrix purification method", "McWeeny"

          CASE (do_admm_purify_none_dm)

             WRITE (unit=iounit, fmt="(T2,A,T73,A)") "ADMM| Density matrix purification method", "NONE(DM)"

          CASE DEFAULT

             cpabort("admm_purification_method")

          END SELECT


          SELECT CASE (admm_control%method)

          CASE (do_admm_basis_projection)

             WRITE (unit=iounit, fmt="(T2,A)") "ADMM| Orbital projection on ADMM basis"

          CASE (do_admm_blocking_purify_full)

             WRITE (unit=iounit, fmt="(T2,A)") "ADMM| Blocked Fock matrix projection with full purification"

          CASE (do_admm_blocked_projection)

             WRITE (unit=iounit, fmt="(T2,A)") "ADMM| Blocked Fock matrix projection"

          CASE (do_admm_charge_constrained_projection)

             WRITE (unit=iounit, fmt="(T2,A)") "ADMM| Orbital projection with charge constrain"

          CASE DEFAULT

             cpabort("admm method")

          END SELECT


          SELECT CASE (admm_control%scaling_model)

          CASE (do_admm_exch_scaling_none)

          CASE (do_admm_exch_scaling_merlot)

             WRITE (unit=iounit, fmt="(T2,A)") "ADMM| Use Merlot (2014) scaling model"

          CASE DEFAULT

             cpabort("admm scaling_model")

          END SELECT


          WRITE (unit=iounit, fmt="(T2,A,T61,G20.10)") "ADMM| eps_filter", admm_control%eps_filter


          SELECT CASE (admm_control%aux_exch_func)

          CASE (do_admm_aux_exch_func_none)

             WRITE (unit=iounit, fmt="(T2,A)") "ADMM| No exchange functional correction term used"

          CASE (do_admm_aux_exch_func_default, do_admm_aux_exch_func_default_libxc)

             WRITE (unit=iounit, fmt="(T2,A,T74,A)") "ADMM| Exchange functional in correction term", "(W)PBEX"

          CASE (do_admm_aux_exch_func_pbex, do_admm_aux_exch_func_pbex_libxc)

             WRITE (unit=iounit, fmt="(T2,A,T77,A)") "ADMM| Exchange functional in correction term", "PBEX"

          CASE (do_admm_aux_exch_func_opt, do_admm_aux_exch_func_opt_libxc)

             WRITE (unit=iounit, fmt="(T2,A,T77,A)") "ADMM| Exchange functional in correction term", "OPTX"

          CASE (do_admm_aux_exch_func_bee, do_admm_aux_exch_func_bee_libxc)

             WRITE (unit=iounit, fmt="(T2,A,T74,A)") "ADMM| Exchange functional in correction term", "Becke88"

          CASE (do_admm_aux_exch_func_sx_libxc)

             WRITE (unit=iounit, fmt="(T2,A,T74,A)") "ADMM| Exchange functional in correction term", "SlaterX"

          CASE DEFAULT

             cpabort("admm aux_exch_func")

          END SELECT


          WRITE (unit=iounit, fmt="(A)") ""


       END IF


       CALL cp_print_key_finished_output(iounit, logger, dft_section, &

                                         "PRINT%DFT_CONTROL_PARAMETERS")

    END SUBROUTINE write_admm_control


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

 !> \brief Write the xTB control parameters to the output unit.

 !> \param xtb_control ...

 !> \param dft_section ...

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

    SUBROUTINE write_xtb_control(xtb_control, dft_section)

       TYPE(xtb_control_type), POINTER                    :: xtb_control

       TYPE(section_vals_type), POINTER                   :: dft_section


       CHARACTER(len=*), PARAMETER                        :: routinen = 'write_xtb_control'


       INTEGER                                            :: handle, output_unit

       TYPE(cp_logger_type), POINTER                      :: logger


       CALL timeset(routinen, handle)

       NULLIFY (logger)

       logger => cp_get_default_logger()


       output_unit = cp_print_key_unit_nr(logger, dft_section, &

                                          "PRINT%DFT_CONTROL_PARAMETERS", extension=".Log")


       IF (output_unit > 0) THEN


          WRITE (unit=output_unit, fmt="(/,T2,A,T31,A50)") &

             "xTB| Parameter file", adjustr(trim(xtb_control%parameter_file_name))

          WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &

             "xTB| Basis expansion STO-NG", xtb_control%sto_ng

          WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &

             "xTB| Basis expansion STO-NG for Hydrogen", xtb_control%h_sto_ng

          WRITE (unit=output_unit, fmt="(T2,A,T71,L10)") &

             "xTB| Halogen interaction potential", xtb_control%xb_interaction

          WRITE (unit=output_unit, fmt="(T2,A,T71,F10.3)") &

             "xTB| Halogen interaction potential cutoff radius", xtb_control%xb_radius

          WRITE (unit=output_unit, fmt="(T2,A,T71,L10)") &

             "xTB| Nonbonded interactions", xtb_control%do_nonbonded

          WRITE (unit=output_unit, fmt="(T2,A,T31,A50)") &

             "xTB| D3 Dispersion: Parameter file", adjustr(trim(xtb_control%dispersion_parameter_file))

          WRITE (unit=output_unit, fmt="(T2,A,T51,3F10.3)") &

             "xTB| Huckel constants ks kp kd", xtb_control%ks, xtb_control%kp, xtb_control%kd

          WRITE (unit=output_unit, fmt="(T2,A,T61,2F10.3)") &

             "xTB| Huckel constants ksp k2sh", xtb_control%ksp, xtb_control%k2sh

          WRITE (unit=output_unit, fmt="(T2,A,T71,F10.3)") &

             "xTB| Mataga-Nishimoto exponent", xtb_control%kg

          WRITE (unit=output_unit, fmt="(T2,A,T71,F10.3)") &

             "xTB| Repulsion potential exponent", xtb_control%kf

          WRITE (unit=output_unit, fmt="(T2,A,T51,3F10.3)") &

             "xTB| Coordination number scaling kcn(s) kcn(p) kcn(d)", &

             xtb_control%kcns, xtb_control%kcnp, xtb_control%kcnd

          WRITE (unit=output_unit, fmt="(T2,A,T71,F10.3)") &

             "xTB| Electronegativity scaling", xtb_control%ken

          WRITE (unit=output_unit, fmt="(T2,A,T61,2F10.3)") &

             "xTB| Halogen potential scaling kxr kx2", xtb_control%kxr, xtb_control%kx2

          WRITE (unit=output_unit, fmt="(/)")


       END IF


       CALL cp_print_key_finished_output(output_unit, logger, dft_section, &

                                         "PRINT%DFT_CONTROL_PARAMETERS")


       CALL timestop(handle)


    END SUBROUTINE write_xtb_control


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

 !> \brief Purpose: Write the QS control parameters to the output unit.

 !> \param qs_control ...

 !> \param dft_section ...

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

    SUBROUTINE write_qs_control(qs_control, dft_section)

       TYPE(qs_control_type), INTENT(IN)                  :: qs_control

       TYPE(section_vals_type), POINTER                   :: dft_section


       CHARACTER(len=*), PARAMETER                        :: routinen = 'write_qs_control'


       CHARACTER(len=20)                                  :: method, quadrature

       INTEGER                                            :: handle, i, igrid_level, ngrid_level, &

                                                             output_unit

       TYPE(cp_logger_type), POINTER                      :: logger

       TYPE(ddapc_restraint_type), POINTER                :: ddapc_restraint_control

       TYPE(enumeration_type), POINTER                    :: enum

       TYPE(keyword_type), POINTER                        :: keyword

       TYPE(section_type), POINTER                        :: qs_section

       TYPE(section_vals_type), POINTER                   :: print_section_vals, qs_section_vals


       IF (qs_control%semi_empirical) RETURN

       IF (qs_control%dftb) RETURN

       IF (qs_control%xtb) RETURN

       CALL timeset(routinen, handle)

       NULLIFY (logger, print_section_vals, qs_section, qs_section_vals)

       logger => cp_get_default_logger()

       print_section_vals => section_vals_get_subs_vals(dft_section, "PRINT")

       qs_section_vals => section_vals_get_subs_vals(dft_section, "QS")

       CALL section_vals_get(qs_section_vals, section=qs_section)


       NULLIFY (enum, keyword)

       keyword => section_get_keyword(qs_section, "METHOD")

       CALL keyword_get(keyword, enum=enum)

       method = enum_i2c(enum, qs_control%method_id)


       NULLIFY (enum, keyword)

       keyword => section_get_keyword(qs_section, "QUADRATURE")

       CALL keyword_get(keyword, enum=enum)

       quadrature = enum_i2c(enum, qs_control%gapw_control%quadrature)


       output_unit = cp_print_key_unit_nr(logger, print_section_vals, &

                                          "DFT_CONTROL_PARAMETERS", extension=".Log")

       IF (output_unit > 0) THEN

          ngrid_level = SIZE(qs_control%e_cutoff)

          WRITE (unit=output_unit, fmt="(/,T2,A,T61,A20)") &

             "QS| Method:", adjustr(method)

          IF (qs_control%pw_grid_opt%spherical) THEN

             WRITE (unit=output_unit, fmt="(T2,A,T61,A)") &

                "QS| Density plane wave grid type", " SPHERICAL HALFSPACE"

          ELSE IF (qs_control%pw_grid_opt%fullspace) THEN

             WRITE (unit=output_unit, fmt="(T2,A,T57,A)") &

                "QS| Density plane wave grid type", " NON-SPHERICAL FULLSPACE"

          ELSE

             WRITE (unit=output_unit, fmt="(T2,A,T57,A)") &

                "QS| Density plane wave grid type", " NON-SPHERICAL HALFSPACE"

          END IF

          WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &

             "QS| Number of grid levels:", SIZE(qs_control%e_cutoff)

          IF (ngrid_level == 1) THEN

             WRITE (unit=output_unit, fmt="(T2,A,T71,F10.1)") &

                "QS| Density cutoff [a.u.]:", qs_control%e_cutoff(1)

          ELSE

             WRITE (unit=output_unit, fmt="(T2,A,T71,F10.1)") &

                "QS| Density cutoff [a.u.]:", qs_control%cutoff

             IF (qs_control%commensurate_mgrids) &

                WRITE (unit=output_unit, fmt="(T2,A)") "QS| Using commensurate multigrids"

             WRITE (unit=output_unit, fmt="(T2,A,T71,F10.1)") &

                "QS| Multi grid cutoff [a.u.]: 1) grid level", qs_control%e_cutoff(1)

             WRITE (unit=output_unit, fmt="(T2,A,I3,A,T71,F10.1)") &

                ("QS|                         ", igrid_level, ") grid level", &

                 qs_control%e_cutoff(igrid_level), &

                 igrid_level=2, SIZE(qs_control%e_cutoff))

          END IF

          IF (qs_control%pao) THEN

             WRITE (unit=output_unit, fmt="(T2,A)") "QS| PAO active"

          END IF

          WRITE (unit=output_unit, fmt="(T2,A,T71,F10.1)") &

             "QS| Grid level progression factor:", qs_control%progression_factor

          WRITE (unit=output_unit, fmt="(T2,A,T71,F10.1)") &

             "QS| Relative density cutoff [a.u.]:", qs_control%relative_cutoff

          WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &

             "QS| Interaction thresholds: eps_pgf_orb:", &

             qs_control%eps_pgf_orb, &

             "QS|                         eps_filter_matrix:", &

             qs_control%eps_filter_matrix, &

             "QS|                         eps_core_charge:", &

             qs_control%eps_core_charge, &

             "QS|                         eps_rho_gspace:", &

             qs_control%eps_rho_gspace, &

             "QS|                         eps_rho_rspace:", &

             qs_control%eps_rho_rspace, &

             "QS|                         eps_gvg_rspace:", &

             qs_control%eps_gvg_rspace, &

             "QS|                         eps_ppl:", &

             qs_control%eps_ppl, &

             "QS|                         eps_ppnl:", &

             qs_control%eps_ppnl

          IF (qs_control%gapw) THEN

             SELECT CASE (qs_control%gapw_control%basis_1c)

             CASE (gapw_1c_orb)

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW|      One center basis from orbital basis primitives"

             CASE (gapw_1c_small)

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW|      One center basis extended with primitives (small:s)"

             CASE (gapw_1c_medium)

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW|      One center basis extended with primitives (medium:sp)"

             CASE (gapw_1c_large)

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW|      One center basis extended with primitives (large:spd)"

             CASE (gapw_1c_very_large)

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW|      One center basis extended with primitives (very large:spdf)"

             CASE DEFAULT

                cpabort("basis_1c incorrect")

             END SELECT

             WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &

                "QS| GAPW|                   eps_fit:", &

                qs_control%gapw_control%eps_fit, &

                "QS| GAPW|                   eps_iso:", &

                qs_control%gapw_control%eps_iso, &

                "QS| GAPW|                   eps_svd:", &

                qs_control%gapw_control%eps_svd, &

                "QS| GAPW|                   eps_cpc:", &

                qs_control%gapw_control%eps_cpc

             WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &

                "QS| GAPW|   atom-r-grid: quadrature:", &

                adjustr(quadrature)

             WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &

                "QS| GAPW|      atom-s-grid:  max l :", &

                qs_control%gapw_control%lmax_sphere, &

                "QS| GAPW|      max_l_rho0 :", &

                qs_control%gapw_control%lmax_rho0

             IF (qs_control%gapw_control%non_paw_atoms) THEN

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW|      At least one kind is NOT PAW, i.e. it has only soft AO "

             END IF

             IF (qs_control%gapw_control%nopaw_as_gpw) THEN

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW|      The NOT PAW atoms are treated fully GPW"

             END IF

          END IF

          IF (qs_control%gapw_xc) THEN

             SELECT CASE (qs_control%gapw_control%basis_1c)

             CASE (gapw_1c_orb)

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW_XC|      One center basis from orbital basis primitives"

             CASE (gapw_1c_small)

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW_XC|      One center basis extended with primitives (small:s)"

             CASE (gapw_1c_medium)

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW_XC|      One center basis extended with primitives (medium:sp)"

             CASE (gapw_1c_large)

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW_XC|      One center basis extended with primitives (large:spd)"

             CASE (gapw_1c_very_large)

                WRITE (unit=output_unit, fmt="(T2,A)") &

                   "QS| GAPW_XC|      One center basis extended with primitives (very large:spdf)"

             CASE DEFAULT

                cpabort("basis_1c incorrect")

             END SELECT

             WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &

                "QS| GAPW_XC|                eps_fit:", &

                qs_control%gapw_control%eps_fit, &

                "QS| GAPW_XC|                eps_iso:", &

                qs_control%gapw_control%eps_iso, &

                "QS| GAPW_XC|                eps_svd:", &

                qs_control%gapw_control%eps_svd

             WRITE (unit=output_unit, fmt="(T2,A,T55,A30)") &

                "QS| GAPW_XC|atom-r-grid: quadrature:", &

                enum_i2c(enum, qs_control%gapw_control%quadrature)

             WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &

                "QS| GAPW_XC|   atom-s-grid:  max l :", &

                qs_control%gapw_control%lmax_sphere

          END IF

          IF (qs_control%mulliken_restraint) THEN

             WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &

                "QS| Mulliken restraint target", qs_control%mulliken_restraint_control%target

             WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &

                "QS| Mulliken restraint strength", qs_control%mulliken_restraint_control%strength

             WRITE (unit=output_unit, fmt="(T2,A,T73,I8)") &

                "QS| Mulliken restraint atoms: ", qs_control%mulliken_restraint_control%natoms

             WRITE (unit=output_unit, fmt="(5I8)") qs_control%mulliken_restraint_control%atoms

          END IF

          IF (qs_control%ddapc_restraint) THEN

             DO i = 1, SIZE(qs_control%ddapc_restraint_control)

                ddapc_restraint_control => qs_control%ddapc_restraint_control(i)

                IF (SIZE(qs_control%ddapc_restraint_control) .GT. 1) &

                   WRITE (unit=output_unit, fmt="(T2,A,T3,I8)") &

                   "QS| parameters for DDAPC restraint number", i

                WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &

                   "QS| ddapc restraint target", ddapc_restraint_control%target

                WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &

                   "QS| ddapc restraint strength", ddapc_restraint_control%strength

                WRITE (unit=output_unit, fmt="(T2,A,T73,I8)") &

                   "QS| ddapc restraint atoms: ", ddapc_restraint_control%natoms

                WRITE (unit=output_unit, fmt="(5I8)") ddapc_restraint_control%atoms

                WRITE (unit=output_unit, fmt="(T2,A)") "Coefficients:"

                WRITE (unit=output_unit, fmt="(5F6.2)") ddapc_restraint_control%coeff

                SELECT CASE (ddapc_restraint_control%functional_form)

                CASE (do_ddapc_restraint)

                   WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &

                      "QS| ddapc restraint functional form :", "RESTRAINT"

                CASE (do_ddapc_constraint)

                   WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &

                      "QS| ddapc restraint functional form :", "CONSTRAINT"

                CASE DEFAULT

                   cpabort("Unknown ddapc restraint")

                END SELECT

             END DO

          END IF

          IF (qs_control%s2_restraint) THEN

             WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &

                "QS| s2 restraint target", qs_control%s2_restraint_control%target

             WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &

                "QS| s2 restraint strength", qs_control%s2_restraint_control%strength

             SELECT CASE (qs_control%s2_restraint_control%functional_form)

             CASE (do_s2_restraint)

                WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &

                   "QS| s2 restraint functional form :", "RESTRAINT"

                cpabort("Not yet implemented")

             CASE (do_s2_constraint)

                WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &

                   "QS| s2 restraint functional form :", "CONSTRAINT"

             CASE DEFAULT

                cpabort("Unknown ddapc restraint")

             END SELECT

          END IF

       END IF

       CALL cp_print_key_finished_output(output_unit, logger, print_section_vals, &

                                         "DFT_CONTROL_PARAMETERS")


       CALL timestop(handle)


    END SUBROUTINE write_qs_control


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

 !> \brief reads the input parameters needed for ddapc.

 !> \param qs_control ...

 !> \param qs_section ...

 !> \param ddapc_restraint_section ...

 !> \author fschiff

 !> \note

 !>      either reads DFT%QS%DDAPC_RESTRAINT or PROPERTIES%ET_coupling

 !>      if(qs_section is present the DFT part is read, if ddapc_restraint_section

 !>      is present ET_COUPLING is read. Avoid having both!!!

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

    SUBROUTINE read_ddapc_section(qs_control, qs_section, ddapc_restraint_section)


       TYPE(qs_control_type), INTENT(INOUT)               :: qs_control

       TYPE(section_vals_type), OPTIONAL, POINTER         :: qs_section, ddapc_restraint_section


       INTEGER                                            :: i, j, jj, k, n_rep

       INTEGER, DIMENSION(:), POINTER                     :: tmplist

       REAL(kind=dp), DIMENSION(:), POINTER               :: rtmplist

       TYPE(ddapc_restraint_type), POINTER                :: ddapc_restraint_control

       TYPE(section_vals_type), POINTER                   :: ddapc_section


       IF (PRESENT(ddapc_restraint_section)) THEN

          IF (ASSOCIATED(qs_control%ddapc_restraint_control)) THEN

             IF (SIZE(qs_control%ddapc_restraint_control) .GE. 2) &

                cpabort("ET_COUPLING cannot be used in combination with a normal restraint")

          ELSE

             ddapc_section => ddapc_restraint_section

             ALLOCATE (qs_control%ddapc_restraint_control(1))

          END IF

       END IF


       IF (PRESENT(qs_section)) THEN

          NULLIFY (ddapc_section)

          ddapc_section => section_vals_get_subs_vals(qs_section, &

                                                      "DDAPC_RESTRAINT")

       END IF


       DO i = 1, SIZE(qs_control%ddapc_restraint_control)


          CALL ddapc_control_create(qs_control%ddapc_restraint_control(i))

          ddapc_restraint_control => qs_control%ddapc_restraint_control(i)


          CALL section_vals_val_get(ddapc_section, "STRENGTH", i_rep_section=i, &

                                    r_val=ddapc_restraint_control%strength)

          CALL section_vals_val_get(ddapc_section, "TARGET", i_rep_section=i, &

                                    r_val=ddapc_restraint_control%target)

          CALL section_vals_val_get(ddapc_section, "FUNCTIONAL_FORM", i_rep_section=i, &

                                    i_val=ddapc_restraint_control%functional_form)

          CALL section_vals_val_get(ddapc_section, "ATOMS", i_rep_section=i, &

                                    n_rep_val=n_rep)

          CALL section_vals_val_get(ddapc_section, "TYPE_OF_DENSITY", i_rep_section=i, &

                                    i_val=ddapc_restraint_control%density_type)


          jj = 0

          DO k = 1, n_rep

             CALL section_vals_val_get(ddapc_section, "ATOMS", i_rep_section=i, &

                                       i_rep_val=k, i_vals=tmplist)

             DO j = 1, SIZE(tmplist)

                jj = jj + 1

             END DO

          END DO

          IF (jj < 1) cpabort("Need at least 1 atom to use ddapc constraints")

          ddapc_restraint_control%natoms = jj

          IF (ASSOCIATED(ddapc_restraint_control%atoms)) &

             DEALLOCATE (ddapc_restraint_control%atoms)

          ALLOCATE (ddapc_restraint_control%atoms(ddapc_restraint_control%natoms))

          jj = 0

          DO k = 1, n_rep

             CALL section_vals_val_get(ddapc_section, "ATOMS", i_rep_section=i, &

                                       i_rep_val=k, i_vals=tmplist)

             DO j = 1, SIZE(tmplist)

                jj = jj + 1

                ddapc_restraint_control%atoms(jj) = tmplist(j)

             END DO

          END DO


          IF (ASSOCIATED(ddapc_restraint_control%coeff)) &

             DEALLOCATE (ddapc_restraint_control%coeff)

          ALLOCATE (ddapc_restraint_control%coeff(ddapc_restraint_control%natoms))

          ddapc_restraint_control%coeff = 1.0_dp


          CALL section_vals_val_get(ddapc_section, "COEFF", i_rep_section=i, &

                                    n_rep_val=n_rep)

          jj = 0

          DO k = 1, n_rep

             CALL section_vals_val_get(ddapc_section, "COEFF", i_rep_section=i, &

                                       i_rep_val=k, r_vals=rtmplist)

             DO j = 1, SIZE(rtmplist)

                jj = jj + 1

                IF (jj > ddapc_restraint_control%natoms) &

                   cpabort("Need the same number of coeff as there are atoms ")

                ddapc_restraint_control%coeff(jj) = rtmplist(j)

             END DO

          END DO

          IF (jj < ddapc_restraint_control%natoms .AND. jj .NE. 0) &

             cpabort("Need no or the same number of coeff as there are atoms.")

       END DO

       k = 0

       DO i = 1, SIZE(qs_control%ddapc_restraint_control)

          IF (qs_control%ddapc_restraint_control(i)%functional_form == &

              do_ddapc_constraint) k = k + 1

       END DO

       IF (k == 2) CALL cp_abort(__location__, &

                                 "Only a single constraint possible yet, try to use restraints instead ")


    END SUBROUTINE read_ddapc_section


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

 !> \brief ...

 !> \param dft_control ...

 !> \param efield_section ...

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

    SUBROUTINE read_efield_sections(dft_control, efield_section)

       TYPE(dft_control_type), POINTER                    :: dft_control

       TYPE(section_vals_type), POINTER                   :: efield_section


       CHARACTER(len=default_path_length)                 :: file_name

       INTEGER                                            :: i, io, j, n, unit_nr

       REAL(kind=dp), DIMENSION(:), POINTER               :: tmp_vals

       TYPE(efield_type), POINTER                         :: efield

       TYPE(section_vals_type), POINTER                   :: tmp_section


       DO i = 1, SIZE(dft_control%efield_fields)

          NULLIFY (dft_control%efield_fields(i)%efield)

          ALLOCATE (dft_control%efield_fields(i)%efield)

          efield => dft_control%efield_fields(i)%efield

          NULLIFY (efield%envelop_i_vars, efield%envelop_r_vars)

          CALL section_vals_val_get(efield_section, "INTENSITY", i_rep_section=i, &

                                    r_val=efield%strength)


          CALL section_vals_val_get(efield_section, "POLARISATION", i_rep_section=i, &

                                    r_vals=tmp_vals)

          ALLOCATE (efield%polarisation(SIZE(tmp_vals)))

          efield%polarisation = tmp_vals

          CALL section_vals_val_get(efield_section, "PHASE", i_rep_section=i, &

                                    r_val=efield%phase_offset)

          CALL section_vals_val_get(efield_section, "ENVELOP", i_rep_section=i, &

                                    i_val=efield%envelop_id)

          CALL section_vals_val_get(efield_section, "WAVELENGTH", i_rep_section=i, &

                                    r_val=efield%wavelength)

          CALL section_vals_val_get(efield_section, "VEC_POT_INITIAL", i_rep_section=i, &

                                    r_vals=tmp_vals)

          efield%vec_pot_initial = tmp_vals


          IF (efield%envelop_id == constant_env) THEN

             ALLOCATE (efield%envelop_i_vars(2))

             tmp_section => section_vals_get_subs_vals(efield_section, "CONSTANT_ENV", i_rep_section=i)

             CALL section_vals_val_get(tmp_section, "START_STEP", &

                                       i_val=efield%envelop_i_vars(1))

             CALL section_vals_val_get(tmp_section, "END_STEP", &

                                       i_val=efield%envelop_i_vars(2))

          ELSE IF (efield%envelop_id == gaussian_env) THEN

             ALLOCATE (efield%envelop_r_vars(2))

             tmp_section => section_vals_get_subs_vals(efield_section, "GAUSSIAN_ENV", i_rep_section=i)

             CALL section_vals_val_get(tmp_section, "T0", &

                                       r_val=efield%envelop_r_vars(1))

             CALL section_vals_val_get(tmp_section, "SIGMA", &

                                       r_val=efield%envelop_r_vars(2))

          ELSE IF (efield%envelop_id == ramp_env) THEN

             ALLOCATE (efield%envelop_i_vars(4))

             tmp_section => section_vals_get_subs_vals(efield_section, "RAMP_ENV", i_rep_section=i)

             CALL section_vals_val_get(tmp_section, "START_STEP_IN", &

                                       i_val=efield%envelop_i_vars(1))

             CALL section_vals_val_get(tmp_section, "END_STEP_IN", &

                                       i_val=efield%envelop_i_vars(2))

             CALL section_vals_val_get(tmp_section, "START_STEP_OUT", &

                                       i_val=efield%envelop_i_vars(3))

             CALL section_vals_val_get(tmp_section, "END_STEP_OUT", &

                                       i_val=efield%envelop_i_vars(4))

          ELSE IF (efield%envelop_id == custom_env) THEN

             tmp_section => section_vals_get_subs_vals(efield_section, "CUSTOM_ENV", i_rep_section=i)

             CALL section_vals_val_get(tmp_section, "EFIELD_FILE_NAME", c_val=file_name)

             CALL open_file(file_name=trim(file_name), file_action="READ", file_status="OLD", unit_number=unit_nr)

             !Determine the number of lines in file

             n = 0

             DO WHILE (.true.)

                READ (unit_nr, *, iostat=io)

                IF (io /= 0) EXIT

                n = n + 1

             END DO

             rewind(unit_nr)

             ALLOCATE (efield%envelop_r_vars(n + 1))

             !Store the timestep of the list in the first entry of the r_vars

             CALL section_vals_val_get(tmp_section, "TIMESTEP", r_val=efield%envelop_r_vars(1))

             !Read the file

             DO j = 2, n + 1

                READ (unit_nr, *) efield%envelop_r_vars(j)

                efield%envelop_r_vars(j) = cp_unit_to_cp2k(efield%envelop_r_vars(j), "volt/m")

             END DO

             CALL close_file(unit_nr)

          END IF

       END DO

    END SUBROUTINE read_efield_sections


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

 !> \brief reads the input parameters needed real time propagation

 !> \param dft_control ...

 !> \param rtp_section ...

 !> \author fschiff

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

    SUBROUTINE read_rtp_section(dft_control, rtp_section)


       TYPE(dft_control_type), INTENT(INOUT)              :: dft_control

       TYPE(section_vals_type), POINTER                   :: rtp_section


       INTEGER, DIMENSION(:), POINTER                     :: tmp

       LOGICAL                                            :: is_present

       TYPE(section_vals_type), POINTER                   :: proj_mo_section


       ALLOCATE (dft_control%rtp_control)

       CALL section_vals_val_get(rtp_section, "MAX_ITER", &

                                 i_val=dft_control%rtp_control%max_iter)

       CALL section_vals_val_get(rtp_section, "MAT_EXP", &

                                 i_val=dft_control%rtp_control%mat_exp)

       CALL section_vals_val_get(rtp_section, "ASPC_ORDER", &

                                 i_val=dft_control%rtp_control%aspc_order)

       CALL section_vals_val_get(rtp_section, "EXP_ACCURACY", &

                                 r_val=dft_control%rtp_control%eps_exp)

       CALL section_vals_val_get(rtp_section, "PROPAGATOR", &

                                 i_val=dft_control%rtp_control%propagator)

       CALL section_vals_val_get(rtp_section, "EPS_ITER", &

                                 r_val=dft_control%rtp_control%eps_ener)

       CALL section_vals_val_get(rtp_section, "INITIAL_WFN", &

                                 i_val=dft_control%rtp_control%initial_wfn)

       CALL section_vals_val_get(rtp_section, "HFX_BALANCE_IN_CORE", &

                                 l_val=dft_control%rtp_control%hfx_redistribute)

       CALL section_vals_val_get(rtp_section, "APPLY_WFN_MIX_INIT_RESTART", &

                                 l_val=dft_control%rtp_control%apply_wfn_mix_init_restart)

       CALL section_vals_val_get(rtp_section, "APPLY_DELTA_PULSE", &

                                 l_val=dft_control%rtp_control%apply_delta_pulse)

       CALL section_vals_val_get(rtp_section, "APPLY_DELTA_PULSE_MAG", &

                                 l_val=dft_control%rtp_control%apply_delta_pulse_mag)

       CALL section_vals_val_get(rtp_section, "VELOCITY_GAUGE", &

                                 l_val=dft_control%rtp_control%velocity_gauge)

       CALL section_vals_val_get(rtp_section, "VG_COM_NL", &

                                 l_val=dft_control%rtp_control%nl_gauge_transform)

       CALL section_vals_val_get(rtp_section, "PERIODIC", &

                                 l_val=dft_control%rtp_control%periodic)

       CALL section_vals_val_get(rtp_section, "DENSITY_PROPAGATION", &

                                 l_val=dft_control%rtp_control%linear_scaling)

       CALL section_vals_val_get(rtp_section, "MCWEENY_MAX_ITER", &

                                 i_val=dft_control%rtp_control%mcweeny_max_iter)

       CALL section_vals_val_get(rtp_section, "ACCURACY_REFINEMENT", &

                                 i_val=dft_control%rtp_control%acc_ref)

       CALL section_vals_val_get(rtp_section, "MCWEENY_EPS", &

                                 r_val=dft_control%rtp_control%mcweeny_eps)

       CALL section_vals_val_get(rtp_section, "DELTA_PULSE_SCALE", &

                                 r_val=dft_control%rtp_control%delta_pulse_scale)

       CALL section_vals_val_get(rtp_section, "DELTA_PULSE_DIRECTION", &

                                 i_vals=tmp)

       dft_control%rtp_control%delta_pulse_direction = tmp

       CALL section_vals_val_get(rtp_section, "SC_CHECK_START", &

                                 i_val=dft_control%rtp_control%sc_check_start)

       proj_mo_section => section_vals_get_subs_vals(rtp_section, "PRINT%PROJECTION_MO")

       CALL section_vals_get(proj_mo_section, explicit=is_present)

       IF (is_present) THEN

          IF (dft_control%rtp_control%linear_scaling) &

             CALL cp_abort(__location__, &

                           "You have defined a time dependent projection of mos, but "// &

                           "only the density matrix is propagated (DENSITY_PROPAGATION "// &

                           ".TRUE.). Please either use MO-based real time DFT or do not "// &

                           "define any PRINT%PROJECTION_MO section")

          dft_control%rtp_control%is_proj_mo = .true.

       ELSE

          dft_control%rtp_control%is_proj_mo = .false.

       END IF


    END SUBROUTINE read_rtp_section


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

 !> \brief Parses the BLOCK_LIST keywords from the ADMM section

 !> \param admm_control ...

 !> \param dft_section ...

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

    SUBROUTINE read_admm_block_list(admm_control, dft_section)

       TYPE(admm_control_type), POINTER                   :: admm_control

       TYPE(section_vals_type), POINTER                   :: dft_section


       INTEGER                                            :: irep, list_size, n_rep

       INTEGER, DIMENSION(:), POINTER                     :: tmplist


       NULLIFY (tmplist)


       CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%BLOCK_LIST", &

                                 n_rep_val=n_rep)


       ALLOCATE (admm_control%blocks(n_rep))


       DO irep = 1, n_rep

          CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%BLOCK_LIST", &

                                    i_rep_val=irep, i_vals=tmplist)

          list_size = SIZE(tmplist)

          ALLOCATE (admm_control%blocks(irep)%list(list_size))

          admm_control%blocks(irep)%list(:) = tmplist(:)

       END DO


    END SUBROUTINE read_admm_block_list


 END MODULE cp_control_utils

bibliography
collects all references to literature in CP2K as new algorithms / method are included from literature...
Definition: bibliography.F:28

bibliography::vandevondele2005b
integer, save, public vandevondele2005b
Definition: bibliography.F:43

bibliography::umari2002
integer, save, public umari2002
Definition: bibliography.F:43

bibliography::yin2017
integer, save, public yin2017
Definition: bibliography.F:43

bibliography::stewart2007
integer, save, public stewart2007
Definition: bibliography.F:43

bibliography::stengel2009
integer, save, public stengel2009
Definition: bibliography.F:43

bibliography::vandevondele2005a
integer, save, public vandevondele2005a
Definition: bibliography.F:43

bibliography::grimme2017
integer, save, public grimme2017
Definition: bibliography.F:43

bibliography::lippert1999
integer, save, public lippert1999
Definition: bibliography.F:43

bibliography::dewar1977
integer, save, public dewar1977
Definition: bibliography.F:43

bibliography::elstner1998
integer, save, public elstner1998
Definition: bibliography.F:43

bibliography::vanvoorhis2015
integer, save, public vanvoorhis2015
Definition: bibliography.F:43

bibliography::repasky2002
integer, save, public repasky2002
Definition: bibliography.F:43

bibliography::hu2007
integer, save, public hu2007
Definition: bibliography.F:43

bibliography::andreussi2012
integer, save, public andreussi2012
Definition: bibliography.F:43

bibliography::rocha2006
integer, save, public rocha2006
Definition: bibliography.F:43

bibliography::lippert1997
integer, save, public lippert1997
Definition: bibliography.F:43

bibliography::fattebert2002
integer, save, public fattebert2002
Definition: bibliography.F:43

bibliography::thiel1992
integer, save, public thiel1992
Definition: bibliography.F:43

bibliography::porezag1995
integer, save, public porezag1995
Definition: bibliography.F:43

bibliography::souza2002
integer, save, public souza2002
Definition: bibliography.F:43

bibliography::schenter2008
integer, save, public schenter2008
Definition: bibliography.F:43

bibliography::krack2000
integer, save, public krack2000
Definition: bibliography.F:43

bibliography::dewar1985
integer, save, public dewar1985
Definition: bibliography.F:43

bibliography::stewart1989
integer, save, public stewart1989
Definition: bibliography.F:43

bibliography::seifert1996
integer, save, public seifert1996
Definition: bibliography.F:43

bibliography::zhechkov2005
integer, save, public zhechkov2005
Definition: bibliography.F:43

cp_control_types
Defines control structures, which contain the parameters and the settings for the DFT-based calculati...
Definition: cp_control_types.F:12

cp_control_types::dft_control_create
subroutine, public dft_control_create(dft_control)
allocates and perform a very basic initialization
Definition: cp_control_types.F:767

cp_control_types::expot_control_create
subroutine, public expot_control_create(expot_control)
...
Definition: cp_control_types.F:1143

cp_control_types::maxwell_control_create
subroutine, public maxwell_control_create(maxwell_control)
...
Definition: cp_control_types.F:1172

cp_control_types::ddapc_control_create
subroutine, public ddapc_control_create(ddapc_restraint_control)
create the ddapc_restraint_type
Definition: cp_control_types.F:700

cp_control_types::admm_control_create
subroutine, public admm_control_create(admm_control)
...
Definition: cp_control_types.F:1119

cp_control_types::tddfpt_control_create
subroutine, public tddfpt_control_create(tddfpt_control)
...
Definition: cp_control_types.F:895

cp_control_utils
Utilities to set up the control types.
Definition: cp_control_utils.F:11

cp_control_utils::write_qs_control
subroutine, public write_qs_control(qs_control, dft_section)
Purpose: Write the QS control parameters to the output unit.
Definition: cp_control_utils.F:1976

cp_control_utils::read_tddfpt2_control
subroutine, public read_tddfpt2_control(t_control, t_section, qs_control)
Read TDDFPT-related input parameters.
Definition: cp_control_utils.F:1348

cp_control_utils::read_dft_control
subroutine, public read_dft_control(dft_control, dft_section)
...
Definition: cp_control_utils.F:101

cp_control_utils::read_qs_section
subroutine, public read_qs_section(qs_control, qs_section)
...
Definition: cp_control_utils.F:715

cp_control_utils::write_admm_control
subroutine, public write_admm_control(admm_control, dft_section)
Write the ADMM control parameters to the output unit.
Definition: cp_control_utils.F:1809

cp_control_utils::read_tddfpt_control
subroutine, public read_tddfpt_control(t_control, dft_section)
...
Definition: cp_control_utils.F:1309

cp_control_utils::write_dft_control
subroutine, public write_dft_control(dft_control, dft_section)
Write the DFT control parameters to the output unit.
Definition: cp_control_utils.F:1572

cp_control_utils::read_ddapc_section
subroutine, public read_ddapc_section(qs_control, qs_section, ddapc_restraint_section)
reads the input parameters needed for ddapc.
Definition: cp_control_utils.F:2221

cp_control_utils::read_mgrid_section
subroutine, public read_mgrid_section(qs_control, dft_section)
...
Definition: cp_control_utils.F:625

cp_files
Utility routines to open and close files. Tracking of preconnections.
Definition: cp_files.F:16

cp_files::open_file
subroutine, public open_file(file_name, file_status, file_form, file_action, file_position, file_pad, unit_number, debug, skip_get_unit_number, file_access)
Opens the requested file using a free unit number.
Definition: cp_files.F:308

cp_files::close_file
subroutine, public close_file(unit_number, file_status, keep_preconnection)
Close an open file given by its logical unit number. Optionally, keep the file and unit preconnected.
Definition: cp_files.F:119

cp_log_handling
various routines to log and control the output. The idea is that decisions about where to log should ...
Definition: cp_log_handling.F:41

cp_log_handling::cp_get_default_logger
type(cp_logger_type) function, pointer, public cp_get_default_logger()
returns the default logger
Definition: cp_log_handling.F:234

cp_output_handling
routines to handle the output, The idea is to remove the decision of wheter to output and what to out...
Definition: cp_output_handling.F:25

cp_output_handling::cp_print_key_unit_nr
integer function, public cp_print_key_unit_nr(logger, basis_section, print_key_path, extension, middle_name, local, log_filename, ignore_should_output, file_form, file_position, file_action, file_status, do_backup, on_file, is_new_file, mpi_io, fout)
...
Definition: cp_output_handling.F:803

cp_output_handling::cp_print_key_finished_output
subroutine, public cp_print_key_finished_output(unit_nr, logger, basis_section, print_key_path, local, ignore_should_output, on_file, mpi_io)
should be called after you finish working with a unit obtained with cp_print_key_unit_nr,...
Definition: cp_output_handling.F:1013

cp_units
unit conversion facility
Definition: cp_units.F:30

cp_units::cp_unit_from_cp2k
real(kind=dp) function, public cp_unit_from_cp2k(value, unit_str, defaults, power)
converts from the internal cp2k units to the given unit
Definition: cp_units.F:1179

cp_units::cp_unit_to_cp2k
real(kind=dp) function, public cp_unit_to_cp2k(value, unit_str, defaults, power)
converts to the internal cp2k units to the given unit
Definition: cp_units.F:1150

force_fields_input
Definition: force_fields_input.F:20

force_fields_input::read_gp_section
subroutine, public read_gp_section(nonbonded, section, start)
Reads the GENPOT - generic potential section.
Definition: force_fields_input.F:1366

input_constants
collects all constants needed in input so that they can be used without circular dependencies
Definition: input_constants.F:17

input_constants::sic_list_unpaired
integer, parameter, public sic_list_unpaired
Definition: input_constants.F:573

input_constants::sic_mauri_spz
integer, parameter, public sic_mauri_spz
Definition: input_constants.F:568

input_constants::do_method_ofgpw
integer, parameter, public do_method_ofgpw
Definition: input_constants.F:250

input_constants::do_admm_purify_mo_no_diag
integer, parameter, public do_admm_purify_mo_no_diag
Definition: input_constants.F:848

input_constants::do_se_lr_ewald_gks
integer, parameter, public do_se_lr_ewald_gks
Definition: input_constants.F:281

input_constants::do_admm_aux_exch_func_opt_libxc
integer, parameter, public do_admm_aux_exch_func_opt_libxc
Definition: input_constants.F:863

input_constants::do_s2_restraint
integer, parameter, public do_s2_restraint
Definition: input_constants.F:754

input_constants::do_admm_purify_none
integer, parameter, public do_admm_purify_none
Definition: input_constants.F:848

input_constants::do_method_rigpw
integer, parameter, public do_method_rigpw
Definition: input_constants.F:250

input_constants::do_s2_constraint
integer, parameter, public do_s2_constraint
Definition: input_constants.F:754

input_constants::use_mom_ref_user
integer, parameter, public use_mom_ref_user
Definition: input_constants.F:496

input_constants::do_method_gpw
integer, parameter, public do_method_gpw
Definition: input_constants.F:250

input_constants::gapw_1c_large
integer, parameter, public gapw_1c_large
Definition: input_constants.F:229

input_constants::do_method_pdg
integer, parameter, public do_method_pdg
Definition: input_constants.F:250

input_constants::do_admm_purify_none_dm
integer, parameter, public do_admm_purify_none_dm
Definition: input_constants.F:848

input_constants::do_method_pnnl
integer, parameter, public do_method_pnnl
Definition: input_constants.F:250

input_constants::do_ddapc_constraint
integer, parameter, public do_ddapc_constraint
Definition: input_constants.F:714

input_constants::do_se_lr_none
integer, parameter, public do_se_lr_none
Definition: input_constants.F:281

input_constants::do_admm_purify_mcweeny
integer, parameter, public do_admm_purify_mcweeny
Definition: input_constants.F:848

input_constants::do_se_lr_ewald
integer, parameter, public do_se_lr_ewald
Definition: input_constants.F:281

input_constants::do_admm_blocking_purify_full
integer, parameter, public do_admm_blocking_purify_full
Definition: input_constants.F:857

input_constants::ramp_env
integer, parameter, public ramp_env
Definition: input_constants.F:931

input_constants::do_se_is_kdso_d
integer, parameter, public do_se_is_kdso_d
Definition: input_constants.F:277

input_constants::gapw_1c_medium
integer, parameter, public gapw_1c_medium
Definition: input_constants.F:229

input_constants::do_admm_aux_exch_func_sx_libxc
integer, parameter, public do_admm_aux_exch_func_sx_libxc
Definition: input_constants.F:863

input_constants::admm2_type
integer, parameter, public admm2_type
Definition: input_constants.F:878

input_constants::sic_list_all
integer, parameter, public sic_list_all
Definition: input_constants.F:573

input_constants::constant_env
integer, parameter, public constant_env
Definition: input_constants.F:931

input_constants::tddfpt_excitations
integer, parameter, public tddfpt_excitations
Definition: input_constants.F:590

input_constants::sic_eo
integer, parameter, public sic_eo
Definition: input_constants.F:568

input_constants::sccs_derivative_cd5
integer, parameter, public sccs_derivative_cd5
Definition: input_constants.F:1169

input_constants::do_admm_aux_exch_func_bee
integer, parameter, public do_admm_aux_exch_func_bee
Definition: input_constants.F:863

input_constants::no_admm_type
integer, parameter, public no_admm_type
Definition: input_constants.F:878

input_constants::do_admm_blocked_projection
integer, parameter, public do_admm_blocked_projection
Definition: input_constants.F:857

input_constants::do_admm_basis_projection
integer, parameter, public do_admm_basis_projection
Definition: input_constants.F:857

input_constants::do_method_rm1
integer, parameter, public do_method_rm1
Definition: input_constants.F:250

input_constants::do_admm_aux_exch_func_default_libxc
integer, parameter, public do_admm_aux_exch_func_default_libxc
Definition: input_constants.F:863

input_constants::do_admm_aux_exch_func_opt
integer, parameter, public do_admm_aux_exch_func_opt
Definition: input_constants.F:863

input_constants::gapw_1c_small
integer, parameter, public gapw_1c_small
Definition: input_constants.F:229

input_constants::do_admm_aux_exch_func_none
integer, parameter, public do_admm_aux_exch_func_none
Definition: input_constants.F:863

input_constants::do_admm_purify_cauchy_subspace
integer, parameter, public do_admm_purify_cauchy_subspace
Definition: input_constants.F:848

input_constants::do_method_pm3
integer, parameter, public do_method_pm3
Definition: input_constants.F:250

input_constants::do_admm_aux_exch_func_bee_libxc
integer, parameter, public do_admm_aux_exch_func_bee_libxc
Definition: input_constants.F:863

input_constants::admm1_type
integer, parameter, public admm1_type
Definition: input_constants.F:878

input_constants::do_admm_aux_exch_func_pbex_libxc
integer, parameter, public do_admm_aux_exch_func_pbex_libxc
Definition: input_constants.F:863

input_constants::do_method_mndo
integer, parameter, public do_method_mndo
Definition: input_constants.F:250

input_constants::gapw_1c_orb
integer, parameter, public gapw_1c_orb
Definition: input_constants.F:229

input_constants::do_admm_aux_exch_func_default
integer, parameter, public do_admm_aux_exch_func_default
Definition: input_constants.F:863

input_constants::do_pwgrid_ns_fullspace
integer, parameter, public do_pwgrid_ns_fullspace
Definition: input_constants.F:235

input_constants::gapw_1c_very_large
integer, parameter, public gapw_1c_very_large
Definition: input_constants.F:229

input_constants::do_method_gapw
integer, parameter, public do_method_gapw
Definition: input_constants.F:250

input_constants::admms_type
integer, parameter, public admms_type
Definition: input_constants.F:878

input_constants::do_admm_charge_constrained_projection
integer, parameter, public do_admm_charge_constrained_projection
Definition: input_constants.F:857

input_constants::do_admm_purify_cauchy
integer, parameter, public do_admm_purify_cauchy
Definition: input_constants.F:848

input_constants::sccs_fattebert_gygi
integer, parameter, public sccs_fattebert_gygi
Definition: input_constants.F:1165

input_constants::gaussian_env
integer, parameter, public gaussian_env
Definition: input_constants.F:931

input_constants::sccs_derivative_cd7
integer, parameter, public sccs_derivative_cd7
Definition: input_constants.F:1169

input_constants::do_method_mndod
integer, parameter, public do_method_mndod
Definition: input_constants.F:250

input_constants::do_method_am1
integer, parameter, public do_method_am1
Definition: input_constants.F:250

input_constants::do_method_dftb
integer, parameter, public do_method_dftb
Definition: input_constants.F:250

input_constants::tddfpt_dipole_length
integer, parameter, public tddfpt_dipole_length
Definition: input_constants.F:694

input_constants::sccs_derivative_fft
integer, parameter, public sccs_derivative_fft
Definition: input_constants.F:1169

input_constants::tddfpt_kernel_stda
integer, parameter, public tddfpt_kernel_stda
Definition: input_constants.F:581

input_constants::do_pwgrid_spherical
integer, parameter, public do_pwgrid_spherical
Definition: input_constants.F:235

input_constants::do_se_lr_ewald_r3
integer, parameter, public do_se_lr_ewald_r3
Definition: input_constants.F:281

input_constants::do_se_is_kdso
integer, parameter, public do_se_is_kdso
Definition: input_constants.F:277

input_constants::do_admm_purify_mo_diag
integer, parameter, public do_admm_purify_mo_diag
Definition: input_constants.F:848

input_constants::do_method_lrigpw
integer, parameter, public do_method_lrigpw
Definition: input_constants.F:250

input_constants::sic_mauri_us
integer, parameter, public sic_mauri_us
Definition: input_constants.F:568

input_constants::sic_none
integer, parameter, public sic_none
Definition: input_constants.F:568

input_constants::do_se_is_slater
integer, parameter, public do_se_is_slater
Definition: input_constants.F:277

input_constants::custom_env
integer, parameter, public custom_env
Definition: input_constants.F:931

input_constants::do_method_xtb
integer, parameter, public do_method_xtb
Definition: input_constants.F:250

input_constants::do_ddapc_restraint
integer, parameter, public do_ddapc_restraint
Definition: input_constants.F:714

input_constants::do_pwgrid_ns_halfspace
integer, parameter, public do_pwgrid_ns_halfspace
Definition: input_constants.F:235

input_constants::sccs_derivative_cd3
integer, parameter, public sccs_derivative_cd3
Definition: input_constants.F:1169

input_constants::do_method_pm6fm
integer, parameter, public do_method_pm6fm
Definition: input_constants.F:250

input_constants::admmq_type
integer, parameter, public admmq_type
Definition: input_constants.F:878

input_constants::sccs_andreussi
integer, parameter, public sccs_andreussi
Definition: input_constants.F:1165

input_constants::sic_ad
integer, parameter, public sic_ad
Definition: input_constants.F:568

input_constants::do_admm_exch_scaling_none
integer, parameter, public do_admm_exch_scaling_none
Definition: input_constants.F:875

input_constants::admmp_type
integer, parameter, public admmp_type
Definition: input_constants.F:878

input_constants::do_method_gapw_xc
integer, parameter, public do_method_gapw_xc
Definition: input_constants.F:250

input_constants::do_admm_exch_scaling_merlot
integer, parameter, public do_admm_exch_scaling_merlot
Definition: input_constants.F:875

input_constants::real_time_propagation
integer, parameter, public real_time_propagation
Definition: input_constants.F:121

input_constants::numerical
integer, parameter, public numerical
Definition: input_constants.F:153

input_constants::do_method_pm6
integer, parameter, public do_method_pm6
Definition: input_constants.F:250

input_constants::do_admm_aux_exch_func_pbex
integer, parameter, public do_admm_aux_exch_func_pbex
Definition: input_constants.F:863

input_constants::slater
integer, parameter, public slater
Definition: input_constants.F:153

input_cp2k_check
checks the input and perform some automatic "magic" on it
Definition: input_cp2k_check.F:14

input_cp2k_check::xc_functionals_expand
subroutine, public xc_functionals_expand(functionals, xc_section)
expand a shortcutted functional section
Definition: input_cp2k_check.F:146

input_cp2k_dft
function that build the dft section of the input
Definition: input_cp2k_dft.F:14

input_cp2k_dft::create_dft_section
subroutine, public create_dft_section(section)
creates the dft section
Definition: input_cp2k_dft.F:187

input_enumeration_types
represents an enumeration, i.e. a mapping between integers and strings
Definition: input_enumeration_types.F:14

input_enumeration_types::enum_i2c
character(len=default_string_length) function, public enum_i2c(enum, i)
maps an integer to a string
Definition: input_enumeration_types.F:152

input_keyword_types
represents keywords in an input
Definition: input_keyword_types.F:14

input_keyword_types::keyword_get
subroutine, public keyword_get(keyword, names, usage, description, type_of_var, n_var, default_value, lone_keyword_value, repeats, enum, citations)
...
Definition: input_keyword_types.F:467

input_section_types
objects that represent the structure of input sections and the data contained in an input section
Definition: input_section_types.F:15

input_section_types::section_vals_val_set
subroutine, public section_vals_val_set(section_vals, keyword_name, i_rep_section, i_rep_val, val, l_val, i_val, r_val, c_val, l_vals_ptr, i_vals_ptr, r_vals_ptr, c_vals_ptr)
sets the requested value
Definition: input_section_types.F:1216

input_section_types::section_get_ival
integer function, public section_get_ival(section_vals, keyword_name)
...
Definition: input_section_types.F:973

input_section_types::section_vals_get_subs_vals
recursive type(section_vals_type) function, pointer, public section_vals_get_subs_vals(section_vals, subsection_name, i_rep_section, can_return_null)
returns the values of the requested subsection
Definition: input_section_types.F:724

input_section_types::section_release
recursive subroutine, public section_release(section)
releases the given keyword list (see doc/ReferenceCounting.html)
Definition: input_section_types.F:231

input_section_types::section_get_keyword
recursive type(keyword_type) function, pointer, public section_get_keyword(section, keyword_name)
returns the requested keyword
Definition: input_section_types.F:471

input_section_types::section_vals_get
subroutine, public section_vals_get(section_vals, ref_count, n_repetition, n_subs_vals_rep, section, explicit)
returns various attributes about the section_vals
Definition: input_section_types.F:697

input_section_types::section_vals_val_get
subroutine, public section_vals_val_get(section_vals, keyword_name, i_rep_section, i_rep_val, n_rep_val, val, l_val, i_val, r_val, c_val, l_vals, i_vals, r_vals, c_vals, explicit)
returns the requested value
Definition: input_section_types.F:1040

kinds
Defines the basic variable types.
Definition: kinds.F:23

kinds::dp
integer, parameter, public dp
Definition: kinds.F:34

kinds::default_string_length
integer, parameter, public default_string_length
Definition: kinds.F:57

kinds::default_path_length
integer, parameter, public default_path_length
Definition: kinds.F:58

mathconstants
Definition of mathematical constants and functions.
Definition: mathconstants.F:16

mathconstants::fourpi
real(kind=dp), parameter, public fourpi
Definition: mathconstants.F:113

pair_potential_types
Definition: pair_potential_types.F:14

pair_potential_types::pair_potential_reallocate
subroutine, public pair_potential_reallocate(p, lb1_new, ub1_new, lj, lj_charmm, williams, goodwin, eam, quip, nequip, allegro, bmhft, bmhftd, ipbv, buck4r, buckmo, gp, tersoff, siepmann, gal, gal21, tab, deepmd)
Cleans the potential parameter type.
Definition: pair_potential_types.F:1109

periodic_table
Periodic Table related data definitions.
Definition: periodic_table.F:28

periodic_table::get_ptable_info
subroutine, public get_ptable_info(symbol, number, amass, ielement, covalent_radius, metallic_radius, vdw_radius, found)
Pass information about the kind given the element symbol.
Definition: periodic_table.F:85

qs_cdft_utils
Utility subroutines for CDFT calculations.
Definition: qs_cdft_utils.F:14

qs_cdft_utils::read_cdft_control_section
subroutine, public read_cdft_control_section(qs_control, cdft_control_section)
reads the input parameters needed for CDFT with OT
Definition: qs_cdft_utils.F:718

string_utilities
Utilities for string manipulations.
Definition: string_utilities.F:16

string_utilities::uppercase
elemental subroutine, public uppercase(string)
Convert all lower case characters in a string to upper case.
Definition: string_utilities.F:3361

util
All kind of helpful little routines.
Definition: util.F:14

xc_input_constants
input constants for xc
Definition: xc_input_constants.F:10

xc_input_constants::xc_deriv_collocate
integer, parameter, public xc_deriv_collocate
Definition: xc_input_constants.F:14

xc_write_output
Writes information on XC functionals to output.
Definition: xc_write_output.F:11

xc_write_output::xc_write
subroutine, public xc_write(iounit, xc_section, lsd)
...
Definition: xc_write_output.F:42

xc
Exchange and Correlation functional calculations.
Definition: xc.F:17

xc::xc_uses_norm_drho
logical function, public xc_uses_norm_drho(xc_fun_section, lsd)
...
Definition: xc.F:111

xc::xc_uses_kinetic_energy_density
logical function, public xc_uses_kinetic_energy_density(xc_fun_section, lsd)
...
Definition: xc.F:91