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cp_control_utils.F
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1!--------------------------------------------------------------------------------------------------!
2! CP2K: A general program to perform molecular dynamics simulations !
3! Copyright 2000-2026 CP2K developers group <https://cp2k.org> !
4! !
5! SPDX-License-Identifier: GPL-2.0-or-later !
6!--------------------------------------------------------------------------------------------------!
7
8! **************************************************************************************************
9!> \brief Utilities to set up the control types
10! **************************************************************************************************
11MODULE cp_control_utils
12 USE bibliography, ONLY: &
13 andreussi2012, dewar1977, dewar1985, elstner1998, fattebert2002, grimme2017, hu2007, &
14 katbashev2025, krack2000, lippert1997, lippert1999, porezag1995, pracht2019, repasky2002, &
15 rocha2006, schenter2008, seifert1996, souza2002, stengel2009, stewart1989, stewart2007, &
16 thiel1992, umari2002, vanvoorhis2015, vandevondele2005a, vandevondele2005b, yin2017, &
17 zhechkov2005, cite_reference
18 USE cell_types, ONLY: cell_transform_input_cartesian,&
19 cell_type
20 USE cp_control_types, ONLY: &
21 admm_control_create, admm_control_type, ddapc_control_create, ddapc_restraint_type, &
22 dft_control_create, dft_control_type, efield_type, expot_control_create, &
23 maxwell_control_create, qs_control_type, rixs_control_type, tddfpt2_control_type, &
24 xtb_control_type, xtb_reference_cli_type
25 USE cp_files, ONLY: close_file,&
26 open_file
27 USE cp_log_handling, ONLY: cp_get_default_logger,&
28 cp_logger_type
29 USE cp_output_handling, ONLY: cp_print_key_finished_output,&
30 cp_print_key_unit_nr
31 USE cp_parser_methods, ONLY: parser_read_line
32 USE cp_parser_types, ONLY: cp_parser_type,&
33 parser_create,&
34 parser_release,&
35 parser_reset
36 USE cp_units, ONLY: cp_unit_from_cp2k,&
37 cp_unit_to_cp2k
38 USE eeq_input, ONLY: read_eeq_param
39 USE force_fields_input, ONLY: read_gp_section
40 USE input_constants, ONLY: &
41 admm1_type, admm2_type, admmp_type, admmq_type, admms_type, constant_env, custom_env, &
42 do_admm_aux_exch_func_bee, do_admm_aux_exch_func_bee_libxc, do_admm_aux_exch_func_default, &
43 do_admm_aux_exch_func_default_libxc, do_admm_aux_exch_func_none, &
44 do_admm_aux_exch_func_opt, do_admm_aux_exch_func_opt_libxc, do_admm_aux_exch_func_pbex, &
45 do_admm_aux_exch_func_pbex_libxc, do_admm_aux_exch_func_sx_libxc, &
46 do_admm_basis_projection, do_admm_blocked_projection, do_admm_blocking_purify_full, &
47 do_admm_charge_constrained_projection, do_admm_exch_scaling_merlot, &
48 do_admm_exch_scaling_none, do_admm_purify_cauchy, do_admm_purify_cauchy_subspace, &
49 do_admm_purify_mcweeny, do_admm_purify_mo_diag, do_admm_purify_mo_no_diag, &
50 do_admm_purify_none, do_admm_purify_none_dm, do_ddapc_constraint, do_ddapc_restraint, &
51 do_method_am1, do_method_dftb, do_method_gapw, do_method_gapw_xc, do_method_gpw, &
52 do_method_lrigpw, do_method_mndo, do_method_mndod, do_method_ofgpw, do_method_pdg, &
53 do_method_pm3, do_method_pm6, do_method_pm6fm, do_method_pnnl, do_method_rigpw, &
54 do_method_rm1, do_method_xtb, do_pwgrid_ns_fullspace, do_pwgrid_ns_halfspace, &
55 do_pwgrid_spherical, do_s2_constraint, do_s2_restraint, do_se_is_kdso, do_se_is_kdso_d, &
56 do_se_is_slater, do_se_lr_ewald, do_se_lr_ewald_gks, do_se_lr_ewald_r3, do_se_lr_none, &
57 gapw_1c_large, gapw_1c_medium, gapw_1c_orb, gapw_1c_small, gapw_1c_very_large, &
58 gaussian_env, gfn1xtb, gfn_tblite, kg_tnadd_embed, kg_tnadd_embed_ri, no_admm_type, &
59 numerical, ramp_env, real_time_propagation, rtp_method_bse, sccs_andreussi, &
60 sccs_derivative_cd3, sccs_derivative_cd5, sccs_derivative_cd7, sccs_derivative_fft, &
61 sccs_fattebert_gygi, sic_ad, sic_eo, sic_list_all, sic_list_unpaired, sic_mauri_spz, &
62 sic_mauri_us, sic_none, slater, tblite_cli_born_kernel_auto, &
63 tblite_cli_solution_state_gsolv, tblite_cli_solvation_alpb, tblite_cli_solvation_cpcm, &
64 tblite_cli_solvation_gb, tblite_cli_solvation_gbe, tblite_cli_solvation_gbsa, &
65 tblite_guess_ceh, tblite_mixer_memory_inherit, tblite_scc_mixer_auto, &
66 tblite_scc_mixer_cp2k, tblite_scc_mixer_none, tblite_scc_mixer_tblite, tblite_solver_gvd, &
67 tblite_solver_gvr, tddfpt_dipole_length, tddfpt_kernel_stda, use_mom_ref_user, &
68 xtb_vdw_type_d3, xtb_vdw_type_d4, xtb_vdw_type_none
69 USE input_cp2k_check, ONLY: xc_functionals_expand
70 USE input_cp2k_dft, ONLY: create_dft_section
71 USE input_enumeration_types, ONLY: enum_i2c,&
72 enumeration_type
73 USE input_keyword_types, ONLY: keyword_get,&
74 keyword_type
75 USE input_section_types, ONLY: &
76 section_get_ival, section_get_keyword, section_release, section_type, section_vals_get, &
77 section_vals_get_subs_vals, section_vals_type, section_vals_val_get, section_vals_val_set
78 USE kinds, ONLY: default_path_length,&
79 default_string_length,&
80 dp
81 USE mathconstants, ONLY: fourpi
82 USE pair_potential_types, ONLY: pair_potential_reallocate
83 USE periodic_table, ONLY: get_ptable_info
84 USE qs_cdft_utils, ONLY: read_cdft_control_section
85 USE smeagol_control_types, ONLY: read_smeagol_control
86 USE string_utilities, ONLY: uppercase
87 USE util, ONLY: sort
88 USE xas_tdp_types, ONLY: read_xas_tdp_control
89 USE xc, ONLY: xc_uses_kinetic_energy_density,&
90 xc_uses_norm_drho
91 USE xc_input_constants, ONLY: xc_deriv_collocate
92 USE xc_write_output, ONLY: xc_write
93#include "./base/base_uses.f90"
94
95 IMPLICIT NONE
96
97 PRIVATE
98
99 CHARACTER(len=*), PARAMETER, PRIVATE :: moduleN = 'cp_control_utils'
100
101 PUBLIC :: read_dft_control, &
102 read_rixs_control, &
103 read_mgrid_section, &
104 read_qs_section, &
105 read_tddfpt2_control, &
106 write_dft_control, &
107 write_qs_control, &
108 write_admm_control, &
109 read_ddapc_section
110CONTAINS
111
112! **************************************************************************************************
113!> \brief ...
114!> \param dft_control ...
115!> \param dft_section ...
116!> \param cell ...
117! **************************************************************************************************
118 SUBROUTINE read_dft_control(dft_control, dft_section, cell)
119 TYPE(dft_control_type), POINTER :: dft_control
120 TYPE(section_vals_type), POINTER :: dft_section
121 TYPE(cell_type), OPTIONAL, POINTER :: cell
122
123 CHARACTER(len=default_path_length) :: basis_set_file_name, &
124 intensities_file_name, &
125 potential_file_name
126 CHARACTER(LEN=default_string_length), &
127 DIMENSION(:), POINTER :: tmpstringlist
128 INTEGER :: admmtype, irep, isize, kg_tnadd_method, &
129 method_id, nrep, xc_deriv_method_id
130 LOGICAL :: at_end, do_hfx, do_ot, do_rpa_admm, do_rtp, exopt1, exopt2, exopt3, explicit, &
131 is_present, l_param, local_moment_possible, native_skala_grid, not_se, was_present
132 REAL(kind=dp) :: density_cut, gradient_cut, tau_cut
133 REAL(kind=dp), DIMENSION(:), POINTER :: pol
134 TYPE(cp_logger_type), POINTER :: logger
135 TYPE(cp_parser_type) :: parser
136 TYPE(section_vals_type), POINTER :: hairy_probes_section, hfx_section, kg_xc_fun_section, &
137 kg_xc_section, maxwell_section, sccs_section, scf_section, tmp_section, xc_fun_section, &
138 xc_gauxc_subsection, xc_section
139
140 was_present = .false.
141
142 logger => cp_get_default_logger()
143
144 NULLIFY (kg_xc_fun_section, kg_xc_section, tmp_section, xc_fun_section, xc_section, xc_gauxc_subsection)
145 ALLOCATE (dft_control)
146 CALL dft_control_create(dft_control)
147 ! determine wheather this is a semiempirical or DFTB run
148 ! --> (no XC section needs to be provided)
149 not_se = .true.
150 CALL section_vals_val_get(dft_section, "QS%METHOD", i_val=method_id)
151 SELECT CASE (method_id)
152 CASE (do_method_dftb, do_method_xtb, do_method_mndo, do_method_am1, do_method_pm3, do_method_pnnl, &
153 do_method_pm6, do_method_pm6fm, do_method_pdg, do_method_rm1, do_method_mndod)
154 not_se = .false.
155 END SELECT
156 ! Check for XC section and XC_FUNCTIONAL section
157 xc_section => section_vals_get_subs_vals(dft_section, "XC")
158 CALL section_vals_get(xc_section, explicit=is_present)
159 IF (.NOT. is_present .AND. not_se) THEN
160 cpabort("XC section missing.")
161 END IF
162 IF (is_present) THEN
163 CALL section_vals_val_get(xc_section, "density_cutoff", r_val=density_cut)
164 CALL section_vals_val_get(xc_section, "gradient_cutoff", r_val=gradient_cut)
165 CALL section_vals_val_get(xc_section, "tau_cutoff", r_val=tau_cut)
166 ! Perform numerical stability checks and possibly correct the issues
167 IF (density_cut <= epsilon(0.0_dp)*100.0_dp) &
168 CALL cp_warn(__location__, &
169 "DENSITY_CUTOFF lower than 100*EPSILON, where EPSILON is the machine precision. "// &
170 "This may lead to numerical problems. Setting up shake_tol to 100*EPSILON! ")
171 density_cut = max(epsilon(0.0_dp)*100.0_dp, density_cut)
172 IF (gradient_cut <= epsilon(0.0_dp)*100.0_dp) &
173 CALL cp_warn(__location__, &
174 "GRADIENT_CUTOFF lower than 100*EPSILON, where EPSILON is the machine precision. "// &
175 "This may lead to numerical problems. Setting up shake_tol to 100*EPSILON! ")
176 gradient_cut = max(epsilon(0.0_dp)*100.0_dp, gradient_cut)
177 IF (tau_cut <= epsilon(0.0_dp)*100.0_dp) &
178 CALL cp_warn(__location__, &
179 "TAU_CUTOFF lower than 100*EPSILON, where EPSILON is the machine precision. "// &
180 "This may lead to numerical problems. Setting up shake_tol to 100*EPSILON! ")
181 tau_cut = max(epsilon(0.0_dp)*100.0_dp, tau_cut)
182 CALL section_vals_val_set(xc_section, "density_cutoff", r_val=density_cut)
183 CALL section_vals_val_set(xc_section, "gradient_cutoff", r_val=gradient_cut)
184 CALL section_vals_val_set(xc_section, "tau_cutoff", r_val=tau_cut)
185 END IF
186 xc_fun_section => section_vals_get_subs_vals(xc_section, "XC_FUNCTIONAL")
187 CALL section_vals_get(xc_fun_section, explicit=is_present)
188 IF (.NOT. is_present .AND. not_se) THEN
189 cpabort("XC_FUNCTIONAL section missing.")
190 END IF
191
192 dft_control%use_gauxc = .false.
193 IF (is_present) THEN
194 xc_gauxc_subsection => section_vals_get_subs_vals(xc_fun_section, "GAUXC")
195 CALL section_vals_get(xc_gauxc_subsection, explicit=dft_control%use_gauxc)
196 END IF
197
198 scf_section => section_vals_get_subs_vals(dft_section, "SCF")
199 CALL section_vals_val_get(dft_section, "UKS", l_val=dft_control%uks)
200 CALL section_vals_val_get(dft_section, "ROKS", l_val=dft_control%roks)
201 IF (dft_control%uks .OR. dft_control%roks) THEN
202 dft_control%nspins = 2
203 ELSE
204 dft_control%nspins = 1
205 END IF
206
207 dft_control%lsd = (dft_control%nspins > 1)
208 dft_control%use_kinetic_energy_density = xc_uses_kinetic_energy_density(xc_fun_section, dft_control%lsd)
209 IF (dft_control%use_gauxc) THEN
210 native_skala_grid = .false.
211 CALL section_vals_val_get(xc_gauxc_subsection, "NATIVE_GRID", l_val=native_skala_grid)
212 IF (native_skala_grid) dft_control%use_kinetic_energy_density = .true.
213 END IF
214 tmp_section => section_vals_get_subs_vals(dft_section, "KG_METHOD")
215 CALL section_vals_get(tmp_section, explicit=explicit)
216 IF (explicit) THEN
217 CALL section_vals_val_get(tmp_section, "TNADD_METHOD", i_val=kg_tnadd_method)
218 IF (kg_tnadd_method == kg_tnadd_embed .OR. kg_tnadd_method == kg_tnadd_embed_ri) THEN
219 kg_xc_section => section_vals_get_subs_vals(tmp_section, "XC")
220 kg_xc_fun_section => section_vals_get_subs_vals(kg_xc_section, "XC_FUNCTIONAL")
221 CALL section_vals_get(kg_xc_fun_section, explicit=is_present)
222 IF (is_present) THEN
223 dft_control%use_kinetic_energy_density = dft_control%use_kinetic_energy_density .OR. &
224 xc_uses_kinetic_energy_density(kg_xc_fun_section, &
225 dft_control%lsd)
226 END IF
227 END IF
228 END IF
229
230 xc_deriv_method_id = section_get_ival(xc_section, "XC_GRID%XC_DERIV")
231 dft_control%drho_by_collocation = (xc_uses_norm_drho(xc_fun_section, dft_control%lsd) &
232 .AND. (xc_deriv_method_id == xc_deriv_collocate))
233 IF (dft_control%drho_by_collocation) THEN
234 cpabort("derivatives by collocation not implemented")
235 END IF
236
237 ! Automatic auxiliary basis set generation
238 CALL section_vals_val_get(dft_section, "AUTO_BASIS", n_rep_val=nrep)
239 DO irep = 1, nrep
240 CALL section_vals_val_get(dft_section, "AUTO_BASIS", i_rep_val=irep, c_vals=tmpstringlist)
241 IF (SIZE(tmpstringlist) == 2) THEN
242 CALL uppercase(tmpstringlist(2))
243 SELECT CASE (tmpstringlist(2))
244 CASE ("X")
245 isize = -1
246 CASE ("SMALL")
247 isize = 0
248 CASE ("MEDIUM")
249 isize = 1
250 CASE ("LARGE")
251 isize = 2
252 CASE ("HUGE")
253 isize = 3
254 CASE DEFAULT
255 cpwarn("Unknown basis size in AUTO_BASIS keyword:"//trim(tmpstringlist(1)))
256 END SELECT
257 !
258 SELECT CASE (tmpstringlist(1))
259 CASE ("X")
260 CASE ("RI_AUX")
261 dft_control%auto_basis_ri_aux = isize
262 CASE ("AUX_FIT")
263 dft_control%auto_basis_aux_fit = isize
264 CASE ("LRI_AUX")
265 dft_control%auto_basis_lri_aux = isize
266 CASE ("P_LRI_AUX")
267 dft_control%auto_basis_p_lri_aux = isize
268 CASE ("RI_HXC")
269 dft_control%auto_basis_ri_hxc = isize
270 CASE ("RI_XAS")
271 dft_control%auto_basis_ri_xas = isize
272 CASE ("RI_HFX")
273 dft_control%auto_basis_ri_hfx = isize
274 CASE DEFAULT
275 cpwarn("Unknown basis type in AUTO_BASIS keyword:"//trim(tmpstringlist(1)))
276 END SELECT
277 ELSE
278 CALL cp_abort(__location__, &
279 "AUTO_BASIS keyword in &DFT section has a wrong number of arguments.")
280 END IF
281 END DO
282
283 !! check if we do wavefunction fitting
284 tmp_section => section_vals_get_subs_vals(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD")
285 CALL section_vals_get(tmp_section, explicit=is_present)
286 !
287 hfx_section => section_vals_get_subs_vals(xc_section, "HF")
288 CALL section_vals_get(hfx_section, explicit=do_hfx)
289 CALL section_vals_val_get(xc_section, "WF_CORRELATION%RI_RPA%ADMM", l_val=do_rpa_admm)
290 is_present = is_present .AND. (do_hfx .OR. do_rpa_admm)
291 !
292 dft_control%do_admm = is_present
293 dft_control%do_admm_mo = .false.
294 dft_control%do_admm_dm = .false.
295 IF (is_present) THEN
296 do_ot = .false.
297 CALL section_vals_val_get(scf_section, "OT%_SECTION_PARAMETERS_", l_val=do_ot)
298 CALL admm_control_create(dft_control%admm_control)
299
300 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%ADMM_TYPE", i_val=admmtype)
301 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%ADMM_PURIFICATION_METHOD", explicit=exopt1)
302 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%METHOD", explicit=exopt2)
303 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%EXCH_SCALING_MODEL", explicit=exopt3)
304 dft_control%admm_control%admm_type = admmtype
305 SELECT CASE (admmtype)
306 CASE (no_admm_type)
307 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%ADMM_PURIFICATION_METHOD", i_val=method_id)
308 dft_control%admm_control%purification_method = method_id
309 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%METHOD", i_val=method_id)
310 dft_control%admm_control%method = method_id
311 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%EXCH_SCALING_MODEL", i_val=method_id)
312 dft_control%admm_control%scaling_model = method_id
313 CASE (admm1_type)
314 ! METHOD BASIS_PROJECTION
315 ! ADMM_PURIFICATION_METHOD choose
316 ! EXCH_SCALING_MODEL NONE
317 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%ADMM_PURIFICATION_METHOD", i_val=method_id)
318 dft_control%admm_control%purification_method = method_id
319 dft_control%admm_control%method = do_admm_basis_projection
320 dft_control%admm_control%scaling_model = do_admm_exch_scaling_none
321 CASE (admm2_type)
322 ! METHOD BASIS_PROJECTION
323 ! ADMM_PURIFICATION_METHOD NONE
324 ! EXCH_SCALING_MODEL NONE
325 dft_control%admm_control%purification_method = do_admm_purify_none
326 dft_control%admm_control%method = do_admm_basis_projection
327 dft_control%admm_control%scaling_model = do_admm_exch_scaling_none
328 CASE (admms_type)
329 ! ADMM_PURIFICATION_METHOD NONE
330 ! METHOD CHARGE_CONSTRAINED_PROJECTION
331 ! EXCH_SCALING_MODEL MERLOT
332 dft_control%admm_control%purification_method = do_admm_purify_none
333 dft_control%admm_control%method = do_admm_charge_constrained_projection
334 dft_control%admm_control%scaling_model = do_admm_exch_scaling_merlot
335 CASE (admmp_type)
336 ! ADMM_PURIFICATION_METHOD NONE
337 ! METHOD BASIS_PROJECTION
338 ! EXCH_SCALING_MODEL MERLOT
339 dft_control%admm_control%purification_method = do_admm_purify_none
340 dft_control%admm_control%method = do_admm_basis_projection
341 dft_control%admm_control%scaling_model = do_admm_exch_scaling_merlot
342 CASE (admmq_type)
343 ! ADMM_PURIFICATION_METHOD NONE
344 ! METHOD CHARGE_CONSTRAINED_PROJECTION
345 ! EXCH_SCALING_MODEL NONE
346 dft_control%admm_control%purification_method = do_admm_purify_none
347 dft_control%admm_control%method = do_admm_charge_constrained_projection
348 dft_control%admm_control%scaling_model = do_admm_exch_scaling_none
349 CASE DEFAULT
350 CALL cp_abort(__location__, &
351 "ADMM_TYPE keyword in &AUXILIARY_DENSITY_MATRIX_METHOD section has a wrong value.")
352 END SELECT
353
354 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%EPS_FILTER", &
355 r_val=dft_control%admm_control%eps_filter)
356
357 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%EXCH_CORRECTION_FUNC", i_val=method_id)
358 dft_control%admm_control%aux_exch_func = method_id
359
360 ! parameters for X functional
361 dft_control%admm_control%aux_exch_func_param = .false.
362 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%OPTX_A1", explicit=explicit, &
363 r_val=dft_control%admm_control%aux_x_param(1))
364 IF (explicit) dft_control%admm_control%aux_exch_func_param = .true.
365 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%OPTX_A2", explicit=explicit, &
366 r_val=dft_control%admm_control%aux_x_param(2))
367 IF (explicit) dft_control%admm_control%aux_exch_func_param = .true.
368 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%OPTX_GAMMA", explicit=explicit, &
369 r_val=dft_control%admm_control%aux_x_param(3))
370 IF (explicit) dft_control%admm_control%aux_exch_func_param = .true.
371
372 CALL read_admm_block_list(dft_control%admm_control, dft_section)
373
374 ! check for double assignments
375 SELECT CASE (admmtype)
376 CASE (admm2_type)
377 IF (exopt2) CALL cp_warn(__location__, &
378 "Value of ADMM_PURIFICATION_METHOD keyword will be overwritten with ADMM_TYPE selections.")
379 IF (exopt3) CALL cp_warn(__location__, &
380 "Value of EXCH_SCALING_MODEL keyword will be overwritten with ADMM_TYPE selections.")
381 CASE (admm1_type, admms_type, admmp_type, admmq_type)
382 IF (exopt1) CALL cp_warn(__location__, &
383 "Value of METHOD keyword will be overwritten with ADMM_TYPE selections.")
384 IF (exopt2) CALL cp_warn(__location__, &
385 "Value of METHOD keyword will be overwritten with ADMM_TYPE selections.")
386 IF (exopt3) CALL cp_warn(__location__, &
387 "Value of EXCH_SCALING_MODEL keyword will be overwritten with ADMM_TYPE selections.")
388 END SELECT
389
390 ! In the case of charge-constrained projection (e.g. according to Merlot),
391 ! there is no purification needed and hence, do_admm_purify_none has to be set.
392
393 IF ((dft_control%admm_control%method == do_admm_blocking_purify_full .OR. &
394 dft_control%admm_control%method == do_admm_blocked_projection) &
395 .AND. dft_control%admm_control%scaling_model == do_admm_exch_scaling_merlot) THEN
396 cpabort("ADMM: Blocking and Merlot scaling are mutually exclusive.")
397 END IF
398
399 IF (dft_control%admm_control%method == do_admm_charge_constrained_projection .AND. &
400 dft_control%admm_control%purification_method /= do_admm_purify_none) THEN
401 CALL cp_abort(__location__, &
402 "ADMM: In the case of METHOD=CHARGE_CONSTRAINED_PROJECTION, "// &
403 "ADMM_PURIFICATION_METHOD=NONE has to be set.")
404 END IF
405
406 IF (dft_control%admm_control%purification_method == do_admm_purify_mo_diag .OR. &
407 dft_control%admm_control%purification_method == do_admm_purify_mo_no_diag) THEN
408 IF (dft_control%admm_control%method /= do_admm_basis_projection) &
409 cpabort("ADMM: Chosen purification requires BASIS_PROJECTION")
410
411 IF (.NOT. do_ot) cpabort("ADMM: MO-based purification requires OT.")
412 END IF
413
414 IF (dft_control%admm_control%purification_method == do_admm_purify_none_dm .OR. &
415 dft_control%admm_control%purification_method == do_admm_purify_mcweeny) THEN
416 dft_control%do_admm_dm = .true.
417 ELSE
418 dft_control%do_admm_mo = .true.
419 END IF
420 END IF
421
422 ! Set restricted to true, if both OT and ROKS are requested
423 !MK in principle dft_control%restricted could be dropped completely like the
424 !MK input key by using only dft_control%roks now
425 CALL section_vals_val_get(scf_section, "OT%_SECTION_PARAMETERS_", l_val=l_param)
426 dft_control%restricted = (dft_control%roks .AND. l_param)
427
428 CALL section_vals_val_get(dft_section, "CHARGE", i_val=dft_control%charge)
429 CALL section_vals_val_get(dft_section, "MULTIPLICITY", i_val=dft_control%multiplicity)
430 CALL section_vals_val_get(dft_section, "RELAX_MULTIPLICITY", r_val=dft_control%relax_multiplicity)
431 IF (dft_control%relax_multiplicity > 0.0_dp) THEN
432 IF (.NOT. dft_control%uks) &
433 CALL cp_abort(__location__, "The option RELAX_MULTIPLICITY is only valid for "// &
434 "unrestricted Kohn-Sham (UKS) calculations")
435 END IF
436
437 !Read the HAIR PROBES input section if present
438 hairy_probes_section => section_vals_get_subs_vals(dft_section, "HAIRY_PROBES")
439 CALL section_vals_get(hairy_probes_section, n_repetition=nrep, explicit=is_present)
440
441 IF (is_present) THEN
442 dft_control%hairy_probes = .true.
443 ALLOCATE (dft_control%probe(nrep))
444 CALL read_hairy_probes_sections(dft_control, hairy_probes_section)
445 END IF
446
447 ! check for the presence of the low spin roks section
448 tmp_section => section_vals_get_subs_vals(dft_section, "LOW_SPIN_ROKS")
449 CALL section_vals_get(tmp_section, explicit=dft_control%low_spin_roks)
450
451 dft_control%sic_method_id = sic_none
452 dft_control%sic_scaling_a = 1.0_dp
453 dft_control%sic_scaling_b = 1.0_dp
454
455 ! DFT+U
456 dft_control%dft_plus_u = .false.
457 CALL section_vals_val_get(dft_section, "PLUS_U_METHOD", i_val=method_id)
458 dft_control%plus_u_method_id = method_id
459
460 ! Smearing in use
461 dft_control%smear = .false.
462
463 ! Surface dipole correction
464 dft_control%correct_surf_dip = .false.
465 CALL section_vals_val_get(dft_section, "SURFACE_DIPOLE_CORRECTION", l_val=dft_control%correct_surf_dip)
466 CALL section_vals_val_get(dft_section, "SURF_DIP_DIR", i_val=dft_control%dir_surf_dip)
467 dft_control%pos_dir_surf_dip = -1.0_dp
468 CALL section_vals_val_get(dft_section, "SURF_DIP_POS", r_val=dft_control%pos_dir_surf_dip)
469 ! another logical variable, surf_dip_correct_switch, is introduced for
470 ! implementation of "SURF_DIP_SWITCH" [SGh]
471 dft_control%switch_surf_dip = .false.
472 dft_control%surf_dip_correct_switch = dft_control%correct_surf_dip
473 CALL section_vals_val_get(dft_section, "SURF_DIP_SWITCH", l_val=dft_control%switch_surf_dip)
474 dft_control%correct_el_density_dip = .false.
475 CALL section_vals_val_get(dft_section, "CORE_CORR_DIP", l_val=dft_control%correct_el_density_dip)
476 IF (dft_control%correct_el_density_dip) THEN
477 IF (dft_control%correct_surf_dip) THEN
478 ! Do nothing, move on
479 ELSE
480 dft_control%correct_el_density_dip = .false.
481 cpwarn("CORE_CORR_DIP keyword is activated only if SURFACE_DIPOLE_CORRECTION is TRUE")
482 END IF
483 END IF
484
485 CALL section_vals_val_get(dft_section, "BASIS_SET_FILE_NAME", &
486 c_val=basis_set_file_name)
487 CALL section_vals_val_get(dft_section, "POTENTIAL_FILE_NAME", &
488 c_val=potential_file_name)
489
490 ! Read the input section
491 tmp_section => section_vals_get_subs_vals(dft_section, "sic")
492 CALL section_vals_val_get(tmp_section, "SIC_METHOD", &
493 i_val=dft_control%sic_method_id)
494 CALL section_vals_val_get(tmp_section, "ORBITAL_SET", &
495 i_val=dft_control%sic_list_id)
496 CALL section_vals_val_get(tmp_section, "SIC_SCALING_A", &
497 r_val=dft_control%sic_scaling_a)
498 CALL section_vals_val_get(tmp_section, "SIC_SCALING_B", &
499 r_val=dft_control%sic_scaling_b)
500
501 do_rtp = .false.
502 tmp_section => section_vals_get_subs_vals(dft_section, "REAL_TIME_PROPAGATION")
503 CALL section_vals_get(tmp_section, explicit=is_present)
504 IF (is_present) THEN
505 CALL read_rtp_section(dft_control, tmp_section)
506 do_rtp = .true.
507 END IF
508
509 ! Read the input section
510 tmp_section => section_vals_get_subs_vals(dft_section, "XAS")
511 CALL section_vals_get(tmp_section, explicit=dft_control%do_xas_calculation)
512 IF (dft_control%do_xas_calculation) THEN
513 ! Override with section parameter
514 CALL section_vals_val_get(tmp_section, "_SECTION_PARAMETERS_", &
515 l_val=dft_control%do_xas_calculation)
516 END IF
517
518 tmp_section => section_vals_get_subs_vals(dft_section, "XAS_TDP")
519 CALL section_vals_get(tmp_section, explicit=dft_control%do_xas_tdp_calculation)
520 IF (dft_control%do_xas_tdp_calculation) THEN
521 ! Override with section parameter
522 CALL section_vals_val_get(tmp_section, "_SECTION_PARAMETERS_", &
523 l_val=dft_control%do_xas_tdp_calculation)
524 END IF
525
526 ! Read the finite field input section
527 dft_control%apply_efield = .false.
528 dft_control%apply_efield_field = .false. !this is for RTP
529 dft_control%apply_vector_potential = .false. !this is for RTP
530 tmp_section => section_vals_get_subs_vals(dft_section, "EFIELD")
531 CALL section_vals_get(tmp_section, n_repetition=nrep, explicit=is_present)
532 IF (is_present) THEN
533 ALLOCATE (dft_control%efield_fields(nrep))
534 CALL read_efield_sections(dft_control, tmp_section, cell)
535 IF (do_rtp) THEN
536 IF (.NOT. dft_control%rtp_control%velocity_gauge) THEN
537 dft_control%apply_efield_field = .true.
538 ELSE
539 dft_control%apply_vector_potential = .true.
540 ! Use this input value of vector potential to (re)start RTP
541 dft_control%rtp_control%vec_pot = dft_control%efield_fields(1)%efield%vec_pot_initial
542 END IF
543 ELSE
544 dft_control%apply_efield = .true.
545 cpassert(nrep == 1)
546 END IF
547 END IF
548
549 ! Now, can try to guess polarisation in rtp
550 IF (do_rtp) THEN
551 ! tmp_section => section_vals_get_subs_vals(dft_section, "REAL_TIME_PROPAGATION%PRINT%POLARIZABILITY")
552 ! CALL section_vals_get(tmp_section, explicit=is_present)
553 local_moment_possible = (dft_control%rtp_control%rtp_method == rtp_method_bse) .OR. &
554 ((.NOT. dft_control%rtp_control%periodic) .AND. dft_control%rtp_control%linear_scaling)
555 IF (local_moment_possible .AND. (.NOT. ASSOCIATED(dft_control%rtp_control%print_pol_elements))) THEN
556 tmp_section => section_vals_get_subs_vals(dft_section, "REAL_TIME_PROPAGATION")
557 CALL guess_pol_elements(dft_control, &
558 dft_control%rtp_control%print_pol_elements)
559 END IF
560 END IF
561
562 ! Read the finite field input section for periodic fields
563 tmp_section => section_vals_get_subs_vals(dft_section, "PERIODIC_EFIELD")
564 CALL section_vals_get(tmp_section, explicit=dft_control%apply_period_efield)
565 IF (dft_control%apply_period_efield) THEN
566 ALLOCATE (dft_control%period_efield)
567 CALL section_vals_val_get(tmp_section, "POLARISATION", r_vals=pol)
568 dft_control%period_efield%polarisation(1:3) = pol(1:3)
569 IF (PRESENT(cell)) THEN
570 IF (ASSOCIATED(cell)) &
571 CALL cell_transform_input_cartesian(cell, dft_control%period_efield%polarisation(1:3))
572 END IF
573 CALL section_vals_val_get(tmp_section, "D_FILTER", r_vals=pol)
574 dft_control%period_efield%d_filter(1:3) = pol(1:3)
575 IF (PRESENT(cell)) THEN
576 IF (ASSOCIATED(cell)) CALL cell_transform_input_cartesian(cell, dft_control%period_efield%d_filter(1:3))
577 END IF
578 CALL section_vals_val_get(tmp_section, "INTENSITY", &
579 r_val=dft_control%period_efield%strength)
580 dft_control%period_efield%displacement_field = .false.
581 CALL section_vals_val_get(tmp_section, "DISPLACEMENT_FIELD", &
582 l_val=dft_control%period_efield%displacement_field)
583
584 CALL section_vals_val_get(tmp_section, "INTENSITY_LIST", r_vals=pol)
585
586 CALL section_vals_val_get(tmp_section, "INTENSITIES_FILE_NAME", c_val=intensities_file_name)
587
588 IF (SIZE(pol) > 1 .OR. pol(1) /= 0.0_dp) THEN
589 ! if INTENSITY_LIST is present, INTENSITY and INTENSITIES_FILE_NAME must not be present
590 IF (dft_control%period_efield%strength /= 0.0_dp .OR. intensities_file_name /= "") THEN
591 CALL cp_abort(__location__, "[PERIODIC FIELD] Only one of INTENSITY, INTENSITY_LIST "// &
592 "or INTENSITIES_FILE_NAME can be specified.")
593 END IF
594
595 ALLOCATE (dft_control%period_efield%strength_list(SIZE(pol)))
596 dft_control%period_efield%strength_list(1:SIZE(pol)) = pol(1:SIZE(pol))
597 END IF
598
599 IF (intensities_file_name /= "") THEN
600 ! if INTENSITIES_FILE_NAME is present, INTENSITY must not be present
601 IF (dft_control%period_efield%strength /= 0.0_dp) THEN
602 CALL cp_abort(__location__, "[PERIODIC FIELD] Only one of INTENSITY, INTENSITY_LIST "// &
603 "or INTENSITIES_FILE_NAME can be specified.")
604 END IF
605
606 CALL parser_create(parser, intensities_file_name)
607
608 nrep = 0
609 DO WHILE (.true.)
610 CALL parser_read_line(parser, 1, at_end)
611 IF (at_end) EXIT
612 nrep = nrep + 1
613 END DO
614
615 IF (nrep == 0) THEN
616 cpabort("[PERIODIC FIELD] No intensities found in INTENSITIES_FILE_NAME")
617 END IF
618
619 ALLOCATE (dft_control%period_efield%strength_list(nrep))
620
621 CALL parser_reset(parser)
622 DO irep = 1, nrep
623 CALL parser_read_line(parser, 1)
624 READ (parser%input_line, *) dft_control%period_efield%strength_list(irep)
625 END DO
626
627 CALL parser_release(parser)
628 END IF
629
630 CALL section_vals_val_get(tmp_section, "START_FRAME", &
631 i_val=dft_control%period_efield%start_frame)
632 CALL section_vals_val_get(tmp_section, "END_FRAME", &
633 i_val=dft_control%period_efield%end_frame)
634
635 IF (dft_control%period_efield%end_frame /= -1) THEN
636 ! check if valid bounds are given
637 ! if an end frame is given, the number of active frames must be a
638 ! multiple of the number of intensities
639 IF (dft_control%period_efield%start_frame > dft_control%period_efield%end_frame) THEN
640 cpabort("[PERIODIC FIELD] START_FRAME > END_FRAME")
641 ELSE IF (dft_control%period_efield%start_frame < 1) THEN
642 cpabort("[PERIODIC FIELD] START_FRAME < 1")
643 ELSE IF (mod(dft_control%period_efield%end_frame - &
644 dft_control%period_efield%start_frame + 1, SIZE(pol)) /= 0) THEN
645 CALL cp_abort(__location__, &
646 "[PERIODIC FIELD] Number of active frames must be a multiple of the number of intensities")
647 END IF
648 END IF
649
650 ! periodic fields don't work with RTP
651 cpassert(.NOT. do_rtp)
652 IF (dft_control%period_efield%displacement_field) THEN
653 CALL cite_reference(stengel2009)
654 ELSE
655 CALL cite_reference(souza2002)
656 CALL cite_reference(umari2002)
657 END IF
658 END IF
659
660 ! Read the external potential input section
661 tmp_section => section_vals_get_subs_vals(dft_section, "EXTERNAL_POTENTIAL")
662 CALL section_vals_get(tmp_section, explicit=dft_control%apply_external_potential)
663 IF (dft_control%apply_external_potential) THEN
664 CALL expot_control_create(dft_control%expot_control)
665 CALL section_vals_val_get(tmp_section, "READ_FROM_CUBE", &
666 l_val=dft_control%expot_control%read_from_cube)
667 CALL section_vals_val_get(tmp_section, "STATIC", &
668 l_val=dft_control%expot_control%static)
669 CALL section_vals_val_get(tmp_section, "SCALING_FACTOR", &
670 r_val=dft_control%expot_control%scaling_factor)
671 ! External potential using Maxwell equation
672 maxwell_section => section_vals_get_subs_vals(tmp_section, "MAXWELL")
673 CALL section_vals_get(maxwell_section, explicit=is_present)
674 IF (is_present) THEN
675 dft_control%expot_control%maxwell_solver = .true.
676 CALL maxwell_control_create(dft_control%maxwell_control)
677 ! read the input values from Maxwell section
678 CALL section_vals_val_get(maxwell_section, "TEST_REAL", &
679 r_val=dft_control%maxwell_control%real_test)
680 CALL section_vals_val_get(maxwell_section, "TEST_INTEGER", &
681 i_val=dft_control%maxwell_control%int_test)
682 CALL section_vals_val_get(maxwell_section, "TEST_LOGICAL", &
683 l_val=dft_control%maxwell_control%log_test)
684 ELSE
685 dft_control%expot_control%maxwell_solver = .false.
686 END IF
687 END IF
688
689 ! Read the SCCS input section if present
690 sccs_section => section_vals_get_subs_vals(dft_section, "SCCS")
691 CALL section_vals_get(sccs_section, explicit=is_present)
692 IF (is_present) THEN
693 ! Check section parameter if SCCS is activated
694 CALL section_vals_val_get(sccs_section, "_SECTION_PARAMETERS_", &
695 l_val=dft_control%do_sccs)
696 IF (dft_control%do_sccs) THEN
697 ALLOCATE (dft_control%sccs_control)
698 CALL section_vals_val_get(sccs_section, "RELATIVE_PERMITTIVITY", &
699 r_val=dft_control%sccs_control%epsilon_solvent)
700 CALL section_vals_val_get(sccs_section, "ALPHA", &
701 r_val=dft_control%sccs_control%alpha_solvent)
702 CALL section_vals_val_get(sccs_section, "BETA", &
703 r_val=dft_control%sccs_control%beta_solvent)
704 CALL section_vals_val_get(sccs_section, "DELTA_RHO", &
705 r_val=dft_control%sccs_control%delta_rho)
706 CALL section_vals_val_get(sccs_section, "DERIVATIVE_METHOD", &
707 i_val=dft_control%sccs_control%derivative_method)
708 CALL section_vals_val_get(sccs_section, "METHOD", &
709 i_val=dft_control%sccs_control%method_id)
710 CALL section_vals_val_get(sccs_section, "EPS_SCCS", &
711 r_val=dft_control%sccs_control%eps_sccs)
712 CALL section_vals_val_get(sccs_section, "EPS_SCF", &
713 r_val=dft_control%sccs_control%eps_scf)
714 CALL section_vals_val_get(sccs_section, "GAMMA", &
715 r_val=dft_control%sccs_control%gamma_solvent)
716 CALL section_vals_val_get(sccs_section, "MAX_ITER", &
717 i_val=dft_control%sccs_control%max_iter)
718 CALL section_vals_val_get(sccs_section, "MIXING", &
719 r_val=dft_control%sccs_control%mixing)
720 SELECT CASE (dft_control%sccs_control%method_id)
721 CASE (sccs_andreussi)
722 tmp_section => section_vals_get_subs_vals(sccs_section, "ANDREUSSI")
723 CALL section_vals_val_get(tmp_section, "RHO_MAX", &
724 r_val=dft_control%sccs_control%rho_max)
725 CALL section_vals_val_get(tmp_section, "RHO_MIN", &
726 r_val=dft_control%sccs_control%rho_min)
727 IF (dft_control%sccs_control%rho_max < dft_control%sccs_control%rho_min) THEN
728 CALL cp_abort(__location__, &
729 "The SCCS parameter RHO_MAX is smaller than RHO_MIN. "// &
730 "Please, check your input!")
731 END IF
732 CALL cite_reference(andreussi2012)
733 CASE (sccs_fattebert_gygi)
734 tmp_section => section_vals_get_subs_vals(sccs_section, "FATTEBERT-GYGI")
735 CALL section_vals_val_get(tmp_section, "BETA", &
736 r_val=dft_control%sccs_control%beta)
737 IF (dft_control%sccs_control%beta < 0.5_dp) THEN
738 CALL cp_abort(__location__, &
739 "A value smaller than 0.5 for the SCCS parameter beta "// &
740 "causes numerical problems. Please, check your input!")
741 END IF
742 CALL section_vals_val_get(tmp_section, "RHO_ZERO", &
743 r_val=dft_control%sccs_control%rho_zero)
744 CALL cite_reference(fattebert2002)
745 CASE DEFAULT
746 cpabort("Invalid SCCS model specified. Please, check your input!")
747 END SELECT
748 CALL cite_reference(yin2017)
749 END IF
750 END IF
751
752 ! Read the planar counter charge section
753 tmp_section => section_vals_get_subs_vals(dft_section, "PLANAR_COUNTER_CHARGE")
754 CALL section_vals_get(tmp_section, explicit=is_present)
755 IF (is_present) THEN
756 ! Check section parameter if planar counter charge is activated
757 CALL section_vals_val_get(tmp_section, "_SECTION_PARAMETERS_", &
758 l_val=dft_control%do_pcc)
759 IF (dft_control%do_pcc) THEN
760 ALLOCATE (dft_control%pcc_control)
761 CALL section_vals_val_get(tmp_section, "DIST_EDGE", &
762 r_val=dft_control%pcc_control%dist_edge)
763 CALL section_vals_val_get(tmp_section, "GAU_C", &
764 r_val=dft_control%pcc_control%gau_c)
765 CALL section_vals_val_get(tmp_section, "PARALLEL_PLANE", &
766 i_val=dft_control%pcc_control%surf_normal)
767 END IF
768 END IF
769
770 ! Read the planar averaged Hartree potential section
771 tmp_section => section_vals_get_subs_vals(dft_section, "PLANAR_AVERAGED_V_HARTREE")
772 CALL section_vals_get(tmp_section, explicit=is_present)
773 IF (is_present) THEN
774 ! Check section parameter if the planar-averaged potential is activated
775 CALL section_vals_val_get(tmp_section, "_SECTION_PARAMETERS_", &
776 l_val=dft_control%do_paep)
777 IF (dft_control%do_paep) THEN
778 ALLOCATE (dft_control%paep_control)
779 CALL section_vals_val_get(tmp_section, "PARALLEL_PLANE", &
780 i_val=dft_control%paep_control%surf_normal)
781 END IF
782 END IF
783
784 ! ZMP added input sections
785 ! Read the external density input section
786 tmp_section => section_vals_get_subs_vals(dft_section, "EXTERNAL_DENSITY")
787 CALL section_vals_get(tmp_section, explicit=dft_control%apply_external_density)
788
789 ! Read the external vxc input section
790 tmp_section => section_vals_get_subs_vals(dft_section, "EXTERNAL_VXC")
791 CALL section_vals_get(tmp_section, explicit=dft_control%apply_external_vxc)
792
793 tmp_section => section_vals_get_subs_vals(dft_section, "LOCALIZE")
794 CALL section_vals_val_get(tmp_section, "EACH", i_val=dft_control%localize_each)
795
796 ! SMEAGOL interface
797 tmp_section => section_vals_get_subs_vals(dft_section, "SMEAGOL")
798 CALL read_smeagol_control(dft_control%smeagol_control, tmp_section)
799
800 END SUBROUTINE read_dft_control
801
802! **************************************************************************************************
803!> \brief Reads the input and stores in the rixs_control_type
804!> \param rixs_control ...
805!> \param rixs_section ...
806!> \param qs_control ...
807! **************************************************************************************************
808 SUBROUTINE read_rixs_control(rixs_control, rixs_section, qs_control)
809 TYPE(rixs_control_type), POINTER :: rixs_control
810 TYPE(section_vals_type), POINTER :: rixs_section
811 TYPE(qs_control_type), POINTER :: qs_control
812
813 TYPE(section_vals_type), POINTER :: td_section, xas_section
814
815 CALL section_vals_val_get(rixs_section, "_SECTION_PARAMETERS_", l_val=rixs_control%enabled)
816
817 CALL section_vals_val_get(rixs_section, "CORE_STATES", i_val=rixs_control%core_states)
818 CALL section_vals_val_get(rixs_section, "VALENCE_STATES", i_val=rixs_control%valence_states)
819
820 td_section => section_vals_get_subs_vals(rixs_section, "TDDFPT")
821 CALL read_tddfpt2_control(rixs_control%tddfpt2_control, td_section, qs_control)
822
823 xas_section => section_vals_get_subs_vals(rixs_section, "XAS_TDP")
824 CALL read_xas_tdp_control(rixs_control%xas_tdp_control, xas_section)
825
826 END SUBROUTINE read_rixs_control
827
828! **************************************************************************************************
829!> \brief ...
830!> \param qs_control ...
831!> \param dft_section ...
832! **************************************************************************************************
833 SUBROUTINE read_mgrid_section(qs_control, dft_section)
834
835 TYPE(qs_control_type), INTENT(INOUT) :: qs_control
836 TYPE(section_vals_type), POINTER :: dft_section
837
838 CHARACTER(len=*), PARAMETER :: routinen = 'read_mgrid_section'
839
840 INTEGER :: handle, igrid_level, ngrid_level
841 LOGICAL :: explicit, multigrid_set
842 REAL(dp) :: cutoff
843 REAL(dp), DIMENSION(:), POINTER :: cutofflist
844 TYPE(section_vals_type), POINTER :: mgrid_section
845
846 CALL timeset(routinen, handle)
847
848 NULLIFY (mgrid_section, cutofflist)
849 mgrid_section => section_vals_get_subs_vals(dft_section, "MGRID")
850
851 CALL section_vals_val_get(mgrid_section, "NGRIDS", i_val=ngrid_level)
852 CALL section_vals_val_get(mgrid_section, "MULTIGRID_SET", l_val=multigrid_set)
853 CALL section_vals_val_get(mgrid_section, "CUTOFF", r_val=cutoff)
854 CALL section_vals_val_get(mgrid_section, "PROGRESSION_FACTOR", r_val=qs_control%progression_factor)
855 CALL section_vals_val_get(mgrid_section, "COMMENSURATE", l_val=qs_control%commensurate_mgrids)
856 CALL section_vals_val_get(mgrid_section, "REALSPACE", l_val=qs_control%realspace_mgrids)
857 CALL section_vals_val_get(mgrid_section, "REL_CUTOFF", r_val=qs_control%relative_cutoff)
858 CALL section_vals_val_get(mgrid_section, "SKIP_LOAD_BALANCE_DISTRIBUTED", &
859 l_val=qs_control%skip_load_balance_distributed)
860
861 ! For SE and DFTB possibly override with new defaults
862 IF (qs_control%semi_empirical .OR. qs_control%dftb .OR. qs_control%xtb) THEN
863 ngrid_level = 1
864 multigrid_set = .false.
865 ! Override default cutoff value unless user specified an explicit argument..
866 CALL section_vals_val_get(mgrid_section, "CUTOFF", explicit=explicit, r_val=cutoff)
867 IF (.NOT. explicit) cutoff = 1.0_dp
868 END IF
869
870 ALLOCATE (qs_control%e_cutoff(ngrid_level))
871 qs_control%cutoff = cutoff
872
873 IF (multigrid_set) THEN
874 ! Read the values from input
875 IF (qs_control%commensurate_mgrids) THEN
876 cpabort("Do not specify cutoffs for the commensurate grids (NYI)")
877 END IF
878
879 CALL section_vals_val_get(mgrid_section, "MULTIGRID_CUTOFF", r_vals=cutofflist)
880 IF (ASSOCIATED(cutofflist)) THEN
881 IF (SIZE(cutofflist, 1) /= ngrid_level) THEN
882 cpabort("Number of multi-grids requested and number of cutoff values do not match")
883 END IF
884 DO igrid_level = 1, ngrid_level
885 qs_control%e_cutoff(igrid_level) = cutofflist(igrid_level)
886 END DO
887 END IF
888 ! set cutoff to smallest value in multgrid available with >= cutoff
889 DO igrid_level = ngrid_level, 1, -1
890 IF (qs_control%cutoff <= qs_control%e_cutoff(igrid_level)) THEN
891 qs_control%cutoff = qs_control%e_cutoff(igrid_level)
892 EXIT
893 END IF
894 ! set largest grid value to cutoff
895 IF (igrid_level == 1) THEN
896 qs_control%cutoff = qs_control%e_cutoff(1)
897 END IF
898 END DO
899 ELSE
900 IF (qs_control%commensurate_mgrids) qs_control%progression_factor = 4.0_dp
901 qs_control%e_cutoff(1) = qs_control%cutoff
902 DO igrid_level = 2, ngrid_level
903 qs_control%e_cutoff(igrid_level) = qs_control%e_cutoff(igrid_level - 1)/ &
904 qs_control%progression_factor
905 END DO
906 END IF
907 ! check that multigrids are ordered
908 DO igrid_level = 2, ngrid_level
909 IF (qs_control%e_cutoff(igrid_level) > qs_control%e_cutoff(igrid_level - 1)) THEN
910 cpabort("The cutoff values for the multi-grids are not ordered from large to small")
911 ELSE IF (qs_control%e_cutoff(igrid_level) == qs_control%e_cutoff(igrid_level - 1)) THEN
912 cpabort("The same cutoff value was specified for two multi-grids")
913 END IF
914 END DO
915 CALL timestop(handle)
916 END SUBROUTINE read_mgrid_section
917
918! **************************************************************************************************
919!> \brief ...
920!> \param qs_control ...
921!> \param qs_section ...
922!> \param cell optional cell used to transform Cartesian input vectors
923! **************************************************************************************************
924 SUBROUTINE read_qs_section(qs_control, qs_section, cell)
925
926 TYPE(qs_control_type), INTENT(INOUT) :: qs_control
927 TYPE(section_vals_type), POINTER :: qs_section
928 TYPE(cell_type), OPTIONAL, POINTER :: cell
929
930 CHARACTER(len=*), PARAMETER :: routinen = 'read_qs_section'
931
932 CHARACTER(LEN=default_string_length) :: cval
933 CHARACTER(LEN=default_string_length), &
934 DIMENSION(:), POINTER :: clist
935 INTEGER :: handle, itmp, j, jj, k, n_rep, n_var, &
936 ngauss, ngp, nrep
937 INTEGER, DIMENSION(:), POINTER :: tmplist
938 LOGICAL :: dftb_scc_mixer_explicit, dftb_tblite_mixer_explicit, explicit, &
939 tblite_reference_cli, tblite_reference_cli_section, tblite_section_active, was_present, &
940 xtb_scc_mixer_explicit, xtb_tblite_mixer_explicit
941 REAL(dp) :: tmp, tmpsqrt, value
942 REAL(dp), POINTER :: scal(:)
943 TYPE(section_vals_type), POINTER :: cdft_control_section, ddapc_restraint_section, &
944 dftb_parameter, dftb_section, dftb_tblite_mixer, eeq_section, genpot_section, &
945 lri_optbas_section, mull_section, nonbonded_section, s2_restraint_section, se_section, &
946 xtb_parameter, xtb_section, xtb_tblite, xtb_tblite_mixer, xtb_tblite_ref_cli
947
948 CALL timeset(routinen, handle)
949
950 was_present = .false.
951 NULLIFY (mull_section, ddapc_restraint_section, s2_restraint_section, &
952 se_section, dftb_section, xtb_section, dftb_parameter, xtb_parameter, lri_optbas_section, &
953 cdft_control_section, genpot_section, eeq_section, dftb_tblite_mixer, &
954 xtb_tblite_mixer, xtb_tblite_ref_cli)
955
956 mull_section => section_vals_get_subs_vals(qs_section, "MULLIKEN_RESTRAINT")
957 ddapc_restraint_section => section_vals_get_subs_vals(qs_section, "DDAPC_RESTRAINT")
958 s2_restraint_section => section_vals_get_subs_vals(qs_section, "S2_RESTRAINT")
959 se_section => section_vals_get_subs_vals(qs_section, "SE")
960 dftb_section => section_vals_get_subs_vals(qs_section, "DFTB")
961 xtb_section => section_vals_get_subs_vals(qs_section, "xTB")
962 dftb_parameter => section_vals_get_subs_vals(dftb_section, "PARAMETER")
963 dftb_tblite_mixer => section_vals_get_subs_vals(dftb_section, "TBLITE_MIXER")
964 xtb_parameter => section_vals_get_subs_vals(xtb_section, "PARAMETER")
965 eeq_section => section_vals_get_subs_vals(xtb_section, "EEQ")
966 lri_optbas_section => section_vals_get_subs_vals(qs_section, "OPTIMIZE_LRI_BASIS")
967 cdft_control_section => section_vals_get_subs_vals(qs_section, "CDFT")
968 nonbonded_section => section_vals_get_subs_vals(xtb_section, "NONBONDED")
969 genpot_section => section_vals_get_subs_vals(nonbonded_section, "GENPOT")
970 xtb_tblite_mixer => section_vals_get_subs_vals(xtb_section, "TBLITE_MIXER")
971 xtb_tblite => section_vals_get_subs_vals(xtb_section, "TBLITE")
972 xtb_tblite_ref_cli => section_vals_get_subs_vals(xtb_tblite, "REFERENCE_CLI")
973
974 ! Setup all defaults values and overwrite input parameters
975 ! EPS_DEFAULT should set the target accuracy in the total energy (~per electron) or a closely related value
976 CALL section_vals_val_get(qs_section, "EPS_DEFAULT", r_val=value)
977 tmpsqrt = sqrt(value) ! a trick to work around a NAG 5.1 optimizer bug
978
979 ! random choice ?
980 qs_control%eps_core_charge = value/100.0_dp
981 ! correct if all Gaussians would have the same radius (overlap will be smaller than eps_pgf_orb**2).
982 ! Can be significantly in error if not... requires fully new screening/pairlist procedures
983 qs_control%eps_pgf_orb = tmpsqrt
984 qs_control%eps_kg_orb = qs_control%eps_pgf_orb
985 ! consistent since also a kind of overlap
986 qs_control%eps_ppnl = qs_control%eps_pgf_orb/100.0_dp
987 ! accuracy is basically set by the overlap, this sets an empirical shift
988 qs_control%eps_ppl = 1.0e-2_dp
989 !
990 qs_control%gapw_control%eps_cpc = value
991 ! expexted error in the density
992 qs_control%eps_rho_gspace = value
993 qs_control%eps_rho_rspace = value
994 ! error in the gradient, can be the sqrt of the error in the energy, ignored if map_consistent
995 qs_control%eps_gvg_rspace = tmpsqrt
996 !
997 CALL section_vals_val_get(qs_section, "EPS_CORE_CHARGE", n_rep_val=n_rep)
998 IF (n_rep /= 0) THEN
999 CALL section_vals_val_get(qs_section, "EPS_CORE_CHARGE", r_val=qs_control%eps_core_charge)
1000 END IF
1001 CALL section_vals_val_get(qs_section, "EPS_GVG_RSPACE", n_rep_val=n_rep)
1002 IF (n_rep /= 0) THEN
1003 CALL section_vals_val_get(qs_section, "EPS_GVG_RSPACE", r_val=qs_control%eps_gvg_rspace)
1004 END IF
1005 CALL section_vals_val_get(qs_section, "EPS_PGF_ORB", n_rep_val=n_rep)
1006 IF (n_rep /= 0) THEN
1007 CALL section_vals_val_get(qs_section, "EPS_PGF_ORB", r_val=qs_control%eps_pgf_orb)
1008 END IF
1009 CALL section_vals_val_get(qs_section, "EPS_KG_ORB", n_rep_val=n_rep)
1010 IF (n_rep /= 0) THEN
1011 CALL section_vals_val_get(qs_section, "EPS_KG_ORB", r_val=tmp)
1012 qs_control%eps_kg_orb = sqrt(tmp)
1013 END IF
1014 CALL section_vals_val_get(qs_section, "EPS_PPL", n_rep_val=n_rep)
1015 IF (n_rep /= 0) THEN
1016 CALL section_vals_val_get(qs_section, "EPS_PPL", r_val=qs_control%eps_ppl)
1017 END IF
1018 CALL section_vals_val_get(qs_section, "EPS_PPNL", n_rep_val=n_rep)
1019 IF (n_rep /= 0) THEN
1020 CALL section_vals_val_get(qs_section, "EPS_PPNL", r_val=qs_control%eps_ppnl)
1021 END IF
1022 CALL section_vals_val_get(qs_section, "EPS_RHO", n_rep_val=n_rep)
1023 IF (n_rep /= 0) THEN
1024 CALL section_vals_val_get(qs_section, "EPS_RHO", r_val=qs_control%eps_rho_gspace)
1025 qs_control%eps_rho_rspace = qs_control%eps_rho_gspace
1026 END IF
1027 CALL section_vals_val_get(qs_section, "EPS_RHO_RSPACE", n_rep_val=n_rep)
1028 IF (n_rep /= 0) THEN
1029 CALL section_vals_val_get(qs_section, "EPS_RHO_RSPACE", r_val=qs_control%eps_rho_rspace)
1030 END IF
1031 CALL section_vals_val_get(qs_section, "EPS_RHO_GSPACE", n_rep_val=n_rep)
1032 IF (n_rep /= 0) THEN
1033 CALL section_vals_val_get(qs_section, "EPS_RHO_GSPACE", r_val=qs_control%eps_rho_gspace)
1034 END IF
1035 CALL section_vals_val_get(qs_section, "EPS_FILTER_MATRIX", n_rep_val=n_rep)
1036 IF (n_rep /= 0) THEN
1037 CALL section_vals_val_get(qs_section, "EPS_FILTER_MATRIX", r_val=qs_control%eps_filter_matrix)
1038 END IF
1039 CALL section_vals_val_get(qs_section, "EPS_CPC", n_rep_val=n_rep)
1040 IF (n_rep /= 0) THEN
1041 CALL section_vals_val_get(qs_section, "EPS_CPC", r_val=qs_control%gapw_control%eps_cpc)
1042 END IF
1043
1044 CALL section_vals_val_get(qs_section, "EPSFIT", r_val=qs_control%gapw_control%eps_fit)
1045 CALL section_vals_val_get(qs_section, "EPSISO", r_val=qs_control%gapw_control%eps_iso)
1046 CALL section_vals_val_get(qs_section, "EPSSVD", r_val=qs_control%gapw_control%eps_svd)
1047 CALL section_vals_val_get(qs_section, "EPSRHO0", r_val=qs_control%gapw_control%eps_Vrho0)
1048 CALL section_vals_val_get(qs_section, "ALPHA0_HARD", r_val=qs_control%gapw_control%alpha0_hard)
1049 qs_control%gapw_control%alpha0_hard_from_input = .false.
1050 IF (qs_control%gapw_control%alpha0_hard /= 0.0_dp) qs_control%gapw_control%alpha0_hard_from_input = .true.
1051 CALL section_vals_val_get(qs_section, "FORCE_PAW", l_val=qs_control%gapw_control%force_paw)
1052 CALL section_vals_val_get(qs_section, "MAX_RAD_LOCAL", r_val=qs_control%gapw_control%max_rad_local)
1053
1054 CALL section_vals_val_get(qs_section, "MIN_PAIR_LIST_RADIUS", r_val=qs_control%pairlist_radius)
1055
1056 CALL section_vals_val_get(qs_section, "LS_SCF", l_val=qs_control%do_ls_scf)
1057 CALL section_vals_val_get(qs_section, "ALMO_SCF", l_val=qs_control%do_almo_scf)
1058 CALL section_vals_val_get(qs_section, "KG_METHOD", l_val=qs_control%do_kg)
1059
1060 ! Logicals
1061 CALL section_vals_val_get(qs_section, "REF_EMBED_SUBSYS", l_val=qs_control%ref_embed_subsys)
1062 CALL section_vals_val_get(qs_section, "CLUSTER_EMBED_SUBSYS", l_val=qs_control%cluster_embed_subsys)
1063 CALL section_vals_val_get(qs_section, "HIGH_LEVEL_EMBED_SUBSYS", l_val=qs_control%high_level_embed_subsys)
1064 CALL section_vals_val_get(qs_section, "DFET_EMBEDDED", l_val=qs_control%dfet_embedded)
1065 CALL section_vals_val_get(qs_section, "DMFET_EMBEDDED", l_val=qs_control%dmfet_embedded)
1066
1067 ! Integers gapw
1068 CALL section_vals_val_get(qs_section, "LMAXN1", i_val=qs_control%gapw_control%lmax_sphere)
1069 CALL section_vals_val_get(qs_section, "LMAXN0", i_val=qs_control%gapw_control%lmax_rho0)
1070 CALL section_vals_val_get(qs_section, "LADDN0", i_val=qs_control%gapw_control%ladd_rho0)
1071 CALL section_vals_val_get(qs_section, "QUADRATURE", i_val=qs_control%gapw_control%quadrature)
1072 ! GAPW 1c basis
1073 CALL section_vals_val_get(qs_section, "GAPW_1C_BASIS", i_val=qs_control%gapw_control%basis_1c)
1074 IF (qs_control%gapw_control%basis_1c /= gapw_1c_orb) THEN
1075 qs_control%gapw_control%eps_svd = max(qs_control%gapw_control%eps_svd, 1.e-12_dp)
1076 END IF
1077 ! GAPW accurate integration
1078 CALL section_vals_val_get(qs_section, "GAPW_ACCURATE_XCINT", l_val=qs_control%gapw_control%accurate_xcint)
1079 CALL section_vals_val_get(qs_section, "ALPHA_WEIGHTS", r_val=qs_control%gapw_control%aweights)
1080
1081 ! Integers grids
1082 CALL section_vals_val_get(qs_section, "PW_GRID", i_val=itmp)
1083 SELECT CASE (itmp)
1084 CASE (do_pwgrid_spherical)
1085 qs_control%pw_grid_opt%spherical = .true.
1086 qs_control%pw_grid_opt%fullspace = .false.
1087 CASE (do_pwgrid_ns_fullspace)
1088 qs_control%pw_grid_opt%spherical = .false.
1089 qs_control%pw_grid_opt%fullspace = .true.
1090 CASE (do_pwgrid_ns_halfspace)
1091 qs_control%pw_grid_opt%spherical = .false.
1092 qs_control%pw_grid_opt%fullspace = .false.
1093 END SELECT
1094
1095 ! Method for PPL calculation
1096 CALL section_vals_val_get(qs_section, "CORE_PPL", i_val=itmp)
1097 qs_control%do_ppl_method = itmp
1098
1099 CALL section_vals_val_get(qs_section, "PW_GRID_LAYOUT", i_vals=tmplist)
1100 qs_control%pw_grid_opt%distribution_layout = tmplist
1101 CALL section_vals_val_get(qs_section, "PW_GRID_BLOCKED", i_val=qs_control%pw_grid_opt%blocked)
1102
1103 !Integers extrapolation
1104 CALL section_vals_val_get(qs_section, "EXTRAPOLATION", i_val=qs_control%wf_interpolation_method_nr)
1105 CALL section_vals_val_get(qs_section, "EXTRAPOLATION_ORDER", i_val=qs_control%wf_extrapolation_order)
1106
1107 !Method
1108 CALL section_vals_val_get(qs_section, "METHOD", i_val=qs_control%method_id)
1109 qs_control%gapw = .false.
1110 qs_control%gapw_xc = .false.
1111 qs_control%gpw = .false.
1112 qs_control%pao = .false.
1113 qs_control%dftb = .false.
1114 qs_control%xtb = .false.
1115 qs_control%semi_empirical = .false.
1116 qs_control%ofgpw = .false.
1117 qs_control%lrigpw = .false.
1118 qs_control%rigpw = .false.
1119 SELECT CASE (qs_control%method_id)
1120 CASE (do_method_gapw)
1121 CALL cite_reference(lippert1999)
1122 CALL cite_reference(krack2000)
1123 qs_control%gapw = .true.
1124 CASE (do_method_gapw_xc)
1125 qs_control%gapw_xc = .true.
1126 CASE (do_method_gpw)
1127 CALL cite_reference(lippert1997)
1128 CALL cite_reference(vandevondele2005a)
1129 qs_control%gpw = .true.
1130 CASE (do_method_ofgpw)
1131 qs_control%ofgpw = .true.
1132 CASE (do_method_lrigpw)
1133 qs_control%lrigpw = .true.
1134 CASE (do_method_rigpw)
1135 qs_control%rigpw = .true.
1136 CASE (do_method_dftb)
1137 qs_control%dftb = .true.
1138 CALL cite_reference(porezag1995)
1139 CALL cite_reference(seifert1996)
1140 CASE (do_method_xtb)
1141 qs_control%xtb = .true.
1142 CALL cite_reference(grimme2017)
1143 CALL cite_reference(pracht2019)
1144 CASE (do_method_mndo)
1145 CALL cite_reference(dewar1977)
1146 qs_control%semi_empirical = .true.
1147 CASE (do_method_am1)
1148 CALL cite_reference(dewar1985)
1149 qs_control%semi_empirical = .true.
1150 CASE (do_method_pm3)
1151 CALL cite_reference(stewart1989)
1152 qs_control%semi_empirical = .true.
1153 CASE (do_method_pnnl)
1154 CALL cite_reference(schenter2008)
1155 qs_control%semi_empirical = .true.
1156 CASE (do_method_pm6)
1157 CALL cite_reference(stewart2007)
1158 qs_control%semi_empirical = .true.
1159 CASE (do_method_pm6fm)
1160 CALL cite_reference(vanvoorhis2015)
1161 qs_control%semi_empirical = .true.
1162 CASE (do_method_pdg)
1163 CALL cite_reference(repasky2002)
1164 qs_control%semi_empirical = .true.
1165 CASE (do_method_rm1)
1166 CALL cite_reference(rocha2006)
1167 qs_control%semi_empirical = .true.
1168 CASE (do_method_mndod)
1169 CALL cite_reference(dewar1977)
1170 CALL cite_reference(thiel1992)
1171 qs_control%semi_empirical = .true.
1172 END SELECT
1173
1174 CALL section_vals_get(mull_section, explicit=qs_control%mulliken_restraint)
1175
1176 IF (qs_control%mulliken_restraint) THEN
1177 CALL section_vals_val_get(mull_section, "STRENGTH", r_val=qs_control%mulliken_restraint_control%strength)
1178 CALL section_vals_val_get(mull_section, "TARGET", r_val=qs_control%mulliken_restraint_control%target)
1179 CALL section_vals_val_get(mull_section, "ATOMS", n_rep_val=n_rep)
1180 jj = 0
1181 DO k = 1, n_rep
1182 CALL section_vals_val_get(mull_section, "ATOMS", i_rep_val=k, i_vals=tmplist)
1183 jj = jj + SIZE(tmplist)
1184 END DO
1185 qs_control%mulliken_restraint_control%natoms = jj
1186 IF (qs_control%mulliken_restraint_control%natoms < 1) &
1187 cpabort("Need at least 1 atom to use mulliken constraints")
1188 ALLOCATE (qs_control%mulliken_restraint_control%atoms(qs_control%mulliken_restraint_control%natoms))
1189 jj = 0
1190 DO k = 1, n_rep
1191 CALL section_vals_val_get(mull_section, "ATOMS", i_rep_val=k, i_vals=tmplist)
1192 DO j = 1, SIZE(tmplist)
1193 jj = jj + 1
1194 qs_control%mulliken_restraint_control%atoms(jj) = tmplist(j)
1195 END DO
1196 END DO
1197 END IF
1198 CALL section_vals_get(ddapc_restraint_section, n_repetition=nrep, explicit=qs_control%ddapc_restraint)
1199 IF (qs_control%ddapc_restraint) THEN
1200 ALLOCATE (qs_control%ddapc_restraint_control(nrep))
1201 CALL read_ddapc_section(qs_control, qs_section=qs_section)
1202 qs_control%ddapc_restraint_is_spin = .false.
1203 qs_control%ddapc_explicit_potential = .false.
1204 END IF
1205
1206 CALL section_vals_get(s2_restraint_section, explicit=qs_control%s2_restraint)
1207 IF (qs_control%s2_restraint) THEN
1208 CALL section_vals_val_get(s2_restraint_section, "STRENGTH", &
1209 r_val=qs_control%s2_restraint_control%strength)
1210 CALL section_vals_val_get(s2_restraint_section, "TARGET", &
1211 r_val=qs_control%s2_restraint_control%target)
1212 CALL section_vals_val_get(s2_restraint_section, "FUNCTIONAL_FORM", &
1213 i_val=qs_control%s2_restraint_control%functional_form)
1214 END IF
1215
1216 CALL section_vals_get(cdft_control_section, explicit=qs_control%cdft)
1217 IF (qs_control%cdft) THEN
1218 CALL read_cdft_control_section(qs_control, cdft_control_section)
1219 END IF
1220
1221 ! Semi-empirical code
1222 IF (qs_control%semi_empirical) THEN
1223 CALL section_vals_val_get(se_section, "ORTHOGONAL_BASIS", &
1224 l_val=qs_control%se_control%orthogonal_basis)
1225 CALL section_vals_val_get(se_section, "DELTA", &
1226 r_val=qs_control%se_control%delta)
1227 CALL section_vals_val_get(se_section, "ANALYTICAL_GRADIENTS", &
1228 l_val=qs_control%se_control%analytical_gradients)
1229 CALL section_vals_val_get(se_section, "FORCE_KDSO-D_EXCHANGE", &
1230 l_val=qs_control%se_control%force_kdsod_EX)
1231 ! Integral Screening
1232 CALL section_vals_val_get(se_section, "INTEGRAL_SCREENING", &
1233 i_val=qs_control%se_control%integral_screening)
1234 IF (qs_control%method_id == do_method_pnnl) THEN
1235 IF (qs_control%se_control%integral_screening /= do_se_is_slater) &
1236 CALL cp_warn(__location__, &
1237 "PNNL semi-empirical parameterization supports only the Slater type "// &
1238 "integral scheme. Revert to Slater and continue the calculation.")
1239 qs_control%se_control%integral_screening = do_se_is_slater
1240 END IF
1241 ! Global Arrays variable
1242 CALL section_vals_val_get(se_section, "GA%NCELLS", &
1243 i_val=qs_control%se_control%ga_ncells)
1244 ! Long-Range correction
1245 CALL section_vals_val_get(se_section, "LR_CORRECTION%CUTOFF", &
1246 r_val=qs_control%se_control%cutoff_lrc)
1247 qs_control%se_control%taper_lrc = qs_control%se_control%cutoff_lrc
1248 CALL section_vals_val_get(se_section, "LR_CORRECTION%RC_TAPER", &
1249 explicit=explicit)
1250 IF (explicit) THEN
1251 CALL section_vals_val_get(se_section, "LR_CORRECTION%RC_TAPER", &
1252 r_val=qs_control%se_control%taper_lrc)
1253 END IF
1254 CALL section_vals_val_get(se_section, "LR_CORRECTION%RC_RANGE", &
1255 r_val=qs_control%se_control%range_lrc)
1256 ! Coulomb
1257 CALL section_vals_val_get(se_section, "COULOMB%CUTOFF", &
1258 r_val=qs_control%se_control%cutoff_cou)
1259 qs_control%se_control%taper_cou = qs_control%se_control%cutoff_cou
1260 CALL section_vals_val_get(se_section, "COULOMB%RC_TAPER", &
1261 explicit=explicit)
1262 IF (explicit) THEN
1263 CALL section_vals_val_get(se_section, "COULOMB%RC_TAPER", &
1264 r_val=qs_control%se_control%taper_cou)
1265 END IF
1266 CALL section_vals_val_get(se_section, "COULOMB%RC_RANGE", &
1267 r_val=qs_control%se_control%range_cou)
1268 ! Exchange
1269 CALL section_vals_val_get(se_section, "EXCHANGE%CUTOFF", &
1270 r_val=qs_control%se_control%cutoff_exc)
1271 qs_control%se_control%taper_exc = qs_control%se_control%cutoff_exc
1272 CALL section_vals_val_get(se_section, "EXCHANGE%RC_TAPER", &
1273 explicit=explicit)
1274 IF (explicit) THEN
1275 CALL section_vals_val_get(se_section, "EXCHANGE%RC_TAPER", &
1276 r_val=qs_control%se_control%taper_exc)
1277 END IF
1278 CALL section_vals_val_get(se_section, "EXCHANGE%RC_RANGE", &
1279 r_val=qs_control%se_control%range_exc)
1280 ! Screening (only if the integral scheme is of dumped type)
1281 IF (qs_control%se_control%integral_screening == do_se_is_kdso_d) THEN
1282 CALL section_vals_val_get(se_section, "SCREENING%RC_TAPER", &
1283 r_val=qs_control%se_control%taper_scr)
1284 CALL section_vals_val_get(se_section, "SCREENING%RC_RANGE", &
1285 r_val=qs_control%se_control%range_scr)
1286 END IF
1287 ! Periodic Type Calculation
1288 CALL section_vals_val_get(se_section, "PERIODIC", &
1289 i_val=qs_control%se_control%periodic_type)
1290 SELECT CASE (qs_control%se_control%periodic_type)
1291 CASE (do_se_lr_none)
1292 qs_control%se_control%do_ewald = .false.
1293 qs_control%se_control%do_ewald_r3 = .false.
1294 qs_control%se_control%do_ewald_gks = .false.
1295 CASE (do_se_lr_ewald)
1296 qs_control%se_control%do_ewald = .true.
1297 qs_control%se_control%do_ewald_r3 = .false.
1298 qs_control%se_control%do_ewald_gks = .false.
1299 CASE (do_se_lr_ewald_gks)
1300 qs_control%se_control%do_ewald = .false.
1301 qs_control%se_control%do_ewald_r3 = .false.
1302 qs_control%se_control%do_ewald_gks = .true.
1303 IF (qs_control%method_id /= do_method_pnnl) &
1304 CALL cp_abort(__location__, &
1305 "A periodic semi-empirical calculation was requested with a long-range "// &
1306 "summation on the single integral evaluation. This scheme is supported "// &
1307 "only by the PNNL parameterization.")
1308 CASE (do_se_lr_ewald_r3)
1309 qs_control%se_control%do_ewald = .true.
1310 qs_control%se_control%do_ewald_r3 = .true.
1311 qs_control%se_control%do_ewald_gks = .false.
1312 IF (qs_control%se_control%integral_screening /= do_se_is_kdso) &
1313 CALL cp_abort(__location__, &
1314 "A periodic semi-empirical calculation was requested with a long-range "// &
1315 "summation for the slowly convergent part 1/R^3, which is not congruent "// &
1316 "with the integral screening chosen. The only integral screening supported "// &
1317 "by this periodic type calculation is the standard Klopman-Dewar-Sabelli-Ohno.")
1318 END SELECT
1319
1320 ! dispersion pair potentials
1321 CALL section_vals_val_get(se_section, "DISPERSION", &
1322 l_val=qs_control%se_control%dispersion)
1323 CALL section_vals_val_get(se_section, "DISPERSION_RADIUS", &
1324 r_val=qs_control%se_control%rcdisp)
1325 CALL section_vals_val_get(se_section, "COORDINATION_CUTOFF", &
1326 r_val=qs_control%se_control%epscn)
1327 CALL section_vals_val_get(se_section, "D3_SCALING", r_vals=scal)
1328 qs_control%se_control%sd3(1) = scal(1)
1329 qs_control%se_control%sd3(2) = scal(2)
1330 qs_control%se_control%sd3(3) = scal(3)
1331 CALL section_vals_val_get(se_section, "DISPERSION_PARAMETER_FILE", &
1332 c_val=qs_control%se_control%dispersion_parameter_file)
1333
1334 ! Stop the execution for non-implemented features
1335 IF (qs_control%se_control%periodic_type == do_se_lr_ewald_r3) THEN
1336 cpabort("EWALD_R3 not implemented yet!")
1337 END IF
1338
1339 IF (qs_control%method_id == do_method_mndo .OR. &
1340 qs_control%method_id == do_method_am1 .OR. &
1341 qs_control%method_id == do_method_mndod .OR. &
1342 qs_control%method_id == do_method_pdg .OR. &
1343 qs_control%method_id == do_method_pm3 .OR. &
1344 qs_control%method_id == do_method_pm6 .OR. &
1345 qs_control%method_id == do_method_pm6fm .OR. &
1346 qs_control%method_id == do_method_pnnl .OR. &
1347 qs_control%method_id == do_method_rm1) THEN
1348 qs_control%se_control%orthogonal_basis = .true.
1349 END IF
1350 END IF
1351
1352 ! DFTB code
1353 IF (qs_control%dftb) THEN
1354 CALL section_vals_val_get(dftb_section, "ORTHOGONAL_BASIS", &
1355 l_val=qs_control%dftb_control%orthogonal_basis)
1356 CALL section_vals_val_get(dftb_section, "SELF_CONSISTENT", &
1357 l_val=qs_control%dftb_control%self_consistent)
1358 CALL section_vals_val_get(dftb_section, "DISPERSION", &
1359 l_val=qs_control%dftb_control%dispersion)
1360 CALL section_vals_val_get(dftb_section, "DIAGONAL_DFTB3", &
1361 l_val=qs_control%dftb_control%dftb3_diagonal)
1362 CALL section_vals_val_get(dftb_section, "HB_SR_GAMMA", &
1363 l_val=qs_control%dftb_control%hb_sr_damp)
1364 CALL section_vals_val_get(dftb_section, "SCC_MIXER", &
1365 explicit=dftb_scc_mixer_explicit)
1366 CALL section_vals_val_get(dftb_section, "SCC_MIXER", &
1367 i_val=qs_control%dftb_control%tblite_scc_mixer)
1368 CALL section_vals_get(dftb_tblite_mixer, explicit=dftb_tblite_mixer_explicit)
1369 CALL read_tblite_mixer_section(dftb_tblite_mixer, &
1370 qs_control%dftb_control%tblite_mixer_iterations, &
1371 qs_control%dftb_control%tblite_mixer_memory, &
1372 qs_control%dftb_control%tblite_mixer_solver, &
1373 qs_control%dftb_control%tblite_mixer_damping, &
1374 qs_control%dftb_control%tblite_mixer_omega0, &
1375 qs_control%dftb_control%tblite_mixer_min_weight, &
1376 qs_control%dftb_control%tblite_mixer_max_weight, &
1377 qs_control%dftb_control%tblite_mixer_weight_factor, &
1378 "DFTB/TBLITE_MIXER")
1379 IF (qs_control%do_ls_scf) THEN
1380 IF (dftb_scc_mixer_explicit .AND. &
1381 qs_control%dftb_control%tblite_scc_mixer /= tblite_scc_mixer_none) &
1382 CALL cp_warn(__location__, &
1383 "DFTB/SCC_MIXER is reset to NONE with QS/LS_SCF; LS_SCF optimizes "// &
1384 "the density matrix directly.")
1385 IF (dftb_tblite_mixer_explicit) &
1386 CALL cp_warn(__location__, &
1387 "DFTB/TBLITE_MIXER settings are ignored with QS/LS_SCF; LS_SCF controls "// &
1388 "the density-matrix optimization.")
1389 qs_control%dftb_control%tblite_scc_mixer = tblite_scc_mixer_none
1390 END IF
1391 IF (qs_control%dftb_control%tblite_mixer_damping <= 0.0_dp) &
1392 cpabort("DFTB/TBLITE_MIXER/DAMPING must be positive")
1393 CALL section_vals_val_get(dftb_section, "EPS_DISP", &
1394 r_val=qs_control%dftb_control%eps_disp)
1395 CALL section_vals_val_get(dftb_section, "DO_EWALD", explicit=explicit)
1396 IF (explicit) THEN
1397 CALL section_vals_val_get(dftb_section, "DO_EWALD", &
1398 l_val=qs_control%dftb_control%do_ewald)
1399 ELSE
1400 qs_control%dftb_control%do_ewald = (qs_control%periodicity /= 0)
1401 END IF
1402 CALL section_vals_val_get(dftb_parameter, "PARAM_FILE_PATH", &
1403 c_val=qs_control%dftb_control%sk_file_path)
1404 CALL section_vals_val_get(dftb_parameter, "PARAM_FILE_NAME", &
1405 c_val=qs_control%dftb_control%sk_file_list)
1406 CALL section_vals_val_get(dftb_parameter, "HB_SR_PARAM", &
1407 r_val=qs_control%dftb_control%hb_sr_para)
1408 CALL section_vals_val_get(dftb_parameter, "SK_FILE", n_rep_val=n_var)
1409 ALLOCATE (qs_control%dftb_control%sk_pair_list(3, n_var))
1410 DO k = 1, n_var
1411 CALL section_vals_val_get(dftb_parameter, "SK_FILE", i_rep_val=k, &
1412 c_vals=clist)
1413 qs_control%dftb_control%sk_pair_list(1:3, k) = clist(1:3)
1414 END DO
1415 ! Dispersion type
1416 CALL section_vals_val_get(dftb_parameter, "DISPERSION_TYPE", &
1417 i_val=qs_control%dftb_control%dispersion_type)
1418 CALL section_vals_val_get(dftb_parameter, "UFF_FORCE_FIELD", &
1419 c_val=qs_control%dftb_control%uff_force_field)
1420 ! D3 Dispersion
1421 CALL section_vals_val_get(dftb_parameter, "DISPERSION_RADIUS", &
1422 r_val=qs_control%dftb_control%rcdisp)
1423 CALL section_vals_val_get(dftb_parameter, "COORDINATION_CUTOFF", &
1424 r_val=qs_control%dftb_control%epscn)
1425 CALL section_vals_val_get(dftb_parameter, "D2_EXP_PRE", &
1426 r_val=qs_control%dftb_control%exp_pre)
1427 CALL section_vals_val_get(dftb_parameter, "D2_SCALING", &
1428 r_val=qs_control%dftb_control%scaling)
1429 CALL section_vals_val_get(dftb_parameter, "D3_SCALING", r_vals=scal)
1430 qs_control%dftb_control%sd3(1) = scal(1)
1431 qs_control%dftb_control%sd3(2) = scal(2)
1432 qs_control%dftb_control%sd3(3) = scal(3)
1433 CALL section_vals_val_get(dftb_parameter, "D3BJ_SCALING", r_vals=scal)
1434 qs_control%dftb_control%sd3bj(1) = scal(1)
1435 qs_control%dftb_control%sd3bj(2) = scal(2)
1436 qs_control%dftb_control%sd3bj(3) = scal(3)
1437 qs_control%dftb_control%sd3bj(4) = scal(4)
1438 CALL section_vals_val_get(dftb_parameter, "DISPERSION_PARAMETER_FILE", &
1439 c_val=qs_control%dftb_control%dispersion_parameter_file)
1440
1441 IF (qs_control%dftb_control%dispersion) CALL cite_reference(zhechkov2005)
1442 IF (qs_control%dftb_control%self_consistent) CALL cite_reference(elstner1998)
1443 IF (qs_control%dftb_control%hb_sr_damp) CALL cite_reference(hu2007)
1444 END IF
1445
1446 ! xTB code
1447 IF (qs_control%xtb) THEN
1448 CALL section_vals_val_get(xtb_section, "GFN_TYPE", i_val=qs_control%xtb_control%gfn_type)
1449 CALL section_vals_val_get(xtb_tblite, "_SECTION_PARAMETERS_", l_val=tblite_section_active)
1450 qs_control%xtb_control%do_tblite = (qs_control%xtb_control%gfn_type == gfn_tblite)
1451 IF (qs_control%xtb_control%do_tblite) THEN
1452 IF (.NOT. tblite_section_active) &
1453 cpabort("XTB/GFN_TYPE TBLITE requires an XTB/TBLITE section")
1454 ! The CP2K-internal GFN1 defaults are still used to initialize shared xTB fields.
1455 qs_control%xtb_control%gfn_type = gfn1xtb
1456 ELSE IF (tblite_section_active) THEN
1457 cpabort("The XTB/TBLITE section requires XTB/GFN_TYPE TBLITE")
1458 END IF
1459 CALL section_vals_val_get(xtb_section, "SCC_MIXER", &
1460 explicit=xtb_scc_mixer_explicit)
1461 CALL section_vals_val_get(xtb_section, "SCC_MIXER", &
1462 i_val=qs_control%xtb_control%tblite_scc_mixer)
1463 CALL section_vals_get(xtb_tblite_mixer, explicit=xtb_tblite_mixer_explicit)
1464 CALL read_tblite_mixer_section(xtb_tblite_mixer, &
1465 qs_control%xtb_control%tblite_mixer_iterations, &
1466 qs_control%xtb_control%tblite_mixer_memory, &
1467 qs_control%xtb_control%tblite_mixer_solver, &
1468 qs_control%xtb_control%tblite_mixer_damping, &
1469 qs_control%xtb_control%tblite_mixer_omega0, &
1470 qs_control%xtb_control%tblite_mixer_min_weight, &
1471 qs_control%xtb_control%tblite_mixer_max_weight, &
1472 qs_control%xtb_control%tblite_mixer_weight_factor, &
1473 "XTB/TBLITE_MIXER")
1474 IF (xtb_tblite_mixer_explicit) &
1475 CALL section_vals_val_get(xtb_tblite_mixer, "DAMPING", &
1476 explicit=qs_control%xtb_control%tblite_mixer_damping_explicit)
1477 IF ((.NOT. qs_control%xtb_control%do_tblite) .AND. &
1478 qs_control%xtb_control%gfn_type == 0) THEN
1479 IF (xtb_scc_mixer_explicit .AND. &
1480 qs_control%xtb_control%tblite_scc_mixer /= tblite_scc_mixer_auto .AND. &
1481 qs_control%xtb_control%tblite_scc_mixer /= tblite_scc_mixer_none) &
1482 CALL cp_warn(__location__, &
1483 "XTB/SCC_MIXER is reset to NONE for CP2K-internal GFN0-xTB; "// &
1484 "GFN0-xTB has no SCC variables to mix.")
1485 IF (xtb_tblite_mixer_explicit) &
1486 CALL cp_warn(__location__, &
1487 "XTB/TBLITE_MIXER settings are ignored for CP2K-internal GFN0-xTB; "// &
1488 "GFN0-xTB has no SCC variables to mix.")
1489 qs_control%xtb_control%tblite_scc_mixer = tblite_scc_mixer_none
1490 END IF
1491 IF (qs_control%do_ls_scf) THEN
1492 IF (xtb_scc_mixer_explicit .AND. &
1493 qs_control%xtb_control%tblite_scc_mixer /= tblite_scc_mixer_none) &
1494 CALL cp_warn(__location__, &
1495 "XTB/SCC_MIXER is reset to NONE with QS/LS_SCF; LS_SCF optimizes "// &
1496 "the density matrix directly.")
1497 IF (xtb_tblite_mixer_explicit) &
1498 CALL cp_warn(__location__, &
1499 "XTB/TBLITE_MIXER settings are ignored with QS/LS_SCF; LS_SCF controls "// &
1500 "the density-matrix optimization.")
1501 qs_control%xtb_control%tblite_scc_mixer = tblite_scc_mixer_none
1502 END IF
1503 IF (qs_control%xtb_control%tblite_mixer_damping <= 0.0_dp) &
1504 cpabort("XTB/TBLITE_MIXER/DAMPING must be positive")
1505 CALL section_vals_val_get(xtb_section, "DO_EWALD", explicit=explicit)
1506 IF (explicit) THEN
1507 CALL section_vals_val_get(xtb_section, "DO_EWALD", &
1508 l_val=qs_control%xtb_control%do_ewald)
1509 ELSE
1510 qs_control%xtb_control%do_ewald = (qs_control%periodicity /= 0)
1511 END IF
1512 ! vdW
1513 CALL section_vals_val_get(xtb_section, "VDW_POTENTIAL", explicit=explicit)
1514 IF (explicit) THEN
1515 CALL section_vals_val_get(xtb_section, "VDW_POTENTIAL", c_val=cval)
1516 CALL uppercase(cval)
1517 SELECT CASE (cval)
1518 CASE ("NONE")
1519 qs_control%xtb_control%vdw_type = xtb_vdw_type_none
1520 CASE ("DFTD3")
1521 qs_control%xtb_control%vdw_type = xtb_vdw_type_d3
1522 CASE ("DFTD4")
1523 qs_control%xtb_control%vdw_type = xtb_vdw_type_d4
1524 CASE DEFAULT
1525 cpabort("vdW type")
1526 END SELECT
1527 ELSE
1528 SELECT CASE (qs_control%xtb_control%gfn_type)
1529 CASE (0)
1530 qs_control%xtb_control%vdw_type = xtb_vdw_type_d4
1531 CASE (1)
1532 qs_control%xtb_control%vdw_type = xtb_vdw_type_d3
1533 CASE (2)
1534 qs_control%xtb_control%vdw_type = xtb_vdw_type_d4
1535 cpabort("gfn2-xtb tbd")
1536 CASE DEFAULT
1537 cpabort("GFN type")
1538 END SELECT
1539 END IF
1540 !
1541 CALL section_vals_val_get(xtb_section, "STO_NG", i_val=ngauss)
1542 qs_control%xtb_control%sto_ng = ngauss
1543 CALL section_vals_val_get(xtb_section, "HYDROGEN_STO_NG", i_val=ngauss)
1544 qs_control%xtb_control%h_sto_ng = ngauss
1545 CALL section_vals_val_get(xtb_parameter, "PARAM_FILE_PATH", &
1546 c_val=qs_control%xtb_control%parameter_file_path)
1547 CALL section_vals_val_get(xtb_parameter, "PARAM_FILE_NAME", explicit=explicit)
1548 IF (explicit) THEN
1549 CALL section_vals_val_get(xtb_parameter, "PARAM_FILE_NAME", &
1550 c_val=qs_control%xtb_control%parameter_file_name)
1551 ELSE
1552 SELECT CASE (qs_control%xtb_control%gfn_type)
1553 CASE (0)
1554 qs_control%xtb_control%parameter_file_name = "xTB0_parameters"
1555 CASE (1)
1556 qs_control%xtb_control%parameter_file_name = "xTB1_parameters"
1557 CASE (2)
1558 cpabort("gfn2-xtb tbd")
1559 CASE DEFAULT
1560 cpabort("GFN type")
1561 END SELECT
1562 END IF
1563 ! D3 Dispersion
1564 CALL section_vals_val_get(xtb_parameter, "DISPERSION_RADIUS", &
1565 r_val=qs_control%xtb_control%rcdisp)
1566 CALL section_vals_val_get(xtb_parameter, "COORDINATION_CUTOFF", &
1567 r_val=qs_control%xtb_control%epscn)
1568 CALL section_vals_val_get(xtb_parameter, "D3BJ_SCALING", explicit=explicit)
1569 IF (explicit) THEN
1570 CALL section_vals_val_get(xtb_parameter, "D3BJ_SCALING", r_vals=scal)
1571 qs_control%xtb_control%s6 = scal(1)
1572 qs_control%xtb_control%s8 = scal(2)
1573 ELSE
1574 SELECT CASE (qs_control%xtb_control%gfn_type)
1575 CASE (0)
1576 qs_control%xtb_control%s6 = 1.00_dp
1577 qs_control%xtb_control%s8 = 2.85_dp
1578 CASE (1)
1579 qs_control%xtb_control%s6 = 1.00_dp
1580 qs_control%xtb_control%s8 = 2.40_dp
1581 CASE (2)
1582 cpabort("gfn2-xtb tbd")
1583 CASE DEFAULT
1584 cpabort("GFN type")
1585 END SELECT
1586 END IF
1587 CALL section_vals_val_get(xtb_parameter, "D3BJ_PARAM", explicit=explicit)
1588 IF (explicit) THEN
1589 CALL section_vals_val_get(xtb_parameter, "D3BJ_PARAM", r_vals=scal)
1590 qs_control%xtb_control%a1 = scal(1)
1591 qs_control%xtb_control%a2 = scal(2)
1592 ELSE
1593 SELECT CASE (qs_control%xtb_control%gfn_type)
1594 CASE (0)
1595 qs_control%xtb_control%a1 = 0.80_dp
1596 qs_control%xtb_control%a2 = 4.60_dp
1597 CASE (1)
1598 qs_control%xtb_control%a1 = 0.63_dp
1599 qs_control%xtb_control%a2 = 5.00_dp
1600 CASE (2)
1601 cpabort("gfn2-xtb tbd")
1602 CASE DEFAULT
1603 cpabort("GFN type")
1604 END SELECT
1605 END IF
1606 CALL section_vals_val_get(xtb_parameter, "DISPERSION_PARAMETER_FILE", &
1607 c_val=qs_control%xtb_control%dispersion_parameter_file)
1608 ! global parameters
1609 CALL section_vals_val_get(xtb_parameter, "HUCKEL_CONSTANTS", explicit=explicit)
1610 IF (explicit) THEN
1611 CALL section_vals_val_get(xtb_parameter, "HUCKEL_CONSTANTS", r_vals=scal)
1612 qs_control%xtb_control%ks = scal(1)
1613 qs_control%xtb_control%kp = scal(2)
1614 qs_control%xtb_control%kd = scal(3)
1615 qs_control%xtb_control%ksp = scal(4)
1616 qs_control%xtb_control%k2sh = scal(5)
1617 IF (qs_control%xtb_control%gfn_type == 0) THEN
1618 ! enforce ksp for gfn0
1619 qs_control%xtb_control%ksp = 0.5_dp*(scal(1) + scal(2))
1620 END IF
1621 ELSE
1622 SELECT CASE (qs_control%xtb_control%gfn_type)
1623 CASE (0)
1624 qs_control%xtb_control%ks = 2.00_dp
1625 qs_control%xtb_control%kp = 2.4868_dp
1626 qs_control%xtb_control%kd = 2.27_dp
1627 qs_control%xtb_control%ksp = 2.2434_dp
1628 qs_control%xtb_control%k2sh = 1.1241_dp
1629 CASE (1)
1630 qs_control%xtb_control%ks = 1.85_dp
1631 qs_control%xtb_control%kp = 2.25_dp
1632 qs_control%xtb_control%kd = 2.00_dp
1633 qs_control%xtb_control%ksp = 2.08_dp
1634 qs_control%xtb_control%k2sh = 2.85_dp
1635 CASE (2)
1636 cpabort("gfn2-xtb tbd")
1637 CASE DEFAULT
1638 cpabort("GFN type")
1639 END SELECT
1640 END IF
1641 CALL section_vals_val_get(xtb_parameter, "COULOMB_CONSTANTS", explicit=explicit)
1642 IF (explicit) THEN
1643 CALL section_vals_val_get(xtb_parameter, "COULOMB_CONSTANTS", r_vals=scal)
1644 qs_control%xtb_control%kg = scal(1)
1645 qs_control%xtb_control%kf = scal(2)
1646 ELSE
1647 SELECT CASE (qs_control%xtb_control%gfn_type)
1648 CASE (0)
1649 qs_control%xtb_control%kg = 2.00_dp
1650 qs_control%xtb_control%kf = 1.50_dp
1651 CASE (1)
1652 qs_control%xtb_control%kg = 2.00_dp
1653 qs_control%xtb_control%kf = 1.50_dp
1654 CASE (2)
1655 cpabort("gfn2-xtb tbd")
1656 CASE DEFAULT
1657 cpabort("GFN type")
1658 END SELECT
1659 END IF
1660 CALL section_vals_val_get(xtb_parameter, "CN_CONSTANTS", r_vals=scal)
1661 qs_control%xtb_control%kcns = scal(1)
1662 qs_control%xtb_control%kcnp = scal(2)
1663 qs_control%xtb_control%kcnd = scal(3)
1664 !
1665 CALL section_vals_val_get(xtb_parameter, "EN_CONSTANTS", explicit=explicit)
1666 IF (explicit) THEN
1667 CALL section_vals_val_get(xtb_parameter, "EN_CONSTANTS", r_vals=scal)
1668 SELECT CASE (qs_control%xtb_control%gfn_type)
1669 CASE (0)
1670 qs_control%xtb_control%ksen = scal(1)
1671 qs_control%xtb_control%kpen = scal(2)
1672 qs_control%xtb_control%kden = scal(3)
1673 CASE (1)
1674 qs_control%xtb_control%ken = scal(1)
1675 CASE (2)
1676 cpabort("gfn2-xtb tbd")
1677 CASE DEFAULT
1678 cpabort("GFN type")
1679 END SELECT
1680 ELSE
1681 SELECT CASE (qs_control%xtb_control%gfn_type)
1682 CASE (0)
1683 qs_control%xtb_control%ksen = 0.006_dp
1684 qs_control%xtb_control%kpen = -0.001_dp
1685 qs_control%xtb_control%kden = -0.002_dp
1686 CASE (1)
1687 qs_control%xtb_control%ken = -0.007_dp
1688 CASE (2)
1689 cpabort("gfn2-xtb tbd")
1690 CASE DEFAULT
1691 cpabort("GFN type")
1692 END SELECT
1693 END IF
1694 ! ben
1695 CALL section_vals_val_get(xtb_parameter, "BEN_CONSTANT", r_vals=scal)
1696 qs_control%xtb_control%ben = scal(1)
1697 ! enscale (hidden parameter in repulsion
1698 CALL section_vals_val_get(xtb_parameter, "ENSCALE", explicit=explicit)
1699 IF (explicit) THEN
1700 CALL section_vals_val_get(xtb_parameter, "ENSCALE", &
1701 r_val=qs_control%xtb_control%enscale)
1702 ELSE
1703 SELECT CASE (qs_control%xtb_control%gfn_type)
1704 CASE (0)
1705 qs_control%xtb_control%enscale = -0.09_dp
1706 CASE (1)
1707 qs_control%xtb_control%enscale = 0._dp
1708 CASE (2)
1709 cpabort("gfn2-xtb tbd")
1710 CASE DEFAULT
1711 cpabort("GFN type")
1712 END SELECT
1713 END IF
1714 ! XB
1715 CALL section_vals_val_get(xtb_section, "USE_HALOGEN_CORRECTION", &
1716 l_val=qs_control%xtb_control%xb_interaction)
1717 CALL section_vals_val_get(xtb_parameter, "HALOGEN_BINDING", r_vals=scal)
1718 qs_control%xtb_control%kxr = scal(1)
1719 qs_control%xtb_control%kx2 = scal(2)
1720 ! NONBONDED interactions
1721 CALL section_vals_val_get(xtb_section, "DO_NONBONDED", &
1722 l_val=qs_control%xtb_control%do_nonbonded)
1723 CALL section_vals_get(nonbonded_section, explicit=explicit)
1724 IF (explicit .AND. qs_control%xtb_control%do_nonbonded) THEN
1725 CALL section_vals_get(genpot_section, explicit=explicit, n_repetition=ngp)
1726 IF (explicit) THEN
1727 CALL pair_potential_reallocate(qs_control%xtb_control%nonbonded, 1, ngp, gp=.true.)
1728 CALL read_gp_section(qs_control%xtb_control%nonbonded, genpot_section, 0)
1729 END IF
1730 END IF !nonbonded
1731 CALL section_vals_val_get(xtb_section, "EPS_PAIRPOTENTIAL", &
1732 r_val=qs_control%xtb_control%eps_pair)
1733 ! SR Coulomb
1734 CALL section_vals_val_get(xtb_parameter, "COULOMB_SR_CUT", r_vals=scal)
1735 qs_control%xtb_control%coulomb_sr_cut = scal(1)
1736 CALL section_vals_val_get(xtb_parameter, "COULOMB_SR_EPS", r_vals=scal)
1737 qs_control%xtb_control%coulomb_sr_eps = scal(1)
1738 ! XB_radius
1739 CALL section_vals_val_get(xtb_parameter, "XB_RADIUS", r_val=qs_control%xtb_control%xb_radius)
1740 ! Kab
1741 CALL section_vals_val_get(xtb_parameter, "KAB_PARAM", n_rep_val=n_rep)
1742 ! Coulomb
1743 SELECT CASE (qs_control%xtb_control%gfn_type)
1744 CASE (0)
1745 qs_control%xtb_control%coulomb_interaction = .false.
1746 qs_control%xtb_control%coulomb_lr = .false.
1747 qs_control%xtb_control%tb3_interaction = .false.
1748 qs_control%xtb_control%check_atomic_charges = .false.
1749 CALL section_vals_val_get(xtb_section, "VARIATIONAL_DIPOLE", &
1750 l_val=qs_control%xtb_control%var_dipole)
1751 CASE (1)
1752 ! For debugging purposes
1753 CALL section_vals_val_get(xtb_section, "COULOMB_INTERACTION", &
1754 l_val=qs_control%xtb_control%coulomb_interaction)
1755 CALL section_vals_val_get(xtb_section, "COULOMB_LR", &
1756 l_val=qs_control%xtb_control%coulomb_lr)
1757 CALL section_vals_val_get(xtb_section, "TB3_INTERACTION", &
1758 l_val=qs_control%xtb_control%tb3_interaction)
1759 ! Check for bad atomic charges
1760 CALL section_vals_val_get(xtb_section, "CHECK_ATOMIC_CHARGES", &
1761 l_val=qs_control%xtb_control%check_atomic_charges)
1762 qs_control%xtb_control%var_dipole = .false.
1763 CASE (2)
1764 cpabort("gfn2-xtb tbd")
1765 CASE DEFAULT
1766 cpabort("GFN type")
1767 END SELECT
1768 qs_control%xtb_control%kab_nval = n_rep
1769 IF (n_rep > 0) THEN
1770 ALLOCATE (qs_control%xtb_control%kab_param(3, n_rep))
1771 ALLOCATE (qs_control%xtb_control%kab_types(2, n_rep))
1772 ALLOCATE (qs_control%xtb_control%kab_vals(n_rep))
1773 DO j = 1, n_rep
1774 CALL section_vals_val_get(xtb_parameter, "KAB_PARAM", i_rep_val=j, c_vals=clist)
1775 qs_control%xtb_control%kab_param(1, j) = clist(1)
1776 CALL get_ptable_info(clist(1), &
1777 ielement=qs_control%xtb_control%kab_types(1, j))
1778 qs_control%xtb_control%kab_param(2, j) = clist(2)
1779 CALL get_ptable_info(clist(2), &
1780 ielement=qs_control%xtb_control%kab_types(2, j))
1781 qs_control%xtb_control%kab_param(3, j) = clist(3)
1782 READ (clist(3), '(F10.0)') qs_control%xtb_control%kab_vals(j)
1783 END DO
1784 END IF
1785
1786 IF (qs_control%xtb_control%gfn_type == 0) THEN
1787 CALL section_vals_val_get(xtb_parameter, "SRB_PARAMETER", r_vals=scal)
1788 qs_control%xtb_control%ksrb = scal(1)
1789 qs_control%xtb_control%esrb = scal(2)
1790 qs_control%xtb_control%gscal = scal(3)
1791 qs_control%xtb_control%c1srb = scal(4)
1792 qs_control%xtb_control%c2srb = scal(5)
1793 qs_control%xtb_control%shift = scal(6)
1794 END IF
1795
1796 CALL section_vals_val_get(xtb_section, "EN_SHIFT_TYPE", c_val=cval)
1797 CALL uppercase(cval)
1798 SELECT CASE (trim(cval))
1799 CASE ("SELECT")
1800 qs_control%xtb_control%enshift_type = 0
1801 CASE ("MOLECULE")
1802 qs_control%xtb_control%enshift_type = 1
1803 CASE ("CRYSTAL")
1804 qs_control%xtb_control%enshift_type = 2
1805 CASE DEFAULT
1806 cpabort("Unknown value for EN_SHIFT_TYPE")
1807 END SELECT
1808
1809 ! EEQ solver params
1810 CALL read_eeq_param(eeq_section, qs_control%xtb_control%eeq_sparam)
1811 END IF
1812
1813 ! Optimize LRI basis set
1814 CALL section_vals_get(lri_optbas_section, explicit=qs_control%lri_optbas)
1815
1816 ! Use tblite if selected through XTB/GFN_TYPE TBLITE.
1817 IF (qs_control%xtb_control%do_tblite) THEN
1818 CALL section_vals_val_get(xtb_tblite, "METHOD", &
1819 i_val=qs_control%xtb_control%tblite_method)
1820 CALL section_vals_val_get(xtb_tblite, "PARAM", &
1821 c_val=qs_control%xtb_control%tblite_param_file)
1822 CALL section_vals_val_get(xtb_tblite, "ACCURACY", &
1823 r_val=qs_control%xtb_control%tblite_accuracy)
1824 IF (qs_control%xtb_control%tblite_accuracy <= 0.0_dp) &
1825 cpabort("XTB/TBLITE/ACCURACY must be positive")
1826 IF (qs_control%xtb_control%tblite_mixer_damping <= 0.0_dp) &
1827 cpabort("XTB/TBLITE_MIXER/DAMPING must be positive")
1828 CALL section_vals_val_get(xtb_tblite, "REFERENCE_CLI", l_val=tblite_reference_cli)
1829 CALL section_vals_get(xtb_tblite_ref_cli, explicit=tblite_reference_cli_section)
1830 IF (tblite_reference_cli .AND. (.NOT. tblite_reference_cli_section)) &
1831 cpabort("XTB/TBLITE/REFERENCE_CLI keyword requires an XTB/TBLITE/REFERENCE_CLI section")
1832 IF (tblite_reference_cli .OR. tblite_reference_cli_section) THEN
1833 CALL read_xtb_reference_cli_section(xtb_tblite_ref_cli, qs_control%xtb_control%reference_cli, cell)
1834 qs_control%xtb_control%reference_cli%enabled = .true.
1835 END IF
1836 CALL cite_reference(katbashev2025)
1837 ! tblite handles periodic long-range terms internally from the CP2K cell periodicity.
1838 ! Keep xtb_control%do_ewald as read above from XTB/DO_EWALD or SUBSYS/CELL/PERIODIC,
1839 ! matching the DFTB and CP2K-internal xTB setup.
1840 END IF
1841
1842 CALL timestop(handle)
1843 END SUBROUTINE read_qs_section
1844
1845! **************************************************************************************************
1846!> \brief Read a TBLITE_MIXER section.
1847!> \param mixer_section input section
1848!> \param iterations tblite SCC iteration limit
1849!> \param memory Broyden history length
1850!> \param solver native tblite electronic solver id
1851!> \param damping mixer damping parameter
1852!> \param omega0 Broyden regularization weight
1853!> \param min_weight minimum dynamic Broyden weight
1854!> \param max_weight maximum dynamic Broyden weight
1855!> \param weight_factor residual-to-weight scaling factor
1856!> \param section_name diagnostic section name
1857! **************************************************************************************************
1858 SUBROUTINE read_tblite_mixer_section(mixer_section, iterations, memory, solver, damping, omega0, min_weight, &
1859 max_weight, weight_factor, section_name)
1860 TYPE(section_vals_type), POINTER :: mixer_section
1861 INTEGER, INTENT(INOUT) :: iterations, memory, solver
1862 REAL(kind=dp), INTENT(INOUT) :: damping, omega0, min_weight, max_weight, &
1863 weight_factor
1864 CHARACTER(LEN=*), INTENT(IN) :: section_name
1865
1866 LOGICAL :: explicit, memory_explicit
1867
1868 CALL section_vals_get(mixer_section, explicit=explicit)
1869 IF (.NOT. explicit) RETURN
1870
1871 CALL section_vals_val_get(mixer_section, "ITERATIONS", i_val=iterations)
1872 CALL section_vals_val_get(mixer_section, "MEMORY", explicit=memory_explicit)
1873 IF (memory_explicit) CALL section_vals_val_get(mixer_section, "MEMORY", i_val=memory)
1874 IF (.NOT. memory_explicit .OR. memory == tblite_mixer_memory_inherit) THEN
1875 memory = iterations
1876 END IF
1877 CALL section_vals_val_get(mixer_section, "SOLVER", i_val=solver)
1878 CALL section_vals_val_get(mixer_section, "DAMPING", r_val=damping)
1879 CALL section_vals_val_get(mixer_section, "OMEGA0", r_val=omega0)
1880 CALL section_vals_val_get(mixer_section, "MIN_WEIGHT", r_val=min_weight)
1881 CALL section_vals_val_get(mixer_section, "MAX_WEIGHT", r_val=max_weight)
1882 CALL section_vals_val_get(mixer_section, "WEIGHT_FACTOR", r_val=weight_factor)
1883
1884 IF (iterations < 1) cpabort(trim(section_name)//"/ITERATIONS must be positive")
1885 IF (memory < 1) cpabort(trim(section_name)//"/MEMORY must be positive")
1886 SELECT CASE (solver)
1887 CASE (tblite_solver_gvd, tblite_solver_gvr)
1888 CASE DEFAULT
1889 cpabort(trim(section_name)//"/SOLVER must be GVD or GVR")
1890 END SELECT
1891 IF (damping <= 0.0_dp) cpabort(trim(section_name)//"/DAMPING must be positive")
1892 IF (omega0 <= 0.0_dp) cpabort(trim(section_name)//"/OMEGA0 must be positive")
1893 IF (min_weight <= 0.0_dp) cpabort(trim(section_name)//"/MIN_WEIGHT must be positive")
1894 IF (max_weight <= 0.0_dp) cpabort(trim(section_name)//"/MAX_WEIGHT must be positive")
1895 IF (max_weight < min_weight) &
1896 cpabort(trim(section_name)//"/MAX_WEIGHT must not be smaller than MIN_WEIGHT")
1897 IF (weight_factor <= 0.0_dp) cpabort(trim(section_name)//"/WEIGHT_FACTOR must be positive")
1898
1899 END SUBROUTINE read_tblite_mixer_section
1900
1901! **************************************************************************************************
1902!> \brief Read native tblite CLI reference options.
1903!> \param ref_cli_section input section
1904!> \param ref_cli reference CLI control data
1905!> \param cell optional cell used to transform Cartesian input vectors
1906! **************************************************************************************************
1907 SUBROUTINE read_xtb_reference_cli_section(ref_cli_section, ref_cli, cell)
1908 TYPE(section_vals_type), POINTER :: ref_cli_section
1909 TYPE(xtb_reference_cli_type), INTENT(INOUT) :: ref_cli
1910 TYPE(cell_type), OPTIONAL, POINTER :: cell
1911
1912 REAL(kind=dp), DIMENSION(:), POINTER :: efield
1913 TYPE(section_vals_type), POINTER :: fit_section, guess_section, &
1914 param_section, solvation_section, &
1915 tagdiff_section
1916
1917 CALL section_vals_val_get(ref_cli_section, "_SECTION_PARAMETERS_", l_val=ref_cli%enabled)
1918 CALL section_vals_val_get(ref_cli_section, "PROGRAM_NAME", c_val=ref_cli%program_name)
1919 CALL section_vals_val_get(ref_cli_section, "GUESS", i_val=ref_cli%guess)
1920 CALL section_vals_val_get(ref_cli_section, "WORK_DIRECTORY", c_val=ref_cli%work_directory)
1921 CALL section_vals_val_get(ref_cli_section, "PREFIX", c_val=ref_cli%prefix)
1922 CALL section_vals_val_get(ref_cli_section, "INPUT_FORMAT", c_val=ref_cli%input_format)
1923 CALL section_vals_val_get(ref_cli_section, "RESTART", c_val=ref_cli%restart_file)
1924 CALL section_vals_val_get(ref_cli_section, "GRAD", c_val=ref_cli%grad_file)
1925 CALL section_vals_val_get(ref_cli_section, "JSON", c_val=ref_cli%json_file)
1926 CALL section_vals_val_get(ref_cli_section, "POST_PROCESSING", c_val=ref_cli%post_processing)
1927 CALL section_vals_val_get(ref_cli_section, "POST_PROCESSING_OUTPUT", &
1928 c_val=ref_cli%post_processing_output_file)
1929 CALL section_vals_val_get(ref_cli_section, "EFIELD", explicit=ref_cli%efield_active)
1930 IF (ref_cli%efield_active) THEN
1931 NULLIFY (efield)
1932 CALL section_vals_val_get(ref_cli_section, "EFIELD", r_vals=efield)
1933 ref_cli%efield = efield(1:3)
1934 IF (PRESENT(cell)) THEN
1935 IF (ASSOCIATED(cell)) CALL cell_transform_input_cartesian(cell, ref_cli%efield)
1936 END IF
1937 END IF
1938 solvation_section => section_vals_get_subs_vals(ref_cli_section, "IMPLICIT_SOLVATION")
1939 CALL section_vals_get(solvation_section, explicit=ref_cli%solvation_active)
1940 IF (ref_cli%solvation_active) THEN
1941 CALL section_vals_val_get(solvation_section, "MODEL", i_val=ref_cli%solvation_model)
1942 CALL section_vals_val_get(solvation_section, "SOLVENT", c_val=ref_cli%solvation_solvent)
1943 CALL section_vals_val_get(solvation_section, "BORN_KERNEL", i_val=ref_cli%solvation_born_kernel)
1944 CALL section_vals_val_get(solvation_section, "SOLUTION_STATE", i_val=ref_cli%solvation_state)
1945 IF (len_trim(ref_cli%solvation_solvent) == 0) &
1946 cpabort("REFERENCE_CLI implicit solvation needs SOLVENT")
1947 IF (ref_cli%solvation_model == tblite_cli_solvation_cpcm .AND. &
1948 ref_cli%solvation_born_kernel /= tblite_cli_born_kernel_auto) &
1949 cpabort("BORN_KERNEL is invalid with MODEL CPCM")
1950 IF (ref_cli%solvation_state /= tblite_cli_solution_state_gsolv) THEN
1951 SELECT CASE (ref_cli%solvation_model)
1952 CASE (tblite_cli_solvation_alpb, tblite_cli_solvation_gbsa)
1953 ! Native tblite supports solution-state shifts for parametrized named-solvent ALPB/GBSA.
1954 CASE (tblite_cli_solvation_gbe, tblite_cli_solvation_gb, tblite_cli_solvation_cpcm)
1955 cpabort("SOLUTION_STATE is valid only for ALPB/GBSA")
1956 END SELECT
1957 END IF
1958 END IF
1959 CALL section_vals_val_get(ref_cli_section, "ELECTRONIC_TEMPERATURE_GUESS", &
1960 r_val=ref_cli%electronic_temperature_guess)
1961 IF (ref_cli%electronic_temperature_guess < 0.0_dp) &
1962 cpabort("XTB/TBLITE/REFERENCE_CLI/ELECTRONIC_TEMPERATURE_GUESS must not be negative")
1963 IF (ref_cli%electronic_temperature_guess > 0.0_dp .AND. ref_cli%guess /= tblite_guess_ceh) &
1964 cpabort("XTB/TBLITE/REFERENCE_CLI/ELECTRONIC_TEMPERATURE_GUESS requires GUESS CEH")
1965 guess_section => section_vals_get_subs_vals(ref_cli_section, "GUESS_CLI")
1966 CALL section_vals_get(guess_section, explicit=ref_cli%guess_cli%enabled)
1967 IF (ref_cli%guess_cli%enabled) THEN
1968 CALL section_vals_val_get(guess_section, "METHOD", i_val=ref_cli%guess_cli%method)
1969 CALL section_vals_val_get(guess_section, "ELECTRONIC_TEMPERATURE_GUESS", &
1970 r_val=ref_cli%guess_cli%electronic_temperature_guess)
1971 IF (ref_cli%guess_cli%electronic_temperature_guess < 0.0_dp) &
1972 cpabort("REFERENCE_CLI/GUESS_CLI/ELECTRONIC_TEMPERATURE_GUESS must not be negative")
1973 CALL section_vals_val_get(guess_section, "SOLVER", i_val=ref_cli%guess_cli%solver)
1974 CALL section_vals_val_get(guess_section, "EFIELD", explicit=ref_cli%guess_cli%efield_active)
1975 IF (ref_cli%guess_cli%efield_active) THEN
1976 NULLIFY (efield)
1977 CALL section_vals_val_get(guess_section, "EFIELD", r_vals=efield)
1978 ref_cli%guess_cli%efield = efield(1:3)
1979 IF (PRESENT(cell)) THEN
1980 IF (ASSOCIATED(cell)) CALL cell_transform_input_cartesian(cell, ref_cli%guess_cli%efield)
1981 END IF
1982 END IF
1983 CALL section_vals_val_get(guess_section, "GRAD", l_val=ref_cli%guess_cli%grad)
1984 CALL section_vals_val_get(guess_section, "JSON", c_val=ref_cli%guess_cli%json_file)
1985 CALL section_vals_val_get(guess_section, "INPUT_FORMAT", c_val=ref_cli%guess_cli%input_format)
1986 CALL section_vals_val_get(guess_section, "INPUT_FILE", c_val=ref_cli%guess_cli%input_file)
1987 END IF
1988 param_section => section_vals_get_subs_vals(ref_cli_section, "PARAM_CLI")
1989 CALL section_vals_get(param_section, explicit=ref_cli%param_cli%enabled)
1990 IF (ref_cli%param_cli%enabled) THEN
1991 CALL section_vals_val_get(param_section, "METHOD", explicit=ref_cli%param_cli%method_explicit, &
1992 i_val=ref_cli%param_cli%method)
1993 CALL section_vals_val_get(param_section, "OUTPUT", c_val=ref_cli%param_cli%output_file)
1994 CALL section_vals_val_get(param_section, "INPUT_FILE", c_val=ref_cli%param_cli%input_file)
1995 END IF
1996 fit_section => section_vals_get_subs_vals(ref_cli_section, "FIT_CLI")
1997 CALL section_vals_get(fit_section, explicit=ref_cli%fit_cli%enabled)
1998 IF (ref_cli%fit_cli%enabled) THEN
1999 CALL section_vals_val_get(fit_section, "PARAM_FILE", c_val=ref_cli%fit_cli%param_file)
2000 CALL section_vals_val_get(fit_section, "INPUT_FILE", c_val=ref_cli%fit_cli%input_file)
2001 CALL section_vals_val_get(fit_section, "DRY_RUN", l_val=ref_cli%fit_cli%dry_run)
2002 CALL section_vals_val_get(fit_section, "COPY", c_val=ref_cli%fit_cli%copy_file)
2003 IF (len_trim(ref_cli%fit_cli%param_file) == 0) &
2004 cpabort("XTB/TBLITE/REFERENCE_CLI/FIT_CLI needs PARAM_FILE")
2005 IF (len_trim(ref_cli%fit_cli%input_file) == 0) &
2006 cpabort("XTB/TBLITE/REFERENCE_CLI/FIT_CLI needs INPUT_FILE")
2007 END IF
2008 tagdiff_section => section_vals_get_subs_vals(ref_cli_section, "TAGDIFF_CLI")
2009 CALL section_vals_get(tagdiff_section, explicit=ref_cli%tagdiff_cli%enabled)
2010 IF (ref_cli%tagdiff_cli%enabled) THEN
2011 CALL section_vals_val_get(tagdiff_section, "ACTUAL", c_val=ref_cli%tagdiff_cli%actual_file)
2012 CALL section_vals_val_get(tagdiff_section, "REFERENCE", c_val=ref_cli%tagdiff_cli%reference_file)
2013 CALL section_vals_val_get(tagdiff_section, "FIT", l_val=ref_cli%tagdiff_cli%fit)
2014 IF (len_trim(ref_cli%tagdiff_cli%actual_file) == 0) &
2015 cpabort("XTB/TBLITE/REFERENCE_CLI/TAGDIFF_CLI needs ACTUAL")
2016 IF (len_trim(ref_cli%tagdiff_cli%reference_file) == 0) &
2017 cpabort("XTB/TBLITE/REFERENCE_CLI/TAGDIFF_CLI needs REFERENCE")
2018 END IF
2019 CALL section_vals_val_get(ref_cli_section, "KEEP_FILES", l_val=ref_cli%keep_files)
2020 CALL section_vals_val_get(ref_cli_section, "ERROR_LIMIT", r_val=ref_cli%error_limit)
2021 CALL section_vals_val_get(ref_cli_section, "STOP_ON_ERROR", l_val=ref_cli%stop_on_error)
2022 CALL section_vals_val_get(ref_cli_section, "CHECK_ENERGY", l_val=ref_cli%check_energy)
2023 CALL section_vals_val_get(ref_cli_section, "CHECK_FORCES", l_val=ref_cli%check_forces)
2024 CALL section_vals_val_get(ref_cli_section, "CHECK_VIRIAL", l_val=ref_cli%check_virial)
2025
2026 END SUBROUTINE read_xtb_reference_cli_section
2027
2028! **************************************************************************************************
2029!> \brief Read TDDFPT-related input parameters.
2030!> \param t_control TDDFPT control parameters
2031!> \param t_section TDDFPT input section
2032!> \param qs_control Quickstep control parameters
2033! **************************************************************************************************
2034 SUBROUTINE read_tddfpt2_control(t_control, t_section, qs_control)
2035 TYPE(tddfpt2_control_type), POINTER :: t_control
2036 TYPE(section_vals_type), POINTER :: t_section
2037 TYPE(qs_control_type), POINTER :: qs_control
2038
2039 CHARACTER(LEN=*), PARAMETER :: routinen = 'read_tddfpt2_control'
2040
2041 CHARACTER(LEN=default_string_length), &
2042 DIMENSION(:), POINTER :: tmpstringlist
2043 INTEGER :: handle, irep, isize, nrep
2044 INTEGER, ALLOCATABLE, DIMENSION(:) :: inds
2045 LOGICAL :: do_ewald, do_exchange, expl, explicit, &
2046 multigrid_set
2047 REAL(kind=dp) :: filter, fval, hfx
2048 TYPE(section_vals_type), POINTER :: dipole_section, mgrid_section, &
2049 soc_section, stda_section, xc_func, &
2050 xc_section
2051
2052 CALL timeset(routinen, handle)
2053
2054 CALL section_vals_val_get(t_section, "_SECTION_PARAMETERS_", l_val=t_control%enabled)
2055
2056 CALL section_vals_val_get(t_section, "NSTATES", i_val=t_control%nstates)
2057 CALL section_vals_val_get(t_section, "MAX_ITER", i_val=t_control%niters)
2058 CALL section_vals_val_get(t_section, "MAX_KV", i_val=t_control%nkvs)
2059 CALL section_vals_val_get(t_section, "NLUMO", i_val=t_control%nlumo)
2060 CALL section_vals_val_get(t_section, "NPROC_STATE", i_val=t_control%nprocs)
2061 CALL section_vals_val_get(t_section, "KERNEL", i_val=t_control%kernel)
2062 CALL section_vals_val_get(t_section, "SPINFLIP", i_val=t_control%spinflip)
2063 CALL section_vals_val_get(t_section, "OE_CORR", i_val=t_control%oe_corr)
2064 CALL section_vals_val_get(t_section, "EV_SHIFT", r_val=t_control%ev_shift)
2065 CALL section_vals_val_get(t_section, "EOS_SHIFT", r_val=t_control%eos_shift)
2066
2067 CALL section_vals_val_get(t_section, "CONVERGENCE", r_val=t_control%conv)
2068 CALL section_vals_val_get(t_section, "MIN_AMPLITUDE", r_val=t_control%min_excitation_amplitude)
2069 CALL section_vals_val_get(t_section, "ORTHOGONAL_EPS", r_val=t_control%orthogonal_eps)
2070
2071 CALL section_vals_val_get(t_section, "RESTART", l_val=t_control%is_restart)
2072 CALL section_vals_val_get(t_section, "RKS_TRIPLETS", l_val=t_control%rks_triplets)
2073 CALL section_vals_val_get(t_section, "DO_LRIGPW", l_val=t_control%do_lrigpw)
2074 CALL section_vals_val_get(t_section, "DO_SMEARING", l_val=t_control%do_smearing)
2075 CALL section_vals_val_get(t_section, "DO_BSE", l_val=t_control%do_bse)
2076 CALL section_vals_val_get(t_section, "DO_BSE_W_ONLY", l_val=t_control%do_bse_w_only)
2077 CALL section_vals_val_get(t_section, "DO_BSE_GW_ONLY", l_val=t_control%do_bse_gw_only)
2078 CALL section_vals_val_get(t_section, "ADMM_KERNEL_CORRECTION_SYMMETRIC", l_val=t_control%admm_symm)
2079 CALL section_vals_val_get(t_section, "ADMM_KERNEL_XC_CORRECTION", l_val=t_control%admm_xc_correction)
2080 CALL section_vals_val_get(t_section, "EXCITON_DESCRIPTORS", l_val=t_control%do_exciton_descriptors)
2081 CALL section_vals_val_get(t_section, "DIRECTIONAL_EXCITON_DESCRIPTORS", l_val=t_control%do_directional_exciton_descriptors)
2082
2083 ! read automatically generated auxiliary basis for LRI
2084 CALL section_vals_val_get(t_section, "AUTO_BASIS", n_rep_val=nrep)
2085 DO irep = 1, nrep
2086 CALL section_vals_val_get(t_section, "AUTO_BASIS", i_rep_val=irep, c_vals=tmpstringlist)
2087 IF (SIZE(tmpstringlist) == 2) THEN
2088 CALL uppercase(tmpstringlist(2))
2089 SELECT CASE (tmpstringlist(2))
2090 CASE ("X")
2091 isize = -1
2092 CASE ("SMALL")
2093 isize = 0
2094 CASE ("MEDIUM")
2095 isize = 1
2096 CASE ("LARGE")
2097 isize = 2
2098 CASE ("HUGE")
2099 isize = 3
2100 CASE DEFAULT
2101 cpabort("Unknown basis size in AUTO_BASIS keyword:"//trim(tmpstringlist(1)))
2102 END SELECT
2103 !
2104 SELECT CASE (tmpstringlist(1))
2105 CASE ("X")
2106 CASE ("P_LRI_AUX")
2107 t_control%auto_basis_p_lri_aux = isize
2108 CASE DEFAULT
2109 cpabort("Unknown basis type in AUTO_BASIS keyword:"//trim(tmpstringlist(1)))
2110 END SELECT
2111 ELSE
2112 CALL cp_abort(__location__, &
2113 "AUTO_BASIS keyword in &PROPERTIES &TDDFT section has a wrong number of arguments.")
2114 END IF
2115 END DO
2116
2117 IF (t_control%conv < 0) &
2118 t_control%conv = abs(t_control%conv)
2119
2120 ! DIPOLE_MOMENTS subsection
2121 dipole_section => section_vals_get_subs_vals(t_section, "DIPOLE_MOMENTS")
2122 CALL section_vals_val_get(dipole_section, "DIPOLE_FORM", explicit=explicit)
2123 IF (explicit) THEN
2124 CALL section_vals_val_get(dipole_section, "DIPOLE_FORM", i_val=t_control%dipole_form)
2125 ELSE
2126 t_control%dipole_form = 0
2127 END IF
2128 CALL section_vals_val_get(dipole_section, "REFERENCE", i_val=t_control%dipole_reference)
2129 CALL section_vals_val_get(dipole_section, "REFERENCE_POINT", explicit=explicit)
2130 IF (explicit) THEN
2131 CALL section_vals_val_get(dipole_section, "REFERENCE_POINT", r_vals=t_control%dipole_ref_point)
2132 ELSE
2133 NULLIFY (t_control%dipole_ref_point)
2134 IF (t_control%dipole_form == tddfpt_dipole_length .AND. t_control%dipole_reference == use_mom_ref_user) THEN
2135 cpabort("User-defined reference point should be given explicitly")
2136 END IF
2137 END IF
2138
2139 !SOC subsection
2140 soc_section => section_vals_get_subs_vals(t_section, "SOC")
2141 CALL section_vals_get(soc_section, explicit=explicit)
2142 IF (explicit) THEN
2143 t_control%do_soc = .true.
2144 END IF
2145
2146 ! MGRID subsection
2147 mgrid_section => section_vals_get_subs_vals(t_section, "MGRID")
2148 CALL section_vals_get(mgrid_section, explicit=t_control%mgrid_is_explicit)
2149
2150 IF (t_control%mgrid_is_explicit) THEN
2151 CALL section_vals_val_get(mgrid_section, "NGRIDS", i_val=t_control%mgrid_ngrids, explicit=explicit)
2152 IF (.NOT. explicit) t_control%mgrid_ngrids = SIZE(qs_control%e_cutoff)
2153
2154 CALL section_vals_val_get(mgrid_section, "CUTOFF", r_val=t_control%mgrid_cutoff, explicit=explicit)
2155 IF (.NOT. explicit) t_control%mgrid_cutoff = qs_control%cutoff
2156
2157 CALL section_vals_val_get(mgrid_section, "PROGRESSION_FACTOR", &
2158 r_val=t_control%mgrid_progression_factor, explicit=explicit)
2159 IF (explicit) THEN
2160 IF (t_control%mgrid_progression_factor <= 1.0_dp) &
2161 CALL cp_abort(__location__, &
2162 "Progression factor should be greater then 1.0 to ensure multi-grid ordering")
2163 ELSE
2164 t_control%mgrid_progression_factor = qs_control%progression_factor
2165 END IF
2166
2167 CALL section_vals_val_get(mgrid_section, "COMMENSURATE", l_val=t_control%mgrid_commensurate_mgrids, explicit=explicit)
2168 IF (.NOT. explicit) t_control%mgrid_commensurate_mgrids = qs_control%commensurate_mgrids
2169 IF (t_control%mgrid_commensurate_mgrids) THEN
2170 IF (explicit) THEN
2171 t_control%mgrid_progression_factor = 4.0_dp
2172 ELSE
2173 t_control%mgrid_progression_factor = qs_control%progression_factor
2174 END IF
2175 END IF
2176
2177 CALL section_vals_val_get(mgrid_section, "REL_CUTOFF", r_val=t_control%mgrid_relative_cutoff, explicit=explicit)
2178 IF (.NOT. explicit) t_control%mgrid_relative_cutoff = qs_control%relative_cutoff
2179
2180 CALL section_vals_val_get(mgrid_section, "MULTIGRID_SET", l_val=multigrid_set, explicit=explicit)
2181 IF (.NOT. explicit) multigrid_set = .false.
2182 IF (multigrid_set) THEN
2183 CALL section_vals_val_get(mgrid_section, "MULTIGRID_CUTOFF", r_vals=t_control%mgrid_e_cutoff)
2184 ELSE
2185 NULLIFY (t_control%mgrid_e_cutoff)
2186 END IF
2187
2188 CALL section_vals_val_get(mgrid_section, "REALSPACE", l_val=t_control%mgrid_realspace_mgrids, explicit=explicit)
2189 IF (.NOT. explicit) t_control%mgrid_realspace_mgrids = qs_control%realspace_mgrids
2190
2191 CALL section_vals_val_get(mgrid_section, "SKIP_LOAD_BALANCE_DISTRIBUTED", &
2192 l_val=t_control%mgrid_skip_load_balance, explicit=explicit)
2193 IF (.NOT. explicit) t_control%mgrid_skip_load_balance = qs_control%skip_load_balance_distributed
2194
2195 IF (ASSOCIATED(t_control%mgrid_e_cutoff)) THEN
2196 IF (SIZE(t_control%mgrid_e_cutoff) /= t_control%mgrid_ngrids) &
2197 cpabort("Inconsistent values for number of multi-grids")
2198
2199 ! sort multi-grids in descending order according to their cutoff values
2200 t_control%mgrid_e_cutoff = -t_control%mgrid_e_cutoff
2201 ALLOCATE (inds(t_control%mgrid_ngrids))
2202 CALL sort(t_control%mgrid_e_cutoff, t_control%mgrid_ngrids, inds)
2203 DEALLOCATE (inds)
2204 t_control%mgrid_e_cutoff = -t_control%mgrid_e_cutoff
2205 END IF
2206 END IF
2207
2208 ! expand XC subsection (if given explicitly)
2209 xc_section => section_vals_get_subs_vals(t_section, "XC")
2210 xc_func => section_vals_get_subs_vals(xc_section, "XC_FUNCTIONAL")
2211 CALL section_vals_get(xc_func, explicit=explicit)
2212 IF (explicit) &
2213 CALL xc_functionals_expand(xc_func, xc_section)
2214
2215 ! sTDA subsection
2216 stda_section => section_vals_get_subs_vals(t_section, "STDA")
2217 IF (t_control%kernel == tddfpt_kernel_stda) THEN
2218 t_control%stda_control%hfx_fraction = 0.0_dp
2219 t_control%stda_control%do_exchange = .true.
2220 t_control%stda_control%eps_td_filter = 1.e-10_dp
2221 t_control%stda_control%mn_alpha = -99.0_dp
2222 t_control%stda_control%mn_beta = -99.0_dp
2223 ! set default for Ewald method (on/off) dependent on periodicity
2224 SELECT CASE (qs_control%periodicity)
2225 CASE (0)
2226 t_control%stda_control%do_ewald = .false.
2227 CASE (1)
2228 t_control%stda_control%do_ewald = .true.
2229 CASE (2)
2230 t_control%stda_control%do_ewald = .true.
2231 CASE (3)
2232 t_control%stda_control%do_ewald = .true.
2233 CASE DEFAULT
2234 cpabort("Illegal value for periodiciy")
2235 END SELECT
2236 CALL section_vals_get(stda_section, explicit=explicit)
2237 IF (explicit) THEN
2238 CALL section_vals_val_get(stda_section, "HFX_FRACTION", r_val=hfx, explicit=expl)
2239 IF (expl) t_control%stda_control%hfx_fraction = hfx
2240 CALL section_vals_val_get(stda_section, "EPS_TD_FILTER", r_val=filter, explicit=expl)
2241 IF (expl) t_control%stda_control%eps_td_filter = filter
2242 CALL section_vals_val_get(stda_section, "DO_EWALD", l_val=do_ewald, explicit=expl)
2243 IF (expl) t_control%stda_control%do_ewald = do_ewald
2244 CALL section_vals_val_get(stda_section, "DO_EXCHANGE", l_val=do_exchange, explicit=expl)
2245 IF (expl) t_control%stda_control%do_exchange = do_exchange
2246 CALL section_vals_val_get(stda_section, "MATAGA_NISHIMOTO_CEXP", r_val=fval)
2247 t_control%stda_control%mn_alpha = fval
2248 CALL section_vals_val_get(stda_section, "MATAGA_NISHIMOTO_XEXP", r_val=fval)
2249 t_control%stda_control%mn_beta = fval
2250 END IF
2251 CALL section_vals_val_get(stda_section, "COULOMB_SR_CUT", r_val=fval)
2252 t_control%stda_control%coulomb_sr_cut = fval
2253 CALL section_vals_val_get(stda_section, "COULOMB_SR_EPS", r_val=fval)
2254 t_control%stda_control%coulomb_sr_eps = fval
2255 END IF
2256
2257 CALL timestop(handle)
2258 END SUBROUTINE read_tddfpt2_control
2259
2260! **************************************************************************************************
2261!> \brief Write the DFT control parameters to the output unit.
2262!> \param dft_control ...
2263!> \param dft_section ...
2264! **************************************************************************************************
2265 SUBROUTINE write_dft_control(dft_control, dft_section)
2266 TYPE(dft_control_type), POINTER :: dft_control
2267 TYPE(section_vals_type), POINTER :: dft_section
2268
2269 CHARACTER(len=*), PARAMETER :: routinen = 'write_dft_control'
2270
2271 CHARACTER(LEN=20) :: tmpstr
2272 INTEGER :: handle, i, i_rep, n_rep, output_unit
2273 REAL(kind=dp) :: density_cut, density_smooth_cut_range, &
2274 gradient_cut, tau_cut
2275 TYPE(cp_logger_type), POINTER :: logger
2276 TYPE(enumeration_type), POINTER :: enum
2277 TYPE(keyword_type), POINTER :: keyword
2278 TYPE(section_type), POINTER :: section
2279 TYPE(section_vals_type), POINTER :: xc_section
2280
2281 IF (dft_control%qs_control%semi_empirical) RETURN
2282 IF (dft_control%qs_control%dftb) RETURN
2283 IF (dft_control%qs_control%xtb) THEN
2284 CALL write_xtb_control(dft_control%qs_control%xtb_control, dft_section)
2285 RETURN
2286 END IF
2287 CALL timeset(routinen, handle)
2288
2289 NULLIFY (logger)
2290 logger => cp_get_default_logger()
2291
2292 output_unit = cp_print_key_unit_nr(logger, dft_section, &
2293 "PRINT%DFT_CONTROL_PARAMETERS", extension=".Log")
2294
2295 IF (output_unit > 0) THEN
2296
2297 xc_section => section_vals_get_subs_vals(dft_section, "XC")
2298
2299 IF (dft_control%uks) THEN
2300 WRITE (unit=output_unit, fmt="(/,T2,A,T78,A)") &
2301 "DFT| Spin unrestricted (spin-polarized) Kohn-Sham calculation", "UKS"
2302 ELSE IF (dft_control%roks) THEN
2303 WRITE (unit=output_unit, fmt="(/,T2,A,T77,A)") &
2304 "DFT| Spin restricted open Kohn-Sham calculation", "ROKS"
2305 ELSE
2306 WRITE (unit=output_unit, fmt="(/,T2,A,T78,A)") &
2307 "DFT| Spin restricted Kohn-Sham (RKS) calculation", "RKS"
2308 END IF
2309
2310 WRITE (unit=output_unit, fmt="(T2,A,T76,I5)") &
2311 "DFT| Multiplicity", dft_control%multiplicity
2312 WRITE (unit=output_unit, fmt="(T2,A,T76,I5)") &
2313 "DFT| Number of spin states", dft_control%nspins
2314
2315 WRITE (unit=output_unit, fmt="(T2,A,T76,I5)") &
2316 "DFT| Charge", dft_control%charge
2317
2318 IF (dft_control%sic_method_id /= sic_none) CALL cite_reference(vandevondele2005b)
2319 SELECT CASE (dft_control%sic_method_id)
2320 CASE (sic_none)
2321 tmpstr = "NO"
2322 CASE (sic_mauri_spz)
2323 tmpstr = "SPZ/MAURI SIC"
2324 CASE (sic_mauri_us)
2325 tmpstr = "US/MAURI SIC"
2326 CASE (sic_ad)
2327 tmpstr = "AD SIC"
2328 CASE (sic_eo)
2329 tmpstr = "Explicit Orbital SIC"
2330 CASE DEFAULT
2331 ! fix throughout the cp2k for this option
2332 cpabort("SIC option unknown")
2333 END SELECT
2334
2335 WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &
2336 "DFT| Self-interaction correction (SIC)", adjustr(trim(tmpstr))
2337
2338 IF (dft_control%sic_method_id /= sic_none) THEN
2339 WRITE (unit=output_unit, fmt="(T2,A,T66,ES15.6)") &
2340 "DFT| SIC scaling parameter a", dft_control%sic_scaling_a, &
2341 "DFT| SIC scaling parameter b", dft_control%sic_scaling_b
2342 END IF
2343
2344 IF (dft_control%sic_method_id == sic_eo) THEN
2345 IF (dft_control%sic_list_id == sic_list_all) THEN
2346 WRITE (unit=output_unit, fmt="(T2,A,T66,A)") &
2347 "DFT| SIC orbitals", "ALL"
2348 END IF
2349 IF (dft_control%sic_list_id == sic_list_unpaired) THEN
2350 WRITE (unit=output_unit, fmt="(T2,A,T66,A)") &
2351 "DFT| SIC orbitals", "UNPAIRED"
2352 END IF
2353 END IF
2354
2355 CALL section_vals_val_get(xc_section, "density_cutoff", r_val=density_cut)
2356 CALL section_vals_val_get(xc_section, "gradient_cutoff", r_val=gradient_cut)
2357 CALL section_vals_val_get(xc_section, "tau_cutoff", r_val=tau_cut)
2358 CALL section_vals_val_get(xc_section, "density_smooth_cutoff_range", r_val=density_smooth_cut_range)
2359
2360 WRITE (unit=output_unit, fmt="(T2,A,T66,ES15.6)") &
2361 "DFT| Cutoffs: density ", density_cut, &
2362 "DFT| gradient", gradient_cut, &
2363 "DFT| tau ", tau_cut, &
2364 "DFT| cutoff_smoothing_range", density_smooth_cut_range
2365 CALL section_vals_val_get(xc_section, "XC_GRID%XC_SMOOTH_RHO", &
2366 c_val=tmpstr)
2367 WRITE (output_unit, '( A, T61, A )') &
2368 " DFT| XC density smoothing ", adjustr(tmpstr)
2369 CALL section_vals_val_get(xc_section, "XC_GRID%XC_DERIV", &
2370 c_val=tmpstr)
2371 WRITE (output_unit, '( A, T61, A )') &
2372 " DFT| XC derivatives ", adjustr(tmpstr)
2373 IF (dft_control%dft_plus_u) THEN
2374 NULLIFY (enum, keyword, section)
2375 CALL create_dft_section(section)
2376 keyword => section_get_keyword(section, "PLUS_U_METHOD")
2377 CALL keyword_get(keyword, enum=enum)
2378 WRITE (unit=output_unit, fmt="(/,T2,A,T41,A40)") &
2379 "DFT+U| Method", adjustr(trim(enum_i2c(enum, dft_control%plus_u_method_id)))
2380 WRITE (unit=output_unit, fmt="(T2,A)") &
2381 "DFT+U| Check atomic kind information for details"
2382 CALL section_release(section)
2383 END IF
2384
2385 WRITE (unit=output_unit, fmt="(A)") ""
2386 CALL xc_write(output_unit, xc_section, dft_control%lsd)
2387
2388 IF (dft_control%apply_period_efield) THEN
2389 WRITE (unit=output_unit, fmt="(A)") ""
2390 IF (dft_control%period_efield%displacement_field) THEN
2391 WRITE (unit=output_unit, fmt="(T2,A)") &
2392 "PERIODIC_EFIELD| Use displacement field formulation"
2393 WRITE (unit=output_unit, fmt="(T2,A,T66,1X,ES14.6)") &
2394 "PERIODIC_EFIELD| Displacement field filter: x", &
2395 dft_control%period_efield%d_filter(1), &
2396 "PERIODIC_EFIELD| y", &
2397 dft_control%period_efield%d_filter(2), &
2398 "PERIODIC_EFIELD| z", &
2399 dft_control%period_efield%d_filter(3)
2400 END IF
2401 WRITE (unit=output_unit, fmt="(T2,A,T66,1X,ES14.6)") &
2402 "PERIODIC_EFIELD| Polarisation vector: x", &
2403 dft_control%period_efield%polarisation(1), &
2404 "PERIODIC_EFIELD| y", &
2405 dft_control%period_efield%polarisation(2), &
2406 "PERIODIC_EFIELD| z", &
2407 dft_control%period_efield%polarisation(3)
2408
2409 WRITE (unit=output_unit, fmt="(T2,A,T66,1X,I14)") &
2410 "PERIODIC_EFIELD| Start Frame:", &
2411 dft_control%period_efield%start_frame, &
2412 "PERIODIC_EFIELD| End Frame:", &
2413 dft_control%period_efield%end_frame
2414
2415 IF (ALLOCATED(dft_control%period_efield%strength_list)) THEN
2416 WRITE (unit=output_unit, fmt="(T2,A,T66,1X,I14)") &
2417 "PERIODIC_EFIELD| Number of Intensities:", &
2418 SIZE(dft_control%period_efield%strength_list)
2419 WRITE (unit=output_unit, fmt="(T2,A,I10,T66,1X,ES14.6)") &
2420 "PERIODIC_EFIELD| Intensity List [a.u.] ", &
2421 1, dft_control%period_efield%strength_list(1)
2422 DO i = 2, SIZE(dft_control%period_efield%strength_list)
2423 WRITE (unit=output_unit, fmt="(T2,A,I10,T66,1X,ES14.6)") &
2424 "PERIODIC_EFIELD| ", &
2425 i, dft_control%period_efield%strength_list(i)
2426 END DO
2427 ELSE
2428 WRITE (unit=output_unit, fmt="(T2,A,T66,1X,ES14.6)") &
2429 "PERIODIC_EFIELD| Intensity [a.u.]:", &
2430 dft_control%period_efield%strength
2431 END IF
2432
2433 IF (sqrt(dot_product(dft_control%period_efield%polarisation, &
2434 dft_control%period_efield%polarisation)) < epsilon(0.0_dp)) THEN
2435 cpabort("Invalid (too small) polarisation vector specified for PERIODIC_EFIELD")
2436 END IF
2437 END IF
2438
2439 IF (dft_control%do_sccs) THEN
2440 WRITE (unit=output_unit, fmt="(/,T2,A)") &
2441 "SCCS| Self-consistent continuum solvation model"
2442 WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &
2443 "SCCS| Relative permittivity of the solvent (medium)", &
2444 dft_control%sccs_control%epsilon_solvent, &
2445 "SCCS| Absolute permittivity [a.u.]", &
2446 dft_control%sccs_control%epsilon_solvent/fourpi
2447 SELECT CASE (dft_control%sccs_control%method_id)
2448 CASE (sccs_andreussi)
2449 WRITE (unit=output_unit, fmt="(T2,A,/,(T2,A,T61,ES20.6))") &
2450 "SCCS| Dielectric function proposed by Andreussi et al.", &
2451 "SCCS| rho_max", dft_control%sccs_control%rho_max, &
2452 "SCCS| rho_min", dft_control%sccs_control%rho_min
2453 CASE (sccs_fattebert_gygi)
2454 WRITE (unit=output_unit, fmt="(T2,A,/,(T2,A,T61,ES20.6))") &
2455 "SCCS| Dielectric function proposed by Fattebert and Gygi", &
2456 "SCCS| beta", dft_control%sccs_control%beta, &
2457 "SCCS| rho_zero", dft_control%sccs_control%rho_zero
2458 CASE DEFAULT
2459 cpabort("Invalid SCCS model specified. Please, check your input!")
2460 END SELECT
2461 SELECT CASE (dft_control%sccs_control%derivative_method)
2462 CASE (sccs_derivative_fft)
2463 WRITE (unit=output_unit, fmt="(T2,A,T46,A35)") &
2464 "SCCS| Numerical derivative calculation", &
2465 adjustr("FFT")
2466 CASE (sccs_derivative_cd3)
2467 WRITE (unit=output_unit, fmt="(T2,A,T46,A35)") &
2468 "SCCS| Numerical derivative calculation", &
2469 adjustr("3-point stencil central differences")
2470 CASE (sccs_derivative_cd5)
2471 WRITE (unit=output_unit, fmt="(T2,A,T46,A35)") &
2472 "SCCS| Numerical derivative calculation", &
2473 adjustr("5-point stencil central differences")
2474 CASE (sccs_derivative_cd7)
2475 WRITE (unit=output_unit, fmt="(T2,A,T46,A35)") &
2476 "SCCS| Numerical derivative calculation", &
2477 adjustr("7-point stencil central differences")
2478 CASE DEFAULT
2479 CALL cp_abort(__location__, &
2480 "Invalid derivative method specified for SCCS model. "// &
2481 "Please, check your input!")
2482 END SELECT
2483 WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &
2484 "SCCS| Repulsion parameter alpha [mN/m] = [dyn/cm]", &
2485 cp_unit_from_cp2k(dft_control%sccs_control%alpha_solvent, "mN/m")
2486 WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &
2487 "SCCS| Dispersion parameter beta [GPa]", &
2488 cp_unit_from_cp2k(dft_control%sccs_control%beta_solvent, "GPa")
2489 WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &
2490 "SCCS| Surface tension gamma [mN/m] = [dyn/cm]", &
2491 cp_unit_from_cp2k(dft_control%sccs_control%gamma_solvent, "mN/m")
2492 WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &
2493 "SCCS| Mixing parameter applied during the iteration cycle", &
2494 dft_control%sccs_control%mixing
2495 WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &
2496 "SCCS| Tolerance for the convergence of the SCCS iteration cycle", &
2497 dft_control%sccs_control%eps_sccs
2498 WRITE (unit=output_unit, fmt="(T2,A,T61,I20)") &
2499 "SCCS| Maximum number of iteration steps", &
2500 dft_control%sccs_control%max_iter
2501 WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &
2502 "SCCS| SCF convergence threshold for starting the SCCS iteration", &
2503 dft_control%sccs_control%eps_scf
2504 WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &
2505 "SCCS| Numerical increment for the cavity surface calculation", &
2506 dft_control%sccs_control%delta_rho
2507 END IF
2508
2509 WRITE (unit=output_unit, fmt="(A)") ""
2510
2511 END IF
2512
2513 IF (dft_control%hairy_probes .EQV. .true.) THEN
2514 n_rep = SIZE(dft_control%probe)
2515 IF (output_unit > 0) THEN
2516 DO i_rep = 1, n_rep
2517 WRITE (unit=output_unit, fmt="(T2,A,I5)") &
2518 "HP | hair probe set", i_rep
2519 WRITE (unit=output_unit, fmt="(T2,A,T61,*(I5))") &
2520 "HP| atom indexes", &
2521 (dft_control%probe(i_rep)%atom_ids(i), i=1, dft_control%probe(i_rep)%natoms)
2522 WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &
2523 "HP| potential", dft_control%probe(i_rep)%mu
2524 WRITE (unit=output_unit, fmt="(T2,A,T61,F20.2)") &
2525 "HP| temperature", dft_control%probe(i_rep)%T
2526 WRITE (unit=output_unit, fmt="(T2,A,T61,ES20.6)") &
2527 "HP| eps_hp", dft_control%probe(i_rep)%eps_hp
2528 END DO
2529 END IF
2530 END IF
2531
2532 CALL cp_print_key_finished_output(output_unit, logger, dft_section, &
2533 "PRINT%DFT_CONTROL_PARAMETERS")
2534
2535 CALL timestop(handle)
2536
2537 END SUBROUTINE write_dft_control
2538
2539! **************************************************************************************************
2540!> \brief Write the ADMM control parameters to the output unit.
2541!> \param admm_control ...
2542!> \param dft_section ...
2543! **************************************************************************************************
2544 SUBROUTINE write_admm_control(admm_control, dft_section)
2545 TYPE(admm_control_type), POINTER :: admm_control
2546 TYPE(section_vals_type), POINTER :: dft_section
2547
2548 INTEGER :: iounit
2549 TYPE(cp_logger_type), POINTER :: logger
2550
2551 NULLIFY (logger)
2552 logger => cp_get_default_logger()
2553
2554 iounit = cp_print_key_unit_nr(logger, dft_section, &
2555 "PRINT%DFT_CONTROL_PARAMETERS", extension=".Log")
2556
2557 IF (iounit > 0) THEN
2558
2559 SELECT CASE (admm_control%admm_type)
2560 CASE (no_admm_type)
2561 WRITE (unit=iounit, fmt="(/,T2,A,T77,A)") "ADMM| Specific ADMM type specified", "NONE"
2562 CASE (admm1_type)
2563 WRITE (unit=iounit, fmt="(/,T2,A,T76,A)") "ADMM| Specific ADMM type specified", "ADMM1"
2564 CASE (admm2_type)
2565 WRITE (unit=iounit, fmt="(/,T2,A,T76,A)") "ADMM| Specific ADMM type specified", "ADMM2"
2566 CASE (admms_type)
2567 WRITE (unit=iounit, fmt="(/,T2,A,T76,A)") "ADMM| Specific ADMM type specified", "ADMMS"
2568 CASE (admmp_type)
2569 WRITE (unit=iounit, fmt="(/,T2,A,T76,A)") "ADMM| Specific ADMM type specified", "ADMMP"
2570 CASE (admmq_type)
2571 WRITE (unit=iounit, fmt="(/,T2,A,T76,A)") "ADMM| Specific ADMM type specified", "ADMMQ"
2572 CASE DEFAULT
2573 cpabort("admm_type")
2574 END SELECT
2575
2576 SELECT CASE (admm_control%purification_method)
2577 CASE (do_admm_purify_none)
2578 WRITE (unit=iounit, fmt="(T2,A,T77,A)") "ADMM| Density matrix purification method", "NONE"
2579 CASE (do_admm_purify_cauchy)
2580 WRITE (unit=iounit, fmt="(T2,A,T75,A)") "ADMM| Density matrix purification method", "Cauchy"
2581 CASE (do_admm_purify_cauchy_subspace)
2582 WRITE (unit=iounit, fmt="(T2,A,T66,A)") "ADMM| Density matrix purification method", "Cauchy subspace"
2583 CASE (do_admm_purify_mo_diag)
2584 WRITE (unit=iounit, fmt="(T2,A,T63,A)") "ADMM| Density matrix purification method", "MO diagonalization"
2585 CASE (do_admm_purify_mo_no_diag)
2586 WRITE (unit=iounit, fmt="(T2,A,T71,A)") "ADMM| Density matrix purification method", "MO no diag"
2587 CASE (do_admm_purify_mcweeny)
2588 WRITE (unit=iounit, fmt="(T2,A,T74,A)") "ADMM| Density matrix purification method", "McWeeny"
2589 CASE (do_admm_purify_none_dm)
2590 WRITE (unit=iounit, fmt="(T2,A,T73,A)") "ADMM| Density matrix purification method", "NONE(DM)"
2591 CASE DEFAULT
2592 cpabort("admm_purification_method")
2593 END SELECT
2594
2595 SELECT CASE (admm_control%method)
2596 CASE (do_admm_basis_projection)
2597 WRITE (unit=iounit, fmt="(T2,A)") "ADMM| Orbital projection on ADMM basis"
2598 CASE (do_admm_blocking_purify_full)
2599 WRITE (unit=iounit, fmt="(T2,A)") "ADMM| Blocked Fock matrix projection with full purification"
2600 CASE (do_admm_blocked_projection)
2601 WRITE (unit=iounit, fmt="(T2,A)") "ADMM| Blocked Fock matrix projection"
2602 CASE (do_admm_charge_constrained_projection)
2603 WRITE (unit=iounit, fmt="(T2,A)") "ADMM| Orbital projection with charge constrain"
2604 CASE DEFAULT
2605 cpabort("admm method")
2606 END SELECT
2607
2608 SELECT CASE (admm_control%scaling_model)
2609 CASE (do_admm_exch_scaling_none)
2610 CASE (do_admm_exch_scaling_merlot)
2611 WRITE (unit=iounit, fmt="(T2,A)") "ADMM| Use Merlot (2014) scaling model"
2612 CASE DEFAULT
2613 cpabort("admm scaling_model")
2614 END SELECT
2615
2616 WRITE (unit=iounit, fmt="(T2,A,T61,G20.10)") "ADMM| eps_filter", admm_control%eps_filter
2617
2618 SELECT CASE (admm_control%aux_exch_func)
2619 CASE (do_admm_aux_exch_func_none)
2620 WRITE (unit=iounit, fmt="(T2,A)") "ADMM| No exchange functional correction term used"
2621 CASE (do_admm_aux_exch_func_default, do_admm_aux_exch_func_default_libxc)
2622 WRITE (unit=iounit, fmt="(T2,A,T74,A)") "ADMM| Exchange functional in correction term", "(W)PBEX"
2623 CASE (do_admm_aux_exch_func_pbex, do_admm_aux_exch_func_pbex_libxc)
2624 WRITE (unit=iounit, fmt="(T2,A,T77,A)") "ADMM| Exchange functional in correction term", "PBEX"
2625 CASE (do_admm_aux_exch_func_opt, do_admm_aux_exch_func_opt_libxc)
2626 WRITE (unit=iounit, fmt="(T2,A,T77,A)") "ADMM| Exchange functional in correction term", "OPTX"
2627 CASE (do_admm_aux_exch_func_bee, do_admm_aux_exch_func_bee_libxc)
2628 WRITE (unit=iounit, fmt="(T2,A,T74,A)") "ADMM| Exchange functional in correction term", "Becke88"
2629 CASE (do_admm_aux_exch_func_sx_libxc)
2630 WRITE (unit=iounit, fmt="(T2,A,T74,A)") "ADMM| Exchange functional in correction term", "SlaterX"
2631 CASE DEFAULT
2632 cpabort("admm aux_exch_func")
2633 END SELECT
2634
2635 WRITE (unit=iounit, fmt="(A)") ""
2636
2637 END IF
2638
2639 CALL cp_print_key_finished_output(iounit, logger, dft_section, &
2640 "PRINT%DFT_CONTROL_PARAMETERS")
2641 END SUBROUTINE write_admm_control
2642
2643! **************************************************************************************************
2644!> \brief Write the xTB control parameters to the output unit.
2645!> \param xtb_control ...
2646!> \param dft_section ...
2647! **************************************************************************************************
2648 SUBROUTINE write_xtb_control(xtb_control, dft_section)
2649 TYPE(xtb_control_type), POINTER :: xtb_control
2650 TYPE(section_vals_type), POINTER :: dft_section
2651
2652 CHARACTER(len=*), PARAMETER :: routinen = 'write_xtb_control'
2653
2654 CHARACTER(LEN=16) :: scc_mixer_name, solver_name
2655 INTEGER :: handle, output_unit
2656 TYPE(cp_logger_type), POINTER :: logger
2657
2658 CALL timeset(routinen, handle)
2659 NULLIFY (logger)
2660 logger => cp_get_default_logger()
2661
2662 output_unit = cp_print_key_unit_nr(logger, dft_section, &
2663 "PRINT%DFT_CONTROL_PARAMETERS", extension=".Log")
2664
2665 IF (output_unit > 0) THEN
2666
2667 WRITE (unit=output_unit, fmt="(/,T2,A,T31,A50)") &
2668 "xTB| Parameter file", adjustr(trim(xtb_control%parameter_file_name))
2669 WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &
2670 "xTB| Basis expansion STO-NG", xtb_control%sto_ng
2671 WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &
2672 "xTB| Basis expansion STO-NG for Hydrogen", xtb_control%h_sto_ng
2673 WRITE (unit=output_unit, fmt="(T2,A,T71,E10.4)") &
2674 "xTB| Repulsive pair potential accuracy", xtb_control%eps_pair
2675 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.6)") &
2676 "xTB| Repulsive enhancement factor", xtb_control%enscale
2677 WRITE (unit=output_unit, fmt="(T2,A,T71,L10)") &
2678 "xTB| Halogen interaction potential", xtb_control%xb_interaction
2679 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.3)") &
2680 "xTB| Halogen interaction potential cutoff radius", xtb_control%xb_radius
2681 WRITE (unit=output_unit, fmt="(T2,A,T71,L10)") &
2682 "xTB| Nonbonded interactions", xtb_control%do_nonbonded
2683 SELECT CASE (xtb_control%vdw_type)
2684 CASE (xtb_vdw_type_none)
2685 WRITE (unit=output_unit, fmt="(T2,A)") "xTB| No vdW potential selected"
2686 CASE (xtb_vdw_type_d3)
2687 WRITE (unit=output_unit, fmt="(T2,A,T72,A)") "xTB| vdW potential type:", "DFTD3(BJ)"
2688 WRITE (unit=output_unit, fmt="(T2,A,T31,A50)") &
2689 "xTB| D3 Dispersion: Parameter file", adjustr(trim(xtb_control%dispersion_parameter_file))
2690 CASE (xtb_vdw_type_d4)
2691 WRITE (unit=output_unit, fmt="(T2,A,T76,A)") "xTB| vdW potential type:", "DFTD4"
2692 WRITE (unit=output_unit, fmt="(T2,A,T31,A50)") &
2693 "xTB| D4 Dispersion: Parameter file", adjustr(trim(xtb_control%dispersion_parameter_file))
2694 CASE DEFAULT
2695 cpabort("vdw type")
2696 END SELECT
2697 WRITE (unit=output_unit, fmt="(T2,A,T51,3F10.3)") &
2698 "xTB| Huckel constants ks kp kd", xtb_control%ks, xtb_control%kp, xtb_control%kd
2699 WRITE (unit=output_unit, fmt="(T2,A,T61,2F10.3)") &
2700 "xTB| Huckel constants ksp k2sh", xtb_control%ksp, xtb_control%k2sh
2701 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.3)") &
2702 "xTB| Mataga-Nishimoto exponent", xtb_control%kg
2703 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.3)") &
2704 "xTB| Repulsion potential exponent", xtb_control%kf
2705 WRITE (unit=output_unit, fmt="(T2,A,T51,3F10.3)") &
2706 "xTB| Coordination number scaling kcn(s) kcn(p) kcn(d)", &
2707 xtb_control%kcns, xtb_control%kcnp, xtb_control%kcnd
2708 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.3)") &
2709 "xTB| Electronegativity scaling", xtb_control%ken
2710 WRITE (unit=output_unit, fmt="(T2,A,T61,2F10.3)") &
2711 "xTB| Halogen potential scaling kxr kx2", xtb_control%kxr, xtb_control%kx2
2712 SELECT CASE (xtb_control%tblite_scc_mixer)
2713 CASE (tblite_scc_mixer_auto)
2714 scc_mixer_name = "AUTO"
2715 CASE (tblite_scc_mixer_tblite)
2716 scc_mixer_name = "TBLITE"
2717 CASE (tblite_scc_mixer_cp2k)
2718 scc_mixer_name = "CP2K"
2719 CASE (tblite_scc_mixer_none)
2720 scc_mixer_name = "NONE"
2721 CASE DEFAULT
2722 cpabort("Unknown tblite SCC mixer")
2723 END SELECT
2724 SELECT CASE (xtb_control%tblite_mixer_solver)
2725 CASE (tblite_solver_gvd)
2726 solver_name = "GVD"
2727 CASE (tblite_solver_gvr)
2728 solver_name = "GVR"
2729 CASE DEFAULT
2730 cpabort("Unknown tblite SCC mixer solver")
2731 END SELECT
2732 WRITE (unit=output_unit, fmt="(T2,A,T72,A)") &
2733 "xTB| SCC mixer:", trim(scc_mixer_name)
2734 WRITE (unit=output_unit, fmt="(T2,A,T71,ES10.3)") &
2735 "xTB| tblite accuracy:", xtb_control%tblite_accuracy
2736 IF (len_trim(xtb_control%tblite_param_file) > 0) THEN
2737 WRITE (unit=output_unit, fmt="(T2,A,T33,A)") &
2738 "xTB| tblite parameter file:", trim(xtb_control%tblite_param_file)
2739 END IF
2740 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.3)") &
2741 "xTB| tblite SCC mixer damping:", xtb_control%tblite_mixer_damping
2742 WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &
2743 "xTB| tblite SCC mixer iterations:", xtb_control%tblite_mixer_iterations
2744 WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &
2745 "xTB| tblite SCC mixer memory:", xtb_control%tblite_mixer_memory
2746 WRITE (unit=output_unit, fmt="(T2,A,T72,A)") &
2747 "xTB| tblite SCC mixer solver:", trim(solver_name)
2748 WRITE (unit=output_unit, fmt="(T2,A,T71,ES10.3)") &
2749 "xTB| tblite SCC mixer omega0:", xtb_control%tblite_mixer_omega0
2750 WRITE (unit=output_unit, fmt="(T2,A,T71,ES10.3)") &
2751 "xTB| tblite SCC mixer min weight:", xtb_control%tblite_mixer_min_weight
2752 WRITE (unit=output_unit, fmt="(T2,A,T71,ES10.3)") &
2753 "xTB| tblite SCC mixer max weight:", xtb_control%tblite_mixer_max_weight
2754 WRITE (unit=output_unit, fmt="(T2,A,T71,ES10.3)") &
2755 "xTB| tblite SCC mixer weight factor:", xtb_control%tblite_mixer_weight_factor
2756 WRITE (unit=output_unit, fmt="(/)")
2757
2758 END IF
2759
2760 CALL cp_print_key_finished_output(output_unit, logger, dft_section, &
2761 "PRINT%DFT_CONTROL_PARAMETERS")
2762
2763 CALL timestop(handle)
2764
2765 END SUBROUTINE write_xtb_control
2766
2767! **************************************************************************************************
2768!> \brief Purpose: Write the QS control parameters to the output unit.
2769!> \param qs_control ...
2770!> \param dft_section ...
2771! **************************************************************************************************
2772 SUBROUTINE write_qs_control(qs_control, dft_section)
2773 TYPE(qs_control_type), INTENT(IN) :: qs_control
2774 TYPE(section_vals_type), POINTER :: dft_section
2775
2776 CHARACTER(len=*), PARAMETER :: routinen = 'write_qs_control'
2777
2778 CHARACTER(len=20) :: method, quadrature
2779 INTEGER :: handle, i, igrid_level, ngrid_level, &
2780 output_unit
2781 TYPE(cp_logger_type), POINTER :: logger
2782 TYPE(ddapc_restraint_type), POINTER :: ddapc_restraint_control
2783 TYPE(enumeration_type), POINTER :: enum
2784 TYPE(keyword_type), POINTER :: keyword
2785 TYPE(section_type), POINTER :: qs_section
2786 TYPE(section_vals_type), POINTER :: print_section_vals, qs_section_vals
2787
2788 IF (qs_control%semi_empirical) RETURN
2789 IF (qs_control%dftb) RETURN
2790 IF (qs_control%xtb) RETURN
2791 CALL timeset(routinen, handle)
2792 NULLIFY (logger, print_section_vals, qs_section, qs_section_vals)
2793 logger => cp_get_default_logger()
2794 print_section_vals => section_vals_get_subs_vals(dft_section, "PRINT")
2795 qs_section_vals => section_vals_get_subs_vals(dft_section, "QS")
2796 CALL section_vals_get(qs_section_vals, section=qs_section)
2797
2798 NULLIFY (enum, keyword)
2799 keyword => section_get_keyword(qs_section, "METHOD")
2800 CALL keyword_get(keyword, enum=enum)
2801 method = trim(enum_i2c(enum, qs_control%method_id))
2802
2803 NULLIFY (enum, keyword)
2804 keyword => section_get_keyword(qs_section, "QUADRATURE")
2805 CALL keyword_get(keyword, enum=enum)
2806 quadrature = trim(enum_i2c(enum, qs_control%gapw_control%quadrature))
2807
2808 output_unit = cp_print_key_unit_nr(logger, print_section_vals, &
2809 "DFT_CONTROL_PARAMETERS", extension=".Log")
2810 IF (output_unit > 0) THEN
2811 ngrid_level = SIZE(qs_control%e_cutoff)
2812 WRITE (unit=output_unit, fmt="(/,T2,A,T61,A20)") &
2813 "QS| Method:", adjustr(method)
2814 IF (qs_control%pw_grid_opt%spherical) THEN
2815 WRITE (unit=output_unit, fmt="(T2,A,T61,A)") &
2816 "QS| Density plane wave grid type", " SPHERICAL HALFSPACE"
2817 ELSE IF (qs_control%pw_grid_opt%fullspace) THEN
2818 WRITE (unit=output_unit, fmt="(T2,A,T57,A)") &
2819 "QS| Density plane wave grid type", " NON-SPHERICAL FULLSPACE"
2820 ELSE
2821 WRITE (unit=output_unit, fmt="(T2,A,T57,A)") &
2822 "QS| Density plane wave grid type", " NON-SPHERICAL HALFSPACE"
2823 END IF
2824 WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &
2825 "QS| Number of grid levels:", SIZE(qs_control%e_cutoff)
2826 IF (ngrid_level == 1) THEN
2827 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.1)") &
2828 "QS| Density cutoff [a.u.]:", qs_control%e_cutoff(1)
2829 ELSE
2830 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.1)") &
2831 "QS| Density cutoff [a.u.]:", qs_control%cutoff
2832 IF (qs_control%commensurate_mgrids) &
2833 WRITE (unit=output_unit, fmt="(T2,A)") "QS| Using commensurate multigrids"
2834 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.1)") &
2835 "QS| Multi grid cutoff [a.u.]: 1) grid level", qs_control%e_cutoff(1)
2836 WRITE (unit=output_unit, fmt="(T2,A,I3,A,T71,F10.1)") &
2837 ("QS| ", igrid_level, ") grid level", &
2838 qs_control%e_cutoff(igrid_level), &
2839 igrid_level=2, SIZE(qs_control%e_cutoff))
2840 END IF
2841 IF (qs_control%pao) THEN
2842 WRITE (unit=output_unit, fmt="(T2,A)") "QS| PAO active"
2843 END IF
2844 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.1)") &
2845 "QS| Grid level progression factor:", qs_control%progression_factor
2846 WRITE (unit=output_unit, fmt="(T2,A,T71,F10.1)") &
2847 "QS| Relative density cutoff [a.u.]:", qs_control%relative_cutoff
2848 WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &
2849 "QS| Interaction thresholds: eps_pgf_orb:", &
2850 qs_control%eps_pgf_orb, &
2851 "QS| eps_filter_matrix:", &
2852 qs_control%eps_filter_matrix, &
2853 "QS| eps_core_charge:", &
2854 qs_control%eps_core_charge, &
2855 "QS| eps_rho_gspace:", &
2856 qs_control%eps_rho_gspace, &
2857 "QS| eps_rho_rspace:", &
2858 qs_control%eps_rho_rspace, &
2859 "QS| eps_gvg_rspace:", &
2860 qs_control%eps_gvg_rspace, &
2861 "QS| eps_ppl:", &
2862 qs_control%eps_ppl, &
2863 "QS| eps_ppnl:", &
2864 qs_control%eps_ppnl
2865 IF (qs_control%gapw) THEN
2866 IF (qs_control%gapw_control%accurate_xcint) THEN
2867 WRITE (unit=output_unit, fmt="(T2,A,T69,F12.6)") &
2868 "QS| GAPW| XC integration using accurate scheme: Ref. exponent =", &
2869 qs_control%gapw_control%aweights
2870 END IF
2871 !
2872 SELECT CASE (qs_control%gapw_control%basis_1c)
2873 CASE (gapw_1c_orb)
2874 WRITE (unit=output_unit, fmt="(T2,A)") &
2875 "QS| GAPW| One center basis from orbital basis primitives"
2876 CASE (gapw_1c_small)
2877 WRITE (unit=output_unit, fmt="(T2,A)") &
2878 "QS| GAPW| One center basis extended with primitives (small:s)"
2879 CASE (gapw_1c_medium)
2880 WRITE (unit=output_unit, fmt="(T2,A)") &
2881 "QS| GAPW| One center basis extended with primitives (medium:sp)"
2882 CASE (gapw_1c_large)
2883 WRITE (unit=output_unit, fmt="(T2,A)") &
2884 "QS| GAPW| One center basis extended with primitives (large:spd)"
2885 CASE (gapw_1c_very_large)
2886 WRITE (unit=output_unit, fmt="(T2,A)") &
2887 "QS| GAPW| One center basis extended with primitives (very large:spdf)"
2888 CASE DEFAULT
2889 cpabort("basis_1c incorrect")
2890 END SELECT
2891 WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &
2892 "QS| GAPW| eps_fit:", &
2893 qs_control%gapw_control%eps_fit, &
2894 "QS| GAPW| eps_iso:", &
2895 qs_control%gapw_control%eps_iso, &
2896 "QS| GAPW| eps_svd:", &
2897 qs_control%gapw_control%eps_svd, &
2898 "QS| GAPW| eps_cpc:", &
2899 qs_control%gapw_control%eps_cpc
2900 WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &
2901 "QS| GAPW| atom-r-grid: quadrature:", &
2902 adjustr(quadrature)
2903 WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &
2904 "QS| GAPW| atom-s-grid: max l :", &
2905 qs_control%gapw_control%lmax_sphere, &
2906 "QS| GAPW| max_l_rho0 :", &
2907 qs_control%gapw_control%lmax_rho0
2908 IF (qs_control%gapw_control%non_paw_atoms) THEN
2909 WRITE (unit=output_unit, fmt="(T2,A)") &
2910 "QS| GAPW| At least one kind is NOT PAW, i.e. it has only soft AO "
2911 END IF
2912 IF (qs_control%gapw_control%nopaw_as_gpw) THEN
2913 WRITE (unit=output_unit, fmt="(T2,A)") &
2914 "QS| GAPW| The NOT PAW atoms are treated fully GPW"
2915 END IF
2916 END IF
2917 IF (qs_control%gapw_xc) THEN
2918 SELECT CASE (qs_control%gapw_control%basis_1c)
2919 CASE (gapw_1c_orb)
2920 WRITE (unit=output_unit, fmt="(T2,A)") &
2921 "QS| GAPW_XC| One center basis from orbital basis primitives"
2922 CASE (gapw_1c_small)
2923 WRITE (unit=output_unit, fmt="(T2,A)") &
2924 "QS| GAPW_XC| One center basis extended with primitives (small:s)"
2925 CASE (gapw_1c_medium)
2926 WRITE (unit=output_unit, fmt="(T2,A)") &
2927 "QS| GAPW_XC| One center basis extended with primitives (medium:sp)"
2928 CASE (gapw_1c_large)
2929 WRITE (unit=output_unit, fmt="(T2,A)") &
2930 "QS| GAPW_XC| One center basis extended with primitives (large:spd)"
2931 CASE (gapw_1c_very_large)
2932 WRITE (unit=output_unit, fmt="(T2,A)") &
2933 "QS| GAPW_XC| One center basis extended with primitives (very large:spdf)"
2934 CASE DEFAULT
2935 cpabort("basis_1c incorrect")
2936 END SELECT
2937 WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &
2938 "QS| GAPW_XC| eps_fit:", &
2939 qs_control%gapw_control%eps_fit, &
2940 "QS| GAPW_XC| eps_iso:", &
2941 qs_control%gapw_control%eps_iso, &
2942 "QS| GAPW_XC| eps_svd:", &
2943 qs_control%gapw_control%eps_svd
2944 WRITE (unit=output_unit, fmt="(T2,A,T55,A30)") &
2945 "QS| GAPW_XC|atom-r-grid: quadrature:", &
2946 enum_i2c(enum, qs_control%gapw_control%quadrature)
2947 WRITE (unit=output_unit, fmt="(T2,A,T71,I10)") &
2948 "QS| GAPW_XC| atom-s-grid: max l :", &
2949 qs_control%gapw_control%lmax_sphere
2950 END IF
2951 IF (qs_control%mulliken_restraint) THEN
2952 WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &
2953 "QS| Mulliken restraint target", qs_control%mulliken_restraint_control%target
2954 WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &
2955 "QS| Mulliken restraint strength", qs_control%mulliken_restraint_control%strength
2956 WRITE (unit=output_unit, fmt="(T2,A,T73,I8)") &
2957 "QS| Mulliken restraint atoms: ", qs_control%mulliken_restraint_control%natoms
2958 WRITE (unit=output_unit, fmt="(5I8)") qs_control%mulliken_restraint_control%atoms
2959 END IF
2960 IF (qs_control%ddapc_restraint) THEN
2961 DO i = 1, SIZE(qs_control%ddapc_restraint_control)
2962 ddapc_restraint_control => qs_control%ddapc_restraint_control(i)
2963 IF (SIZE(qs_control%ddapc_restraint_control) > 1) &
2964 WRITE (unit=output_unit, fmt="(T2,A,T3,I8)") &
2965 "QS| parameters for DDAPC restraint number", i
2966 WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &
2967 "QS| ddapc restraint target", ddapc_restraint_control%target
2968 WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &
2969 "QS| ddapc restraint strength", ddapc_restraint_control%strength
2970 WRITE (unit=output_unit, fmt="(T2,A,T73,I8)") &
2971 "QS| ddapc restraint atoms: ", ddapc_restraint_control%natoms
2972 WRITE (unit=output_unit, fmt="(5I8)") ddapc_restraint_control%atoms
2973 WRITE (unit=output_unit, fmt="(T2,A)") "Coefficients:"
2974 WRITE (unit=output_unit, fmt="(5F6.2)") ddapc_restraint_control%coeff
2975 SELECT CASE (ddapc_restraint_control%functional_form)
2976 CASE (do_ddapc_restraint)
2977 WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &
2978 "QS| ddapc restraint functional form :", "RESTRAINT"
2979 CASE (do_ddapc_constraint)
2980 WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &
2981 "QS| ddapc restraint functional form :", "CONSTRAINT"
2982 CASE DEFAULT
2983 cpabort("Unknown ddapc restraint")
2984 END SELECT
2985 END DO
2986 END IF
2987 IF (qs_control%s2_restraint) THEN
2988 WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &
2989 "QS| s2 restraint target", qs_control%s2_restraint_control%target
2990 WRITE (unit=output_unit, fmt="(T2,A,T73,ES8.1)") &
2991 "QS| s2 restraint strength", qs_control%s2_restraint_control%strength
2992 SELECT CASE (qs_control%s2_restraint_control%functional_form)
2993 CASE (do_s2_restraint)
2994 WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &
2995 "QS| s2 restraint functional form :", "RESTRAINT"
2996 cpabort("Not yet implemented")
2997 CASE (do_s2_constraint)
2998 WRITE (unit=output_unit, fmt="(T2,A,T61,A20)") &
2999 "QS| s2 restraint functional form :", "CONSTRAINT"
3000 CASE DEFAULT
3001 cpabort("Unknown ddapc restraint")
3002 END SELECT
3003 END IF
3004 END IF
3005 CALL cp_print_key_finished_output(output_unit, logger, print_section_vals, &
3006 "DFT_CONTROL_PARAMETERS")
3007
3008 CALL timestop(handle)
3009
3010 END SUBROUTINE write_qs_control
3011
3012! **************************************************************************************************
3013!> \brief reads the input parameters needed for ddapc.
3014!> \param qs_control ...
3015!> \param qs_section ...
3016!> \param ddapc_restraint_section ...
3017!> \author fschiff
3018!> \note
3019!> either reads DFT%QS%DDAPC_RESTRAINT or PROPERTIES%ET_coupling
3020!> if(qs_section is present the DFT part is read, if ddapc_restraint_section
3021!> is present ET_COUPLING is read. Avoid having both!!!
3022! **************************************************************************************************
3023 SUBROUTINE read_ddapc_section(qs_control, qs_section, ddapc_restraint_section)
3024
3025 TYPE(qs_control_type), INTENT(INOUT) :: qs_control
3026 TYPE(section_vals_type), OPTIONAL, POINTER :: qs_section, ddapc_restraint_section
3027
3028 INTEGER :: i, j, jj, k, n_rep
3029 INTEGER, DIMENSION(:), POINTER :: tmplist
3030 REAL(kind=dp), DIMENSION(:), POINTER :: rtmplist
3031 TYPE(ddapc_restraint_type), POINTER :: ddapc_restraint_control
3032 TYPE(section_vals_type), POINTER :: ddapc_section
3033
3034 IF (PRESENT(ddapc_restraint_section)) THEN
3035 IF (ASSOCIATED(qs_control%ddapc_restraint_control)) THEN
3036 IF (SIZE(qs_control%ddapc_restraint_control) >= 2) &
3037 cpabort("ET_COUPLING cannot be used in combination with a normal restraint")
3038 ELSE
3039 ddapc_section => ddapc_restraint_section
3040 ALLOCATE (qs_control%ddapc_restraint_control(1))
3041 END IF
3042 END IF
3043
3044 IF (PRESENT(qs_section)) THEN
3045 NULLIFY (ddapc_section)
3046 ddapc_section => section_vals_get_subs_vals(qs_section, &
3047 "DDAPC_RESTRAINT")
3048 END IF
3049
3050 DO i = 1, SIZE(qs_control%ddapc_restraint_control)
3051
3052 CALL ddapc_control_create(qs_control%ddapc_restraint_control(i))
3053 ddapc_restraint_control => qs_control%ddapc_restraint_control(i)
3054
3055 CALL section_vals_val_get(ddapc_section, "STRENGTH", i_rep_section=i, &
3056 r_val=ddapc_restraint_control%strength)
3057 CALL section_vals_val_get(ddapc_section, "TARGET", i_rep_section=i, &
3058 r_val=ddapc_restraint_control%target)
3059 CALL section_vals_val_get(ddapc_section, "FUNCTIONAL_FORM", i_rep_section=i, &
3060 i_val=ddapc_restraint_control%functional_form)
3061 CALL section_vals_val_get(ddapc_section, "ATOMS", i_rep_section=i, &
3062 n_rep_val=n_rep)
3063 CALL section_vals_val_get(ddapc_section, "TYPE_OF_DENSITY", i_rep_section=i, &
3064 i_val=ddapc_restraint_control%density_type)
3065
3066 jj = 0
3067 DO k = 1, n_rep
3068 CALL section_vals_val_get(ddapc_section, "ATOMS", i_rep_section=i, &
3069 i_rep_val=k, i_vals=tmplist)
3070 DO j = 1, SIZE(tmplist)
3071 jj = jj + 1
3072 END DO
3073 END DO
3074 IF (jj < 1) cpabort("Need at least 1 atom to use ddapc constraints")
3075 ddapc_restraint_control%natoms = jj
3076 IF (ASSOCIATED(ddapc_restraint_control%atoms)) &
3077 DEALLOCATE (ddapc_restraint_control%atoms)
3078 ALLOCATE (ddapc_restraint_control%atoms(ddapc_restraint_control%natoms))
3079 jj = 0
3080 DO k = 1, n_rep
3081 CALL section_vals_val_get(ddapc_section, "ATOMS", i_rep_section=i, &
3082 i_rep_val=k, i_vals=tmplist)
3083 DO j = 1, SIZE(tmplist)
3084 jj = jj + 1
3085 ddapc_restraint_control%atoms(jj) = tmplist(j)
3086 END DO
3087 END DO
3088
3089 IF (ASSOCIATED(ddapc_restraint_control%coeff)) &
3090 DEALLOCATE (ddapc_restraint_control%coeff)
3091 ALLOCATE (ddapc_restraint_control%coeff(ddapc_restraint_control%natoms))
3092 ddapc_restraint_control%coeff = 1.0_dp
3093
3094 CALL section_vals_val_get(ddapc_section, "COEFF", i_rep_section=i, &
3095 n_rep_val=n_rep)
3096 jj = 0
3097 DO k = 1, n_rep
3098 CALL section_vals_val_get(ddapc_section, "COEFF", i_rep_section=i, &
3099 i_rep_val=k, r_vals=rtmplist)
3100 DO j = 1, SIZE(rtmplist)
3101 jj = jj + 1
3102 IF (jj > ddapc_restraint_control%natoms) &
3103 cpabort("Need the same number of coeff as there are atoms ")
3104 ddapc_restraint_control%coeff(jj) = rtmplist(j)
3105 END DO
3106 END DO
3107 IF (jj < ddapc_restraint_control%natoms .AND. jj /= 0) &
3108 cpabort("Need no or the same number of coeff as there are atoms.")
3109 END DO
3110 k = 0
3111 DO i = 1, SIZE(qs_control%ddapc_restraint_control)
3112 IF (qs_control%ddapc_restraint_control(i)%functional_form == &
3113 do_ddapc_constraint) k = k + 1
3114 END DO
3115 IF (k == 2) CALL cp_abort(__location__, &
3116 "Only a single constraint possible yet, try to use restraints instead ")
3117
3118 END SUBROUTINE read_ddapc_section
3119
3120! **************************************************************************************************
3121!> \brief ...
3122!> \param dft_control ...
3123!> \param efield_section ...
3124!> \param cell ...
3125! **************************************************************************************************
3126 SUBROUTINE read_efield_sections(dft_control, efield_section, cell)
3127 TYPE(dft_control_type), POINTER :: dft_control
3128 TYPE(section_vals_type), POINTER :: efield_section
3129 TYPE(cell_type), OPTIONAL, POINTER :: cell
3130
3131 CHARACTER(len=default_path_length) :: file_name
3132 INTEGER :: i, io, j, n, unit_nr
3133 LOGICAL :: amplitude_explicit, intensity_explicit
3134 REAL(kind=dp), DIMENSION(:), POINTER :: tmp_vals
3135 TYPE(efield_type), POINTER :: efield
3136 TYPE(section_vals_type), POINTER :: tmp_section
3137
3138 DO i = 1, SIZE(dft_control%efield_fields)
3139 NULLIFY (dft_control%efield_fields(i)%efield)
3140 ALLOCATE (dft_control%efield_fields(i)%efield)
3141 efield => dft_control%efield_fields(i)%efield
3142 NULLIFY (efield%envelop_i_vars, efield%envelop_r_vars)
3143 CALL section_vals_val_get(efield_section, "INTENSITY", i_rep_section=i, &
3144 r_val=efield%strength, explicit=intensity_explicit)
3145 CALL section_vals_val_get(efield_section, "AMPLITUDE", i_rep_section=i, &
3146 r_val=efield%amplitude, explicit=amplitude_explicit)
3147
3148 IF (intensity_explicit .AND. amplitude_explicit) THEN
3149 cpabort("Both INTENSITY and AMPLITUDE provided in EFIELD section.")
3150 END IF
3151
3152 IF (intensity_explicit) THEN
3153 efield%amplitude = sqrt(efield%strength/(3.50944_dp*10.0_dp**16))
3154 END IF
3155
3156 IF (amplitude_explicit) THEN
3157 efield%strength = (3.50944_dp*10.0_dp**16)*(efield%amplitude)**2
3158 END IF
3159
3160 CALL section_vals_val_get(efield_section, "POLARISATION", i_rep_section=i, &
3161 r_vals=tmp_vals)
3162 ALLOCATE (efield%polarisation(SIZE(tmp_vals)))
3163 efield%polarisation = tmp_vals
3164 IF (PRESENT(cell)) THEN
3165 IF (ASSOCIATED(cell)) CALL cell_transform_input_cartesian(cell, efield%polarisation(1:3))
3166 END IF
3167 CALL section_vals_val_get(efield_section, "PHASE", i_rep_section=i, &
3168 r_val=efield%phase_offset)
3169 CALL section_vals_val_get(efield_section, "ENVELOP", i_rep_section=i, &
3170 i_val=efield%envelop_id)
3171 CALL section_vals_val_get(efield_section, "WAVELENGTH", i_rep_section=i, &
3172 r_val=efield%wavelength)
3173 CALL section_vals_val_get(efield_section, "VEC_POT_INITIAL", i_rep_section=i, &
3174 r_vals=tmp_vals)
3175 efield%vec_pot_initial = tmp_vals
3176 IF (PRESENT(cell)) THEN
3177 IF (ASSOCIATED(cell)) CALL cell_transform_input_cartesian(cell, efield%vec_pot_initial(1:3))
3178 END IF
3179
3180 IF (efield%envelop_id == constant_env) THEN
3181 ALLOCATE (efield%envelop_i_vars(2))
3182 tmp_section => section_vals_get_subs_vals(efield_section, "CONSTANT_ENV", i_rep_section=i)
3183 CALL section_vals_val_get(tmp_section, "START_STEP", &
3184 i_val=efield%envelop_i_vars(1))
3185 CALL section_vals_val_get(tmp_section, "END_STEP", &
3186 i_val=efield%envelop_i_vars(2))
3187 ELSE IF (efield%envelop_id == gaussian_env) THEN
3188 ALLOCATE (efield%envelop_r_vars(2))
3189 tmp_section => section_vals_get_subs_vals(efield_section, "GAUSSIAN_ENV", i_rep_section=i)
3190 CALL section_vals_val_get(tmp_section, "T0", &
3191 r_val=efield%envelop_r_vars(1))
3192 CALL section_vals_val_get(tmp_section, "SIGMA", &
3193 r_val=efield%envelop_r_vars(2))
3194 ELSE IF (efield%envelop_id == ramp_env) THEN
3195 ALLOCATE (efield%envelop_i_vars(4))
3196 tmp_section => section_vals_get_subs_vals(efield_section, "RAMP_ENV", i_rep_section=i)
3197 CALL section_vals_val_get(tmp_section, "START_STEP_IN", &
3198 i_val=efield%envelop_i_vars(1))
3199 CALL section_vals_val_get(tmp_section, "END_STEP_IN", &
3200 i_val=efield%envelop_i_vars(2))
3201 CALL section_vals_val_get(tmp_section, "START_STEP_OUT", &
3202 i_val=efield%envelop_i_vars(3))
3203 CALL section_vals_val_get(tmp_section, "END_STEP_OUT", &
3204 i_val=efield%envelop_i_vars(4))
3205 ELSE IF (efield%envelop_id == custom_env) THEN
3206 tmp_section => section_vals_get_subs_vals(efield_section, "CUSTOM_ENV", i_rep_section=i)
3207 CALL section_vals_val_get(tmp_section, "EFIELD_FILE_NAME", c_val=file_name)
3208 CALL open_file(file_name=trim(file_name), file_action="READ", file_status="OLD", unit_number=unit_nr)
3209 !Determine the number of lines in file
3210 n = 0
3211 DO WHILE (.true.)
3212 READ (unit_nr, *, iostat=io)
3213 IF (io /= 0) EXIT
3214 n = n + 1
3215 END DO
3216 rewind(unit_nr)
3217 ALLOCATE (efield%envelop_r_vars(n + 1))
3218 !Store the timestep of the list in the first entry of the r_vars
3219 CALL section_vals_val_get(tmp_section, "TIMESTEP", r_val=efield%envelop_r_vars(1))
3220 !Read the file
3221 DO j = 2, n + 1
3222 READ (unit_nr, *) efield%envelop_r_vars(j)
3223 efield%envelop_r_vars(j) = cp_unit_to_cp2k(efield%envelop_r_vars(j), "volt/m")
3224 END DO
3225 CALL close_file(unit_nr)
3226 END IF
3227 END DO
3228 END SUBROUTINE read_efield_sections
3229
3230! **************************************************************************************************
3231!> \brief reads the input parameters needed real time propagation
3232!> \param dft_control ...
3233!> \param rtp_section ...
3234!> \author fschiff
3235! **************************************************************************************************
3236 SUBROUTINE read_rtp_section(dft_control, rtp_section)
3237
3238 TYPE(dft_control_type), INTENT(INOUT) :: dft_control
3239 TYPE(section_vals_type), POINTER :: rtp_section
3240
3241 INTEGER :: i, j, n_elems
3242 INTEGER, DIMENSION(:), POINTER :: tmp
3243 LOGICAL :: is_present, local_moment_possible
3244 TYPE(section_vals_type), POINTER :: proj_mo_section, subsection
3245
3246 ALLOCATE (dft_control%rtp_control)
3247 CALL section_vals_val_get(rtp_section, "MAX_ITER", &
3248 i_val=dft_control%rtp_control%max_iter)
3249 CALL section_vals_val_get(rtp_section, "MAT_EXP", &
3250 i_val=dft_control%rtp_control%mat_exp)
3251 CALL section_vals_val_get(rtp_section, "ASPC_ORDER", &
3252 i_val=dft_control%rtp_control%aspc_order)
3253 CALL section_vals_val_get(rtp_section, "EXP_ACCURACY", &
3254 r_val=dft_control%rtp_control%eps_exp)
3255 CALL section_vals_val_get(rtp_section, "RTBSE%_SECTION_PARAMETERS_", &
3256 i_val=dft_control%rtp_control%rtp_method)
3257 CALL section_vals_val_get(rtp_section, "RTBSE%RTBSE_HAMILTONIAN", &
3258 i_val=dft_control%rtp_control%rtbse_ham)
3259 CALL section_vals_val_get(rtp_section, "PROPAGATOR", &
3260 i_val=dft_control%rtp_control%propagator)
3261 CALL section_vals_val_get(rtp_section, "EPS_ITER", &
3262 r_val=dft_control%rtp_control%eps_ener)
3263 CALL section_vals_val_get(rtp_section, "INITIAL_WFN", &
3264 i_val=dft_control%rtp_control%initial_wfn)
3265 CALL section_vals_val_get(rtp_section, "HFX_BALANCE_IN_CORE", &
3266 l_val=dft_control%rtp_control%hfx_redistribute)
3267 CALL section_vals_val_get(rtp_section, "APPLY_WFN_MIX_INIT_RESTART", &
3268 l_val=dft_control%rtp_control%apply_wfn_mix_init_restart)
3269 CALL section_vals_val_get(rtp_section, "APPLY_DELTA_PULSE", &
3270 l_val=dft_control%rtp_control%apply_delta_pulse)
3271 CALL section_vals_val_get(rtp_section, "APPLY_DELTA_PULSE_MAG", &
3272 l_val=dft_control%rtp_control%apply_delta_pulse_mag)
3273 CALL section_vals_val_get(rtp_section, "VELOCITY_GAUGE", &
3274 l_val=dft_control%rtp_control%velocity_gauge)
3275 CALL section_vals_val_get(rtp_section, "VG_COM_NL", &
3276 l_val=dft_control%rtp_control%nl_gauge_transform)
3277 CALL section_vals_val_get(rtp_section, "PERIODIC", &
3278 l_val=dft_control%rtp_control%periodic)
3279 CALL section_vals_val_get(rtp_section, "DENSITY_PROPAGATION", &
3280 l_val=dft_control%rtp_control%linear_scaling)
3281 CALL section_vals_val_get(rtp_section, "MCWEENY_MAX_ITER", &
3282 i_val=dft_control%rtp_control%mcweeny_max_iter)
3283 CALL section_vals_val_get(rtp_section, "ACCURACY_REFINEMENT", &
3284 i_val=dft_control%rtp_control%acc_ref)
3285 CALL section_vals_val_get(rtp_section, "MCWEENY_EPS", &
3286 r_val=dft_control%rtp_control%mcweeny_eps)
3287 CALL section_vals_val_get(rtp_section, "DELTA_PULSE_SCALE", &
3288 r_val=dft_control%rtp_control%delta_pulse_scale)
3289 CALL section_vals_val_get(rtp_section, "DELTA_PULSE_DIRECTION", &
3290 i_vals=tmp)
3291 dft_control%rtp_control%delta_pulse_direction = tmp
3292 CALL section_vals_val_get(rtp_section, "SC_CHECK_START", &
3293 i_val=dft_control%rtp_control%sc_check_start)
3294 proj_mo_section => section_vals_get_subs_vals(rtp_section, "PRINT%PROJECTION_MO")
3295 CALL section_vals_get(proj_mo_section, explicit=is_present)
3296 IF (is_present) THEN
3297 IF (dft_control%rtp_control%linear_scaling) &
3298 CALL cp_abort(__location__, &
3299 "You have defined a time dependent projection of mos, but "// &
3300 "only the density matrix is propagated (DENSITY_PROPAGATION "// &
3301 ".TRUE.). Please either use MO-based real time DFT or do not "// &
3302 "define any PRINT%PROJECTION_MO section")
3303 dft_control%rtp_control%is_proj_mo = .true.
3304 ELSE
3305 dft_control%rtp_control%is_proj_mo = .false.
3306 END IF
3307 ! Moment trace
3308 local_moment_possible = (dft_control%rtp_control%rtp_method == rtp_method_bse) .OR. &
3309 ((.NOT. dft_control%rtp_control%periodic) .AND. dft_control%rtp_control%linear_scaling)
3310 ! TODO : Implement for other moment operators
3311 subsection => section_vals_get_subs_vals(rtp_section, "PRINT%MOMENTS")
3312 CALL section_vals_get(subsection, explicit=is_present)
3313 ! Trigger the flag
3314 dft_control%rtp_control%save_local_moments = &
3315 is_present .OR. dft_control%rtp_control%save_local_moments
3316 IF (is_present .AND. (.NOT. local_moment_possible)) THEN
3317 CALL cp_abort(__location__, "Moments trace printing only "// &
3318 "implemented in non-periodic systems in linear scaling. "// &
3319 "Please use DFT%PRINT%MOMENTS for other printing.")
3320 END IF
3321 CALL section_vals_val_get(rtp_section, "PRINT%MOMENTS%REFERENCE", &
3322 i_val=dft_control%rtp_control%moment_trace_ref_type)
3323 CALL section_vals_val_get(rtp_section, "PRINT%MOMENTS%REFERENCE_POINT", &
3324 r_vals=dft_control%rtp_control%moment_trace_user_ref_point)
3325 ! Moment Fourier transform
3326 subsection => section_vals_get_subs_vals(rtp_section, "PRINT%MOMENTS_FT")
3327 CALL section_vals_get(subsection, explicit=is_present)
3328 ! Trigger the flag
3329 dft_control%rtp_control%save_local_moments = &
3330 is_present .OR. dft_control%rtp_control%save_local_moments
3331 IF (is_present .AND. (.NOT. local_moment_possible)) THEN
3332 ! Not implemented
3333 CALL cp_abort(__location__, "Moments Fourier transform printing "// &
3334 "implemented only for non-periodic systems in linear scaling.")
3335 END IF
3336 ! General FT settings
3337 CALL section_vals_val_get(rtp_section, "FT%DAMPING", &
3338 r_val=dft_control%rtp_control%ft_damping)
3339 CALL section_vals_val_get(rtp_section, "FT%START_TIME", &
3340 r_val=dft_control%rtp_control%ft_t0)
3341 ! Padé settings
3342 subsection => section_vals_get_subs_vals(rtp_section, "FT%PADE")
3343 CALL section_vals_val_get(subsection, "_SECTION_PARAMETERS_", &
3344 l_val=dft_control%rtp_control%pade_requested)
3345 CALL section_vals_val_get(subsection, "E_MIN", &
3346 r_val=dft_control%rtp_control%pade_e_min)
3347 CALL section_vals_val_get(subsection, "E_STEP", &
3348 r_val=dft_control%rtp_control%pade_e_step)
3349 CALL section_vals_val_get(subsection, "E_MAX", &
3350 r_val=dft_control%rtp_control%pade_e_max)
3351 CALL section_vals_val_get(subsection, "FIT_E_MIN", &
3352 r_val=dft_control%rtp_control%pade_fit_e_min)
3353 CALL section_vals_val_get(subsection, "FIT_E_MAX", &
3354 r_val=dft_control%rtp_control%pade_fit_e_max)
3355 ! If default settings used for fit_e_min/max, rewrite with appropriate values
3356 IF (dft_control%rtp_control%pade_fit_e_min < 0) THEN
3357 dft_control%rtp_control%pade_fit_e_min = dft_control%rtp_control%pade_e_min
3358 END IF
3359 IF (dft_control%rtp_control%pade_fit_e_max < 0) THEN
3360 dft_control%rtp_control%pade_fit_e_max = dft_control%rtp_control%pade_e_max
3361 END IF
3362 ! Polarizability settings
3363 subsection => section_vals_get_subs_vals(rtp_section, "PRINT%POLARIZABILITY")
3364 CALL section_vals_get(subsection, explicit=is_present)
3365 ! Trigger the flag
3366 dft_control%rtp_control%save_local_moments = &
3367 is_present .OR. dft_control%rtp_control%save_local_moments
3368 IF (is_present .AND. (.NOT. local_moment_possible)) THEN
3369 ! Not implemented
3370 CALL cp_abort(__location__, "Polarizability printing "// &
3371 "implemented only for non-periodic systems.")
3372 END IF
3373 CALL section_vals_val_get(subsection, "ELEMENT", explicit=is_present, n_rep_val=n_elems)
3374 NULLIFY (dft_control%rtp_control%print_pol_elements)
3375 IF (is_present) THEN
3376 ! Explicit list of elements
3377 ! Allocate the array
3378 ALLOCATE (dft_control%rtp_control%print_pol_elements(n_elems, 2))
3379 DO i = 1, n_elems
3380 CALL section_vals_val_get(subsection, "ELEMENT", i_vals=tmp, i_rep_val=i)
3381 dft_control%rtp_control%print_pol_elements(i, :) = tmp(:)
3382 END DO
3383 ! Do basic sanity checks for pol_element
3384 DO i = 1, n_elems
3385 DO j = 1, 2
3386 IF (dft_control%rtp_control%print_pol_elements(i, j) > 3 .OR. &
3387 dft_control%rtp_control%print_pol_elements(i, j) < 1) &
3388 cpabort("Polarisation tensor element not 1,2 or 3 in at least one index")
3389 END DO
3390 END DO
3391 END IF
3392
3393 ! Finally, allow printing of FT observables also in the case when they are not explicitly
3394 ! required, but they are available, i.e. non-periodic linear scaling calculation
3395 dft_control%rtp_control%save_local_moments = &
3396 dft_control%rtp_control%save_local_moments .OR. &
3397 ((.NOT. dft_control%rtp_control%periodic) .AND. dft_control%rtp_control%linear_scaling)
3398
3399 END SUBROUTINE read_rtp_section
3400! **************************************************************************************************
3401!> \brief Tries to guess the elements of polarization to print
3402!> \param dftc DFT parameters
3403!> \param elems 2D array, where the guessed element indeces are stored
3404!> \date 11.2025
3405!> \author Stepan Marek
3406! **************************************************************************************************
3407 SUBROUTINE guess_pol_elements(dftc, elems)
3408 TYPE(dft_control_type) :: dftc
3409 INTEGER, DIMENSION(:, :), POINTER :: elems
3410
3411 INTEGER :: i, i_nonzero, n_nonzero
3412 LOGICAL :: pol_vector_known
3413 REAL(kind=dp), DIMENSION(3) :: pol_vector
3414
3415 pol_vector_known = .false.
3416
3417 ! TODO : More relevant elements for magnetic pulse?
3418 IF (dftc%rtp_control%apply_delta_pulse .OR. dftc%rtp_control%apply_delta_pulse_mag) THEN
3419 pol_vector(:) = real(dftc%rtp_control%delta_pulse_direction(:), kind=dp)
3420 ELSE
3421 ! Maybe RT field is applied?
3422 pol_vector(:) = dftc%efield_fields(1)%efield%polarisation(:)
3423 END IF
3424 IF (dot_product(pol_vector, pol_vector) > 0.0_dp) pol_vector_known = .true.
3425
3426 IF (.NOT. pol_vector_known) THEN
3427 cpabort("Cannot guess polarization elements - please specify!")
3428 ELSE
3429 ! Check whether just one element is non-zero
3430 n_nonzero = 0
3431 DO i = 1, 3
3432 IF (pol_vector(i) /= 0.0_dp) THEN
3433 n_nonzero = n_nonzero + 1
3434 i_nonzero = i
3435 END IF
3436 END DO
3437 IF (n_nonzero > 1) THEN
3438 CALL cp_abort(__location__, &
3439 "More than one non-zero field elements - "// &
3440 "cannot guess polarizability elements - please specify!")
3441 ELSE IF (n_nonzero == 0) THEN
3442 CALL cp_abort(__location__, &
3443 "No non-zero field elements - "// &
3444 "cannot guess polarizability elements - please specify!")
3445 ELSE
3446 ! Clear guess can be made
3447 NULLIFY (elems)
3448 ALLOCATE (elems(3, 2))
3449 DO i = 1, 3
3450 elems(i, 1) = i
3451 elems(i, 2) = i_nonzero
3452 END DO
3453 END IF
3454 END IF
3455 END SUBROUTINE guess_pol_elements
3456
3457! **************************************************************************************************
3458!> \brief Parses the BLOCK_LIST keywords from the ADMM section
3459!> \param admm_control ...
3460!> \param dft_section ...
3461! **************************************************************************************************
3462 SUBROUTINE read_admm_block_list(admm_control, dft_section)
3463 TYPE(admm_control_type), POINTER :: admm_control
3464 TYPE(section_vals_type), POINTER :: dft_section
3465
3466 INTEGER :: irep, list_size, n_rep
3467 INTEGER, DIMENSION(:), POINTER :: tmplist
3468
3469 NULLIFY (tmplist)
3470
3471 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%BLOCK_LIST", &
3472 n_rep_val=n_rep)
3473
3474 ALLOCATE (admm_control%blocks(n_rep))
3475
3476 DO irep = 1, n_rep
3477 CALL section_vals_val_get(dft_section, "AUXILIARY_DENSITY_MATRIX_METHOD%BLOCK_LIST", &
3478 i_rep_val=irep, i_vals=tmplist)
3479 list_size = SIZE(tmplist)
3480 ALLOCATE (admm_control%blocks(irep)%list(list_size))
3481 admm_control%blocks(irep)%list(:) = tmplist(:)
3482 END DO
3483
3484 END SUBROUTINE read_admm_block_list
3485
3486! **************************************************************************************************
3487!> \brief ...
3488!> \param dft_control ...
3489!> \param hairy_probes_section ...
3490!> \param
3491!> \param
3492! **************************************************************************************************
3493 SUBROUTINE read_hairy_probes_sections(dft_control, hairy_probes_section)
3494 TYPE(dft_control_type), POINTER :: dft_control
3495 TYPE(section_vals_type), POINTER :: hairy_probes_section
3496
3497 INTEGER :: i, j, jj, kk, n_rep
3498 INTEGER, DIMENSION(:), POINTER :: tmplist
3499
3500 DO i = 1, SIZE(dft_control%probe)
3501 NULLIFY (dft_control%probe(i)%atom_ids)
3502
3503 CALL section_vals_val_get(hairy_probes_section, "ATOM_IDS", i_rep_section=i, n_rep_val=n_rep)
3504 jj = 0
3505 DO kk = 1, n_rep
3506 CALL section_vals_val_get(hairy_probes_section, "ATOM_IDS", i_rep_section=i, i_rep_val=kk, i_vals=tmplist)
3507 jj = jj + SIZE(tmplist)
3508 END DO
3509
3510 dft_control%probe(i)%natoms = jj
3511 IF (dft_control%probe(i)%natoms < 1) &
3512 cpabort("Need at least 1 atom to use hair probes formalism")
3513 ALLOCATE (dft_control%probe(i)%atom_ids(dft_control%probe(i)%natoms))
3514
3515 jj = 0
3516 DO kk = 1, n_rep
3517 CALL section_vals_val_get(hairy_probes_section, "ATOM_IDS", i_rep_section=i, i_rep_val=kk, i_vals=tmplist)
3518 DO j = 1, SIZE(tmplist)
3519 jj = jj + 1
3520 dft_control%probe(i)%atom_ids(jj) = tmplist(j)
3521 END DO
3522 END DO
3523
3524 CALL section_vals_val_get(hairy_probes_section, "MU", i_rep_section=i, r_val=dft_control%probe(i)%mu)
3525
3526 CALL section_vals_val_get(hairy_probes_section, "T", i_rep_section=i, r_val=dft_control%probe(i)%T)
3527
3528 CALL section_vals_val_get(hairy_probes_section, "ALPHA", i_rep_section=i, r_val=dft_control%probe(i)%alpha)
3529
3530 CALL section_vals_val_get(hairy_probes_section, "eps_hp", i_rep_section=i, r_val=dft_control%probe(i)%eps_hp)
3531 END DO
3532
3533 END SUBROUTINE read_hairy_probes_sections
3534! **************************************************************************************************
3535
3536END MODULE cp_control_utils
bibliography
collects all references to literature in CP2K as new algorithms / method are included from literature...
Definition bibliography.F:21
bibliography::vandevondele2005b
integer, save, public vandevondele2005b
Definition bibliography.F:36
bibliography::umari2002
integer, save, public umari2002
Definition bibliography.F:36
bibliography::katbashev2025
integer, save, public katbashev2025
Definition bibliography.F:36
bibliography::yin2017
integer, save, public yin2017
Definition bibliography.F:36
bibliography::stewart2007
integer, save, public stewart2007
Definition bibliography.F:36
bibliography::stengel2009
integer, save, public stengel2009
Definition bibliography.F:36
bibliography::vandevondele2005a
integer, save, public vandevondele2005a
Definition bibliography.F:36
bibliography::grimme2017
integer, save, public grimme2017
Definition bibliography.F:36
bibliography::lippert1999
integer, save, public lippert1999
Definition bibliography.F:36
bibliography::dewar1977
integer, save, public dewar1977
Definition bibliography.F:36
bibliography::elstner1998
integer, save, public elstner1998
Definition bibliography.F:36
bibliography::vanvoorhis2015
integer, save, public vanvoorhis2015
Definition bibliography.F:36
bibliography::repasky2002
integer, save, public repasky2002
Definition bibliography.F:36
bibliography::hu2007
integer, save, public hu2007
Definition bibliography.F:36
bibliography::andreussi2012
integer, save, public andreussi2012
Definition bibliography.F:36
bibliography::rocha2006
integer, save, public rocha2006
Definition bibliography.F:36
bibliography::lippert1997
integer, save, public lippert1997
Definition bibliography.F:36
bibliography::fattebert2002
integer, save, public fattebert2002
Definition bibliography.F:36
bibliography::thiel1992
integer, save, public thiel1992
Definition bibliography.F:36
bibliography::pracht2019
integer, save, public pracht2019
Definition bibliography.F:36
bibliography::porezag1995
integer, save, public porezag1995
Definition bibliography.F:36
bibliography::souza2002
integer, save, public souza2002
Definition bibliography.F:36
bibliography::schenter2008
integer, save, public schenter2008
Definition bibliography.F:36
bibliography::krack2000
integer, save, public krack2000
Definition bibliography.F:36
bibliography::dewar1985
integer, save, public dewar1985
Definition bibliography.F:36
bibliography::stewart1989
integer, save, public stewart1989
Definition bibliography.F:36
bibliography::seifert1996
integer, save, public seifert1996
Definition bibliography.F:36
bibliography::zhechkov2005
integer, save, public zhechkov2005
Definition bibliography.F:36
cell_types
Handles all functions related to the CELL.
Definition cell_types.F:15
cell_types::cell_transform_input_cartesian
subroutine, public cell_transform_input_cartesian(cell, vector)
Transform a Cartesian real-space vector from the user input cell frame into CP2K's canonical internal...
Definition cell_types.F:261
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:968
cp_control_types::expot_control_create
subroutine, public expot_control_create(expot_control)
...
Definition cp_control_types.F:1374
cp_control_types::maxwell_control_create
subroutine, public maxwell_control_create(maxwell_control)
...
Definition cp_control_types.F:1403
cp_control_types::ddapc_control_create
subroutine, public ddapc_control_create(ddapc_restraint_control)
create the ddapc_restraint_type
Definition cp_control_types.F:901
cp_control_types::admm_control_create
subroutine, public admm_control_create(admm_control)
...
Definition cp_control_types.F:1350
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:2773
cp_control_utils::read_rixs_control
subroutine, public read_rixs_control(rixs_control, rixs_section, qs_control)
Reads the input and stores in the rixs_control_type.
Definition cp_control_utils.F:809
cp_control_utils::read_qs_section
subroutine, public read_qs_section(qs_control, qs_section, cell)
...
Definition cp_control_utils.F:925
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:2035
cp_control_utils::read_dft_control
subroutine, public read_dft_control(dft_control, dft_section, cell)
...
Definition cp_control_utils.F:119
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:2545
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:2266
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:3024
cp_control_utils::read_mgrid_section
subroutine, public read_mgrid_section(qs_control, dft_section)
...
Definition cp_control_utils.F:834
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:311
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:122
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:853
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:1067
cp_parser_methods
Utility routines to read data from files. Kept as close as possible to the old parser because.
Definition cp_parser_methods.F:20
cp_parser_methods::parser_read_line
subroutine, public parser_read_line(parser, nline, at_end)
Read the next line from a logical unit "unit" (I/O node only). Skip (nline-1) lines and skip also all...
Definition cp_parser_methods.F:147
cp_parser_types
Utility routines to read data from files. Kept as close as possible to the old parser because.
Definition cp_parser_types.F:21
cp_parser_types::parser_reset
subroutine, public parser_reset(parser)
Resets the parser: rewinding the unit and re-initializing all parser structures.
Definition cp_parser_types.F:228
cp_parser_types::parser_release
subroutine, public parser_release(parser)
releases the parser
Definition cp_parser_types.F:109
cp_parser_types::parser_create
subroutine, public parser_create(parser, file_name, unit_nr, para_env, end_section_label, separator_chars, comment_char, continuation_char, quote_char, section_char, parse_white_lines, initial_variables, apply_preprocessing)
Start a parser run. Initial variables allow to @SET stuff before opening the file.
Definition cp_parser_types.F:147
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:1239
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:1210
eeq_input
Input definition and setup for EEQ model.
Definition eeq_input.F:12
eeq_input::read_eeq_param
subroutine, public read_eeq_param(eeq_section, eeq_sparam)
...
Definition eeq_input.F:110
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:1337
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:593
input_constants::sic_mauri_spz
integer, parameter, public sic_mauri_spz
Definition input_constants.F:588
input_constants::do_method_ofgpw
integer, parameter, public do_method_ofgpw
Definition input_constants.F:259
input_constants::do_admm_purify_mo_no_diag
integer, parameter, public do_admm_purify_mo_no_diag
Definition input_constants.F:880
input_constants::do_se_lr_ewald_gks
integer, parameter, public do_se_lr_ewald_gks
Definition input_constants.F:290
input_constants::do_admm_aux_exch_func_opt_libxc
integer, parameter, public do_admm_aux_exch_func_opt_libxc
Definition input_constants.F:895
input_constants::gfn1xtb
integer, parameter, public gfn1xtb
Definition input_constants.F:1373
input_constants::do_s2_restraint
integer, parameter, public do_s2_restraint
Definition input_constants.F:786
input_constants::do_admm_purify_none
integer, parameter, public do_admm_purify_none
Definition input_constants.F:880
input_constants::do_method_rigpw
integer, parameter, public do_method_rigpw
Definition input_constants.F:259
input_constants::do_s2_constraint
integer, parameter, public do_s2_constraint
Definition input_constants.F:786
input_constants::use_mom_ref_user
integer, parameter, public use_mom_ref_user
Definition input_constants.F:509
input_constants::do_method_gpw
integer, parameter, public do_method_gpw
Definition input_constants.F:259
input_constants::gapw_1c_large
integer, parameter, public gapw_1c_large
Definition input_constants.F:236
input_constants::tblite_scc_mixer_cp2k
integer, parameter, public tblite_scc_mixer_cp2k
Definition input_constants.F:1379
input_constants::do_method_pdg
integer, parameter, public do_method_pdg
Definition input_constants.F:259
input_constants::do_admm_purify_none_dm
integer, parameter, public do_admm_purify_none_dm
Definition input_constants.F:880
input_constants::do_method_pnnl
integer, parameter, public do_method_pnnl
Definition input_constants.F:259
input_constants::do_ddapc_constraint
integer, parameter, public do_ddapc_constraint
Definition input_constants.F:746
input_constants::tblite_scc_mixer_none
integer, parameter, public tblite_scc_mixer_none
Definition input_constants.F:1379
input_constants::tblite_mixer_memory_inherit
integer, parameter, public tblite_mixer_memory_inherit
Definition input_constants.F:1385
input_constants::do_se_lr_none
integer, parameter, public do_se_lr_none
Definition input_constants.F:290
input_constants::do_admm_purify_mcweeny
integer, parameter, public do_admm_purify_mcweeny
Definition input_constants.F:880
input_constants::do_se_lr_ewald
integer, parameter, public do_se_lr_ewald
Definition input_constants.F:290
input_constants::do_admm_blocking_purify_full
integer, parameter, public do_admm_blocking_purify_full
Definition input_constants.F:889
input_constants::ramp_env
integer, parameter, public ramp_env
Definition input_constants.F:968
input_constants::tblite_solver_gvd
integer, parameter, public tblite_solver_gvd
Definition input_constants.F:1399
input_constants::do_se_is_kdso_d
integer, parameter, public do_se_is_kdso_d
Definition input_constants.F:286
input_constants::gapw_1c_medium
integer, parameter, public gapw_1c_medium
Definition input_constants.F:236
input_constants::do_admm_aux_exch_func_sx_libxc
integer, parameter, public do_admm_aux_exch_func_sx_libxc
Definition input_constants.F:895
input_constants::tblite_cli_solution_state_gsolv
integer, parameter, public tblite_cli_solution_state_gsolv
Definition input_constants.F:1414
input_constants::admm2_type
integer, parameter, public admm2_type
Definition input_constants.F:910
input_constants::xtb_vdw_type_d3
integer, parameter, public xtb_vdw_type_d3
Definition input_constants.F:649
input_constants::sic_list_all
integer, parameter, public sic_list_all
Definition input_constants.F:593
input_constants::constant_env
integer, parameter, public constant_env
Definition input_constants.F:968
input_constants::kg_tnadd_embed_ri
integer, parameter, public kg_tnadd_embed_ri
Definition input_constants.F:1180
input_constants::tblite_cli_solvation_gb
integer, parameter, public tblite_cli_solvation_gb
Definition input_constants.F:1403
input_constants::kg_tnadd_embed
integer, parameter, public kg_tnadd_embed
Definition input_constants.F:1180
input_constants::sic_eo
integer, parameter, public sic_eo
Definition input_constants.F:588
input_constants::sccs_derivative_cd5
integer, parameter, public sccs_derivative_cd5
Definition input_constants.F:1225
input_constants::do_admm_aux_exch_func_bee
integer, parameter, public do_admm_aux_exch_func_bee
Definition input_constants.F:895
input_constants::tblite_solver_gvr
integer, parameter, public tblite_solver_gvr
Definition input_constants.F:1399
input_constants::no_admm_type
integer, parameter, public no_admm_type
Definition input_constants.F:910
input_constants::do_admm_blocked_projection
integer, parameter, public do_admm_blocked_projection
Definition input_constants.F:889
input_constants::tblite_scc_mixer_tblite
integer, parameter, public tblite_scc_mixer_tblite
Definition input_constants.F:1379
input_constants::do_admm_basis_projection
integer, parameter, public do_admm_basis_projection
Definition input_constants.F:889
input_constants::do_method_rm1
integer, parameter, public do_method_rm1
Definition input_constants.F:259
input_constants::do_admm_aux_exch_func_default_libxc
integer, parameter, public do_admm_aux_exch_func_default_libxc
Definition input_constants.F:895
input_constants::do_admm_aux_exch_func_opt
integer, parameter, public do_admm_aux_exch_func_opt
Definition input_constants.F:895
input_constants::gapw_1c_small
integer, parameter, public gapw_1c_small
Definition input_constants.F:236
input_constants::do_admm_aux_exch_func_none
integer, parameter, public do_admm_aux_exch_func_none
Definition input_constants.F:895
input_constants::do_admm_purify_cauchy_subspace
integer, parameter, public do_admm_purify_cauchy_subspace
Definition input_constants.F:880
input_constants::do_method_pm3
integer, parameter, public do_method_pm3
Definition input_constants.F:259
input_constants::do_admm_aux_exch_func_bee_libxc
integer, parameter, public do_admm_aux_exch_func_bee_libxc
Definition input_constants.F:895
input_constants::tblite_cli_solvation_alpb
integer, parameter, public tblite_cli_solvation_alpb
Definition input_constants.F:1403
input_constants::admm1_type
integer, parameter, public admm1_type
Definition input_constants.F:910
input_constants::do_admm_aux_exch_func_pbex_libxc
integer, parameter, public do_admm_aux_exch_func_pbex_libxc
Definition input_constants.F:895
input_constants::tblite_cli_born_kernel_auto
integer, parameter, public tblite_cli_born_kernel_auto
Definition input_constants.F:1410
input_constants::do_method_mndo
integer, parameter, public do_method_mndo
Definition input_constants.F:259
input_constants::gapw_1c_orb
integer, parameter, public gapw_1c_orb
Definition input_constants.F:236
input_constants::do_admm_aux_exch_func_default
integer, parameter, public do_admm_aux_exch_func_default
Definition input_constants.F:895
input_constants::xtb_vdw_type_d4
integer, parameter, public xtb_vdw_type_d4
Definition input_constants.F:649
input_constants::do_pwgrid_ns_fullspace
integer, parameter, public do_pwgrid_ns_fullspace
Definition input_constants.F:242
input_constants::gapw_1c_very_large
integer, parameter, public gapw_1c_very_large
Definition input_constants.F:236
input_constants::rtp_method_bse
integer, parameter, public rtp_method_bse
Definition input_constants.F:977
input_constants::do_method_gapw
integer, parameter, public do_method_gapw
Definition input_constants.F:259
input_constants::admms_type
integer, parameter, public admms_type
Definition input_constants.F:910
input_constants::do_admm_charge_constrained_projection
integer, parameter, public do_admm_charge_constrained_projection
Definition input_constants.F:889
input_constants::do_admm_purify_cauchy
integer, parameter, public do_admm_purify_cauchy
Definition input_constants.F:880
input_constants::sccs_fattebert_gygi
integer, parameter, public sccs_fattebert_gygi
Definition input_constants.F:1221
input_constants::tblite_scc_mixer_auto
integer, parameter, public tblite_scc_mixer_auto
Definition input_constants.F:1379
input_constants::gaussian_env
integer, parameter, public gaussian_env
Definition input_constants.F:968
input_constants::tblite_cli_solvation_cpcm
integer, parameter, public tblite_cli_solvation_cpcm
Definition input_constants.F:1403
input_constants::sccs_derivative_cd7
integer, parameter, public sccs_derivative_cd7
Definition input_constants.F:1225
input_constants::do_method_mndod
integer, parameter, public do_method_mndod
Definition input_constants.F:259
input_constants::xtb_vdw_type_none
integer, parameter, public xtb_vdw_type_none
Definition input_constants.F:649
input_constants::do_method_am1
integer, parameter, public do_method_am1
Definition input_constants.F:259
input_constants::do_method_dftb
integer, parameter, public do_method_dftb
Definition input_constants.F:259
input_constants::tddfpt_dipole_length
integer, parameter, public tddfpt_dipole_length
Definition input_constants.F:722
input_constants::tblite_cli_solvation_gbe
integer, parameter, public tblite_cli_solvation_gbe
Definition input_constants.F:1403
input_constants::sccs_derivative_fft
integer, parameter, public sccs_derivative_fft
Definition input_constants.F:1225
input_constants::tddfpt_kernel_stda
integer, parameter, public tddfpt_kernel_stda
Definition input_constants.F:601
input_constants::do_pwgrid_spherical
integer, parameter, public do_pwgrid_spherical
Definition input_constants.F:242
input_constants::gfn_tblite
integer, parameter, public gfn_tblite
Definition input_constants.F:1373
input_constants::do_se_lr_ewald_r3
integer, parameter, public do_se_lr_ewald_r3
Definition input_constants.F:290
input_constants::do_se_is_kdso
integer, parameter, public do_se_is_kdso
Definition input_constants.F:286
input_constants::do_admm_purify_mo_diag
integer, parameter, public do_admm_purify_mo_diag
Definition input_constants.F:880
input_constants::do_method_lrigpw
integer, parameter, public do_method_lrigpw
Definition input_constants.F:259
input_constants::tblite_cli_solvation_gbsa
integer, parameter, public tblite_cli_solvation_gbsa
Definition input_constants.F:1403
input_constants::sic_mauri_us
integer, parameter, public sic_mauri_us
Definition input_constants.F:588
input_constants::sic_none
integer, parameter, public sic_none
Definition input_constants.F:588
input_constants::do_se_is_slater
integer, parameter, public do_se_is_slater
Definition input_constants.F:286
input_constants::custom_env
integer, parameter, public custom_env
Definition input_constants.F:968
input_constants::tblite_guess_ceh
integer, parameter, public tblite_guess_ceh
Definition input_constants.F:1394
input_constants::do_method_xtb
integer, parameter, public do_method_xtb
Definition input_constants.F:259
input_constants::do_ddapc_restraint
integer, parameter, public do_ddapc_restraint
Definition input_constants.F:746
input_constants::do_pwgrid_ns_halfspace
integer, parameter, public do_pwgrid_ns_halfspace
Definition input_constants.F:242
input_constants::sccs_derivative_cd3
integer, parameter, public sccs_derivative_cd3
Definition input_constants.F:1225
input_constants::do_method_pm6fm
integer, parameter, public do_method_pm6fm
Definition input_constants.F:259
input_constants::admmq_type
integer, parameter, public admmq_type
Definition input_constants.F:910
input_constants::sccs_andreussi
integer, parameter, public sccs_andreussi
Definition input_constants.F:1221
input_constants::sic_ad
integer, parameter, public sic_ad
Definition input_constants.F:588
input_constants::do_admm_exch_scaling_none
integer, parameter, public do_admm_exch_scaling_none
Definition input_constants.F:907
input_constants::admmp_type
integer, parameter, public admmp_type
Definition input_constants.F:910
input_constants::do_method_gapw_xc
integer, parameter, public do_method_gapw_xc
Definition input_constants.F:259
input_constants::do_admm_exch_scaling_merlot
integer, parameter, public do_admm_exch_scaling_merlot
Definition input_constants.F:907
input_constants::real_time_propagation
integer, parameter, public real_time_propagation
Definition input_constants.F:127
input_constants::numerical
integer, parameter, public numerical
Definition input_constants.F:159
input_constants::do_method_pm6
integer, parameter, public do_method_pm6
Definition input_constants.F:259
input_constants::do_admm_aux_exch_func_pbex
integer, parameter, public do_admm_aux_exch_func_pbex
Definition input_constants.F:895
input_constants::slater
integer, parameter, public slater
Definition input_constants.F:159
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:168
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:122
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:481
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:1223
input_section_types::section_get_ival
integer function, public section_get_ival(section_vals, keyword_name)
...
Definition input_section_types.F:980
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:731
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:238
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:478
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:704
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:1047
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, nequip, bmhft, bmhftd, ipbv, buck4r, buckmo, gp, tersoff, siepmann, gal, gal21, tab, deepmd, ace)
Cleans the potential parameter type.
Definition pair_potential_types.F:1083
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
smeagol_control_types
Input control types for NEGF/SMEAGOL transport calculations.
Definition smeagol_control_types.F:15
smeagol_control_types::read_smeagol_control
subroutine, public read_smeagol_control(smeagol_control, smeagol_section)
Read SMEAGOL-related input parameters.
Definition smeagol_control_types.F:393
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:3362
util
All kind of helpful little routines.
Definition util.F:14
xas_tdp_types
Define XAS TDP control type and associated create, release, etc subroutines, as well as XAS TDP envir...
Definition xas_tdp_types.F:13
xas_tdp_types::read_xas_tdp_control
subroutine, public read_xas_tdp_control(xas_tdp_control, xas_tdp_section)
Reads the inputs and stores in xas_tdp_control_type.
Definition xas_tdp_types.F:486
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:115
xc::xc_uses_kinetic_energy_density
logical function, public xc_uses_kinetic_energy_density(xc_fun_section, lsd)
...
Definition xc.F:95
cell_types::cell_type
Type defining parameters related to the simulation cell.
Definition cell_types.F:60
cp_control_types::admm_control_type
Definition cp_control_types.F:455
cp_control_types::ddapc_restraint_type
Definition cp_control_types.F:426
cp_control_types::dft_control_type
Definition cp_control_types.F:744
cp_control_types::efield_type
Definition cp_control_types.F:383
cp_control_types::qs_control_type
Definition cp_control_types.F:493
cp_control_types::rixs_control_type
Definition cp_control_types.F:728
cp_control_types::tddfpt2_control_type
Definition cp_control_types.F:621
cp_control_types::xtb_control_type
Definition cp_control_types.F:255
cp_control_types::xtb_reference_cli_type
Definition cp_control_types.F:223
cp_log_handling::cp_logger_type
type of a logger, at the moment it contains just a print level starting at which level it should be l...
Definition cp_log_handling.F:140
cp_parser_types::cp_parser_type
represent a parser
Definition cp_parser_types.F:77
input_enumeration_types::enumeration_type
Definition input_enumeration_types.F:43
input_keyword_types::keyword_type
represent a keyword in the input
Definition input_keyword_types.F:89
input_section_types::section_type
represent a section of the input file
Definition input_section_types.F:102
input_section_types::section_vals_type
stores the values of a section
Definition input_section_types.F:127