#!/usr/bin/env python3 """ convert output of GAMESS/GAU$$IAN to ezfio Usage: qp_convert_output_to_ezfio [-o EZFIO_DIR] FILE Options: -o --output=EZFIO_DIR Produced directory by default is FILE.ezfio """ import sys import os from functools import reduce from ezfio import ezfio from docopt import docopt try: QP_ROOT = os.environ["QP_ROOT"] QP_EZFIO = os.environ["QP_EZFIO"] except KeyError: print("Error: QP_ROOT environment variable not found.") sys.exit(1) else: sys.path = [QP_EZFIO + "/Python", QP_ROOT + "/install/resultsFile", QP_ROOT + "/install", QP_ROOT + "/scripts"] + sys.path from resultsFile import * try: from resultsFile import * except: print("Error: resultsFile Python library not installed") sys.exit(1) def write_ezfio(res, filename): res.clean_uncontractions() ezfio.set_file(filename) # _ # |_ | _ _ _|_ ._ _ ._ _ # |_ | (/_ (_ |_ | (_) | | _> # print("Electrons\t...\t", end=' ') ezfio.set_electrons_elec_alpha_num(res.num_alpha) ezfio.set_electrons_elec_beta_num(res.num_beta) print("OK") # # |\ | _ | _ o # | \| |_| (_ | (/_ | # print("Nuclei\t\t...\t", end=' ') # ~#~#~#~ # # I n i t # # ~#~#~#~ # charge = [] coord_x = [] coord_y = [] coord_z = [] # ~#~#~#~#~#~#~ # # P a r s i n g # # ~#~#~#~#~#~#~ # for a in res.geometry: charge.append(a.charge) if res.units == 'BOHR': coord_x.append(a.coord[0]) coord_y.append(a.coord[1]) coord_z.append(a.coord[2]) else: coord_x.append(a.coord[0] / a0) coord_y.append(a.coord[1] / a0) coord_z.append(a.coord[2] / a0) # ~#~#~#~#~ # # W r i t e # # ~#~#~#~#~ # ezfio.set_nuclei_is_complex(False) ezfio.set_nuclei_nucl_num(len(res.geometry)) ezfio.set_nuclei_nucl_charge(charge) # Transformt H1 into H import re p = re.compile(r'(\d*)$') label = [p.sub("", x.name).capitalize() for x in res.geometry] ezfio.set_nuclei_nucl_label(label) ezfio.set_nuclei_nucl_coord(coord_x + coord_y + coord_z) print("OK") # _ # /\ _ _ |_) _. _ o _ # /--\ (_) _> |_) (_| _> | _> # print("AOS\t\t...\t", end=' ') # ~#~#~#~ # # I n i t # # ~#~#~#~ # at = [] num_prim = [] power_x = [] power_y = [] power_z = [] coefficient = [] exponent = [] res.convert_to_cartesian() # ~#~#~#~#~#~#~ # # P a r s i n g # # ~#~#~#~#~#~#~ # for b in res.basis: c = b.center for i, atom in enumerate(res.geometry): if atom.coord == c: at.append(i + 1) num_prim.append(len(b.prim)) s = b.sym power_x.append(str.count(s, "x")) power_y.append(str.count(s, "y")) power_z.append(str.count(s, "z")) coefficient.append(b.coef) exponent.append([p.expo for p in b.prim]) # ~#~#~#~#~ # # W r i t e # # ~#~#~#~#~ # ezfio.set_ao_basis_ao_num(len(res.basis)) ezfio.set_ao_basis_ao_nucl(at) ezfio.set_ao_basis_ao_prim_num(num_prim) ezfio.set_ao_basis_ao_power(power_x + power_y + power_z) # ~#~#~#~#~#~#~ # # P a r s i n g # # ~#~#~#~#~#~#~ # prim_num_max = ezfio.get_ao_basis_ao_prim_num_max() for i in range(len(res.basis)): coefficient[ i] += [0. for j in range(len(coefficient[i]), prim_num_max)] exponent[i] += [0. for j in range(len(exponent[i]), prim_num_max)] coefficient = reduce(lambda x, y: x + y, coefficient, []) exponent = reduce(lambda x, y: x + y, exponent, []) coef = [] expo = [] for i in range(prim_num_max): for j in range(i, len(coefficient), prim_num_max): coef.append(coefficient[j]) expo.append(exponent[j]) # ~#~#~#~#~ # # W r i t e # # ~#~#~#~#~ # ezfio.set_ao_basis_ao_coef(coef) ezfio.set_ao_basis_ao_expo(expo) ezfio.set_ao_basis_ao_basis("Read by resultsFile") print("OK") # _ # |_) _. _ o _ # |_) (_| _> | _> # print("Basis\t\t...\t", end=' ') # ~#~#~#~ # # I n i t # # ~#~#~#~ # coefficient = [] exponent = [] # ~#~#~#~#~#~#~ # # P a r s i n g # # ~#~#~#~#~#~#~ # inucl = {} for i, a in enumerate(res.geometry): inucl[a.coord] = i nbasis = 0 nucl_index = [] curr_center = -1 nucl_shell_num = [] ang_mom = [] nshell = 0 nshell_tot = 0 shell_index = [] shell_prim_num = [] for b in res.basis: s = b.sym if str.count(s, "y") + str.count(s, "x") == 0: c = inucl[b.center] nshell += 1 nshell_tot += 1 if c != curr_center: curr_center = c nucl_shell_num.append(nshell) nshell = 0 nbasis += 1 nucl_index.append(c+1) coefficient += b.coef[:len(b.prim)] exponent += [p.expo for p in b.prim] ang_mom.append(str.count(s, "z")) shell_prim_num.append(len(b.prim)) shell_index += [nshell_tot+1] * len(b.prim) # ~#~#~#~#~ # # W r i t e # # ~#~#~#~#~ # ezfio.set_basis_basis("Read from ResultsFile") ezfio.set_basis_shell_num(len(ang_mom)) ezfio.set_basis_basis_nucleus_index(nucl_index) ezfio.set_basis_prim_num(len(coefficient)) ezfio.set_basis_nucleus_shell_num(nucl_shell_num) ezfio.set_basis_prim_coef(coefficient) ezfio.set_basis_prim_expo(exponent) ezfio.set_basis_shell_ang_mom(ang_mom) ezfio.set_basis_shell_prim_num(shell_prim_num) ezfio.set_basis_shell_index(shell_index) print("OK") # _ # |\/| _ _ |_) _. _ o _ # | | (_) _> |_) (_| _> | _> # print("MOS\t\t...\t", end=' ') # ~#~#~#~ # # I n i t # # ~#~#~#~ # MoTag = res.determinants_mo_type ezfio.set_mo_basis_mo_label('Orthonormalized') MO_type = MoTag allMOs = res.mo_sets[MO_type] # ~#~#~#~#~#~#~ # # P a r s i n g # # ~#~#~#~#~#~#~ # try: closed = [(allMOs[i].eigenvalue, i) for i in res.closed_mos] active = [(allMOs[i].eigenvalue, i) for i in res.active_mos] virtual = [(allMOs[i].eigenvalue, i) for i in res.virtual_mos] except: closed = [] virtual = [] active = [(allMOs[i].eigenvalue, i) for i in range(len(allMOs))] closed = [x[1] for x in closed] active = [x[1] for x in active] virtual = [x[1] for x in virtual] MOindices = closed + active + virtual MOs = [] for i in MOindices: MOs.append(allMOs[i]) mo_num = len(MOs) while len(MOindices) < mo_num: MOindices.append(len(MOindices)) MOmap = list(MOindices) for i in range(len(MOindices)): MOmap[i] = MOindices.index(i) energies = [] for i in range(mo_num): energies.append(MOs[i].eigenvalue) OccNum = [] if res.occ_num is not None: for i in MOindices: OccNum.append(res.occ_num[MO_type][i]) else: for i in range(res.num_beta): OccNum.append(2.) for i in range(res.num_beta,res.num_alpha): OccNum.append(1.) while len(OccNum) < mo_num: OccNum.append(0.) MoMatrix = [] sym0 = [i.sym for i in res.mo_sets[MO_type]] sym = [i.sym for i in res.mo_sets[MO_type]] for i in range(len(sym)): sym[MOmap[i]] = sym0[i] MoMatrix = [] for i in range(len(MOs)): m = MOs[i] for coef in m.vector: MoMatrix.append(coef) while len(MoMatrix) < len(MOs[0].vector)**2: MoMatrix.append(0.) # ~#~#~#~#~ # # W r i t e # # ~#~#~#~#~ # ezfio.set_mo_basis_mo_num(mo_num) ezfio.set_mo_basis_mo_coef(MoMatrix) ezfio.set_mo_basis_mo_occ(OccNum) print("OK") print("Pseudos\t\t...\t", end=' ') try: lmax = 0 nucl_charge_remove = [] klocmax = 0 kmax = 0 nucl_num = len(res.geometry) for ecp in res.pseudo: lmax_local = ecp['lmax'] lmax = max(lmax_local, lmax) nucl_charge_remove.append(ecp['zcore']) klocmax = max(klocmax, len(ecp[str(lmax_local)])) for l in range(lmax_local): kmax = max(kmax, len(ecp[str(l)])) lmax = lmax-1 ezfio.set_pseudo_pseudo_lmax(lmax) ezfio.set_pseudo_nucl_charge_remove(nucl_charge_remove) ezfio.set_pseudo_pseudo_klocmax(klocmax) ezfio.set_pseudo_pseudo_kmax(kmax) pseudo_n_k = [[0 for _ in range(nucl_num)] for _ in range(klocmax)] pseudo_v_k = [[0. for _ in range(nucl_num)] for _ in range(klocmax)] pseudo_dz_k = [[0. for _ in range(nucl_num)] for _ in range(klocmax)] pseudo_n_kl = [[[0 for _ in range(nucl_num)] for _ in range(kmax)] for _ in range(lmax+1)] pseudo_v_kl = [[[0. for _ in range(nucl_num)] for _ in range(kmax)] for _ in range(lmax+1)] pseudo_dz_kl = [[[0. for _ in range(nucl_num)] for _ in range(kmax)] for _ in range(lmax+1)] for ecp in res.pseudo: lmax_local = ecp['lmax'] klocmax = len(ecp[str(lmax_local)]) atom = ecp['atom']-1 for kloc in range(klocmax): try: v, n, dz = ecp[str(lmax_local)][kloc] pseudo_n_k[kloc][atom] = n-2 pseudo_v_k[kloc][atom] = v pseudo_dz_k[kloc][atom] = dz except: pass for l in range(lmax_local): for k in range(kmax): try: v, n, dz = ecp[str(l)][k] pseudo_n_kl[l][k][atom] = n-2 pseudo_v_kl[l][k][atom] = v pseudo_dz_kl[l][k][atom] = dz except: pass ezfio.set_pseudo_pseudo_n_k(pseudo_n_k) ezfio.set_pseudo_pseudo_v_k(pseudo_v_k) ezfio.set_pseudo_pseudo_dz_k(pseudo_dz_k) ezfio.set_pseudo_pseudo_n_kl(pseudo_n_kl) ezfio.set_pseudo_pseudo_v_kl(pseudo_v_kl) ezfio.set_pseudo_pseudo_dz_kl(pseudo_dz_kl) n_alpha = res.num_alpha n_beta = res.num_beta for i in range(nucl_num): charge[i] -= nucl_charge_remove[i] ezfio.set_nuclei_nucl_charge(charge) ezfio.set_electrons_elec_alpha_num(n_alpha) ezfio.set_electrons_elec_beta_num(n_beta) except: ezfio.set_pseudo_do_pseudo(False) else: ezfio.set_pseudo_do_pseudo(True) print("OK") def get_full_path(file_path): file_path = os.path.expanduser(file_path) file_path = os.path.expandvars(file_path) # file_path = os.path.abspath(file_path) return file_path if __name__ == '__main__': ARGUMENTS = docopt(__doc__) FILE = get_full_path(ARGUMENTS['FILE']) if ARGUMENTS["--output"]: EZFIO_FILE = get_full_path(ARGUMENTS["--output"]) else: EZFIO_FILE = "{0}.ezfio".format(FILE) try: RES_FILE = getFile(FILE) except: raise else: print(FILE, 'recognized as', str(RES_FILE).split('.')[-1].split()[0]) write_ezfio(RES_FILE, EZFIO_FILE) sys.stdout.flush() if os.system("qp_run save_ortho_mos "+EZFIO_FILE) != 0: print("""Warning: You need to run qp run save_ortho_mos to be sure your MOs will be orthogonal, which is not the case when the MOs are read from output files (not enough precision in output).""")