def fcidump(wfn, fname='INTDUMP', oe_ints=None): """Save integrals to file in FCIDUMP format as defined in Comp. Phys. Commun. 54 75 (1989) Additional one-electron integrals, including orbital energies, can also be saved. This latter format can be used with the HANDE QMC code but is not standard. :returns: None :raises: ValidationError when SCF wavefunction is not RHF :type wfn: :py:class:`~psi4.core.Wavefunction` :param wfn: set of molecule, basis, orbitals from which to generate cube files :param fname: name of the integrals file, defaults to INTDUMP :param oe_ints: list of additional one-electron integrals to save to file. So far only EIGENVALUES is a valid option. :examples: >>> # [1] Save one- and two-electron integrals to standard FCIDUMP format >>> E, wfn = energy('scf', return_wfn=True) >>> fcidump(wfn) >>> # [2] Save orbital energies, one- and two-electron integrals. >>> E, wfn = energy('scf', return_wfn=True) >>> fcidump(wfn, oe_ints=['EIGENVALUES']) """ # Get some options reference = core.get_option('SCF', 'REFERENCE') ints_tolerance = core.get_global_option('INTS_TOLERANCE') # Some sanity checks if reference not in ['RHF', 'UHF']: raise ValidationError( 'FCIDUMP not implemented for {} references\n'.format(reference)) if oe_ints is None: oe_ints = [] molecule = wfn.molecule() docc = wfn.doccpi() frzcpi = wfn.frzcpi() frzvpi = wfn.frzvpi() active_docc = docc - frzcpi active_socc = wfn.soccpi() active_mopi = wfn.nmopi() - frzcpi - frzvpi nbf = active_mopi.sum() if wfn.same_a_b_orbs() else 2 * active_mopi.sum() nirrep = wfn.nirrep() nelectron = 2 * active_docc.sum() + active_socc.sum() irrep_map = _irrep_map(wfn) wfn_irrep = 0 for h, n_socc in enumerate(active_socc): if n_socc % 2 == 1: wfn_irrep ^= h core.print_out('Writing integrals in FCIDUMP format to ' + fname + '\n') # Generate FCIDUMP header header = '&FCI\n' header += 'NORB={:d},\n'.format(nbf) header += 'NELEC={:d},\n'.format(nelectron) header += 'MS2={:d},\n'.format(wfn.nalpha() - wfn.nbeta()) header += 'UHF=.{}.,\n'.format(not wfn.same_a_b_orbs()).upper() orbsym = '' for h in range(active_mopi.n()): for n in range(frzcpi[h], frzcpi[h] + active_mopi[h]): orbsym += '{:d},'.format(irrep_map[h]) if not wfn.same_a_b_orbs(): orbsym += '{:d},'.format(irrep_map[h]) header += 'ORBSYM={}\n'.format(orbsym) header += 'ISYM={:d},\n'.format(irrep_map[wfn_irrep]) header += '&END\n' with open(fname, 'w') as intdump: intdump.write(header) # Get an IntegralTransform object check_iwl_file_from_scf_type(core.get_global_option('SCF_TYPE'), wfn) spaces = [core.MOSpace.all()] trans_type = core.IntegralTransform.TransformationType.Restricted if not wfn.same_a_b_orbs(): trans_type = core.IntegralTransform.TransformationType.Unrestricted ints = core.IntegralTransform(wfn, spaces, trans_type) ints.transform_tei(core.MOSpace.all(), core.MOSpace.all(), core.MOSpace.all(), core.MOSpace.all()) core.print_out('Integral transformation complete!\n') DPD_info = { 'instance_id': ints.get_dpd_id(), 'alpha_MO': ints.DPD_ID('[A>=A]+'), 'beta_MO': 0 } if not wfn.same_a_b_orbs(): DPD_info['beta_MO'] = ints.DPD_ID("[a>=a]+") # Write TEI to fname in FCIDUMP format core.fcidump_tei_helper(nirrep, wfn.same_a_b_orbs(), DPD_info, ints_tolerance, fname) # Read-in OEI and write them to fname in FCIDUMP format # Indexing functions to translate from zero-based (C and Python) to # one-based (Fortran) mo_idx = lambda x: x + 1 alpha_mo_idx = lambda x: 2 * x + 1 beta_mo_idx = lambda x: 2 * (x + 1) with open(fname, 'a') as intdump: core.print_out('Writing frozen core operator in FCIDUMP format to ' + fname + '\n') if reference == 'RHF': PSIF_MO_FZC = 'MO-basis Frozen-Core Operator' moH = core.Matrix(PSIF_MO_FZC, wfn.nmopi(), wfn.nmopi()) moH.load(core.IO.shared_object(), psif.PSIF_OEI) mo_slice = core.Slice(frzcpi, active_mopi) MO_FZC = moH.get_block(mo_slice, mo_slice) offset = 0 for h, block in enumerate(MO_FZC.nph): il = np.tril_indices(block.shape[0]) for index, x in np.ndenumerate(block[il]): row = mo_idx(il[0][index] + offset) col = mo_idx(il[1][index] + offset) if (abs(x) > ints_tolerance): intdump.write('{:29.20E}{:4d}{:4d}{:4d}{:4d}\n'.format( x, row, col, 0, 0)) offset += block.shape[0] # Additional one-electron integrals as requested in oe_ints # Orbital energies core.print_out('Writing orbital energies in FCIDUMP format to ' + fname + '\n') if 'EIGENVALUES' in oe_ints: eigs_dump = write_eigenvalues( wfn.epsilon_a().get_block(mo_slice).to_array(), mo_idx) intdump.write(eigs_dump) else: PSIF_MO_A_FZC = 'MO-basis Alpha Frozen-Core Oper' moH_A = core.Matrix(PSIF_MO_A_FZC, wfn.nmopi(), wfn.nmopi()) moH_A.load(core.IO.shared_object(), psif.PSIF_OEI) mo_slice = core.Slice(frzcpi, active_mopi) MO_FZC_A = moH_A.get_block(mo_slice, mo_slice) offset = 0 for h, block in enumerate(MO_FZC_A.nph): il = np.tril_indices(block.shape[0]) for index, x in np.ndenumerate(block[il]): row = alpha_mo_idx(il[0][index] + offset) col = alpha_mo_idx(il[1][index] + offset) if (abs(x) > ints_tolerance): intdump.write('{:29.20E}{:4d}{:4d}{:4d}{:4d}\n'.format( x, row, col, 0, 0)) offset += block.shape[0] PSIF_MO_B_FZC = 'MO-basis Beta Frozen-Core Oper' moH_B = core.Matrix(PSIF_MO_B_FZC, wfn.nmopi(), wfn.nmopi()) moH_B.load(core.IO.shared_object(), psif.PSIF_OEI) mo_slice = core.Slice(frzcpi, active_mopi) MO_FZC_B = moH_B.get_block(mo_slice, mo_slice) offset = 0 for h, block in enumerate(MO_FZC_B.nph): il = np.tril_indices(block.shape[0]) for index, x in np.ndenumerate(block[il]): row = beta_mo_idx(il[0][index] + offset) col = beta_mo_idx(il[1][index] + offset) if (abs(x) > ints_tolerance): intdump.write('{:29.20E}{:4d}{:4d}{:4d}{:4d}\n'.format( x, row, col, 0, 0)) offset += block.shape[0] # Additional one-electron integrals as requested in oe_ints # Orbital energies core.print_out('Writing orbital energies in FCIDUMP format to ' + fname + '\n') if 'EIGENVALUES' in oe_ints: alpha_eigs_dump = write_eigenvalues( wfn.epsilon_a().get_block(mo_slice).to_array(), alpha_mo_idx) beta_eigs_dump = write_eigenvalues( wfn.epsilon_b().get_block(mo_slice).to_array(), beta_mo_idx) intdump.write(alpha_eigs_dump + beta_eigs_dump) # Dipole integrals #core.print_out('Writing dipole moment OEI in FCIDUMP format to ' + fname + '\n') # Traceless quadrupole integrals #core.print_out('Writing traceless quadrupole moment OEI in FCIDUMP format to ' + fname + '\n') # Frozen core + nuclear repulsion energy core.print_out( 'Writing frozen core + nuclear repulsion energy in FCIDUMP format to ' + fname + '\n') e_fzc = ints.get_frozen_core_energy() e_nuc = molecule.nuclear_repulsion_energy( wfn.get_dipole_field_strength()) intdump.write('{:29.20E}{:4d}{:4d}{:4d}{:4d}\n'.format( e_fzc + e_nuc, 0, 0, 0, 0)) core.print_out( 'Done generating {} with integrals in FCIDUMP format.\n'.format(fname))
def fcidump(wfn, fname='INTDUMP', oe_ints=None): """Save integrals to file in FCIDUMP format as defined in Comp. Phys. Commun. 54 75 (1989) Additional one-electron integrals, including orbital energies, can also be saved. This latter format can be used with the HANDE QMC code but is not standard. :returns: None :raises: ValidationError when SCF wavefunction is not RHF :type wfn: :py:class:`~psi4.core.Wavefunction` :param wfn: set of molecule, basis, orbitals from which to generate cube files :param fname: name of the integrals file, defaults to INTDUMP :param oe_ints: list of additional one-electron integrals to save to file. So far only EIGENVALUES is a valid option. :examples: >>> # [1] Save one- and two-electron integrals to standard FCIDUMP format >>> E, wfn = energy('scf', return_wfn=True) >>> fcidump(wfn) >>> # [2] Save orbital energies, one- and two-electron integrals. >>> E, wfn = energy('scf', return_wfn=True) >>> fcidump(wfn, oe_ints=['EIGENVALUES']) """ # Get some options reference = core.get_option('SCF', 'REFERENCE') ints_tolerance = core.get_global_option('INTS_TOLERANCE') # Some sanity checks if reference not in ['RHF', 'UHF']: raise ValidationError('FCIDUMP not implemented for {} references\n'.format(reference)) if oe_ints is None: oe_ints = [] molecule = wfn.molecule() docc = wfn.doccpi() frzcpi = wfn.frzcpi() frzvpi = wfn.frzvpi() active_docc = docc - frzcpi active_socc = wfn.soccpi() active_mopi = wfn.nmopi() - frzcpi - frzvpi nbf = active_mopi.sum() if wfn.same_a_b_orbs() else 2 * active_mopi.sum() nirrep = wfn.nirrep() nelectron = 2 * active_docc.sum() + active_socc.sum() core.print_out('Writing integrals in FCIDUMP format to ' + fname + '\n') # Generate FCIDUMP header header = '&FCI\n' header += 'NORB={:d},\n'.format(nbf) header += 'NELEC={:d},\n'.format(nelectron) header += 'MS2={:d},\n'.format(wfn.nalpha() - wfn.nbeta()) header += 'UHF=.{}.,\n'.format(not wfn.same_a_b_orbs()).upper() orbsym = '' for h in range(active_mopi.n()): for n in range(frzcpi[h], frzcpi[h] + active_mopi[h]): orbsym += '{:d},'.format(h + 1) if not wfn.same_a_b_orbs(): orbsym += '{:d},'.format(h + 1) header += 'ORBSYM={}\n'.format(orbsym) header += '&END\n' with open(fname, 'w') as intdump: intdump.write(header) # Get an IntegralTransform object check_iwl_file_from_scf_type(core.get_global_option('SCF_TYPE'), wfn) spaces = [core.MOSpace.all()] trans_type = core.IntegralTransform.TransformationType.Restricted if not wfn.same_a_b_orbs(): trans_type = core.IntegralTransform.TransformationType.Unrestricted ints = core.IntegralTransform(wfn, spaces, trans_type) ints.transform_tei(core.MOSpace.all(), core.MOSpace.all(), core.MOSpace.all(), core.MOSpace.all()) core.print_out('Integral transformation complete!\n') DPD_info = {'instance_id': ints.get_dpd_id(), 'alpha_MO': ints.DPD_ID('[A>=A]+'), 'beta_MO': 0} if not wfn.same_a_b_orbs(): DPD_info['beta_MO'] = ints.DPD_ID("[a>=a]+") # Write TEI to fname in FCIDUMP format core.fcidump_tei_helper(nirrep, wfn.same_a_b_orbs(), DPD_info, ints_tolerance, fname) # Read-in OEI and write them to fname in FCIDUMP format # Indexing functions to translate from zero-based (C and Python) to # one-based (Fortran) mo_idx = lambda x: x + 1 alpha_mo_idx = lambda x: 2 * x + 1 beta_mo_idx = lambda x: 2 * (x + 1) with open(fname, 'a') as intdump: core.print_out('Writing frozen core operator in FCIDUMP format to ' + fname + '\n') if reference == 'RHF': PSIF_MO_FZC = 'MO-basis Frozen-Core Operator' moH = core.Matrix(PSIF_MO_FZC, wfn.nmopi(), wfn.nmopi()) moH.load(core.IO.shared_object(), psif.PSIF_OEI) mo_slice = core.Slice(frzcpi, active_mopi) MO_FZC = moH.get_block(mo_slice, mo_slice) offset = 0 for h, block in enumerate(MO_FZC.nph): il = np.tril_indices(block.shape[0]) for index, x in np.ndenumerate(block[il]): row = mo_idx(il[0][index] + offset) col = mo_idx(il[1][index] + offset) if (abs(x) > ints_tolerance): intdump.write('{:29.20E} {:4d} {:4d} {:4d} {:4d}\n'.format(x, row, col, 0, 0)) offset += block.shape[0] # Additional one-electron integrals as requested in oe_ints # Orbital energies core.print_out('Writing orbital energies in FCIDUMP format to ' + fname + '\n') if 'EIGENVALUES' in oe_ints: eigs_dump = write_eigenvalues(wfn.epsilon_a().get_block(mo_slice).to_array(), mo_idx) intdump.write(eigs_dump) else: PSIF_MO_A_FZC = 'MO-basis Alpha Frozen-Core Oper' moH_A = core.Matrix(PSIF_MO_A_FZC, wfn.nmopi(), wfn.nmopi()) moH_A.load(core.IO.shared_object(), psif.PSIF_OEI) mo_slice = core.Slice(frzcpi, active_mopi) MO_FZC_A = moH_A.get_block(mo_slice, mo_slice) offset = 0 for h, block in enumerate(MO_FZC_A.nph): il = np.tril_indices(block.shape[0]) for index, x in np.ndenumerate(block[il]): row = alpha_mo_idx(il[0][index] + offset) col = alpha_mo_idx(il[1][index] + offset) if (abs(x) > ints_tolerance): intdump.write('{:29.20E} {:4d} {:4d} {:4d} {:4d}\n'.format(x, row, col, 0, 0)) offset += block.shape[0] PSIF_MO_B_FZC = 'MO-basis Beta Frozen-Core Oper' moH_B = core.Matrix(PSIF_MO_B_FZC, wfn.nmopi(), wfn.nmopi()) moH_B.load(core.IO.shared_object(), psif.PSIF_OEI) mo_slice = core.Slice(frzcpi, active_mopi) MO_FZC_B = moH_B.get_block(mo_slice, mo_slice) offset = 0 for h, block in enumerate(MO_FZC_B.nph): il = np.tril_indices(block.shape[0]) for index, x in np.ndenumerate(block[il]): row = beta_mo_idx(il[0][index] + offset) col = beta_mo_idx(il[1][index] + offset) if (abs(x) > ints_tolerance): intdump.write('{:29.20E} {:4d} {:4d} {:4d} {:4d}\n'.format(x, row, col, 0, 0)) offset += block.shape[0] # Additional one-electron integrals as requested in oe_ints # Orbital energies core.print_out('Writing orbital energies in FCIDUMP format to ' + fname + '\n') if 'EIGENVALUES' in oe_ints: alpha_eigs_dump = write_eigenvalues(wfn.epsilon_a().get_block(mo_slice).to_array(), alpha_mo_idx) beta_eigs_dump = write_eigenvalues(wfn.epsilon_b().get_block(mo_slice).to_array(), beta_mo_idx) intdump.write(alpha_eigs_dump + beta_eigs_dump) # Dipole integrals #core.print_out('Writing dipole moment OEI in FCIDUMP format to ' + fname + '\n') # Traceless quadrupole integrals #core.print_out('Writing traceless quadrupole moment OEI in FCIDUMP format to ' + fname + '\n') # Frozen core + nuclear repulsion energy core.print_out('Writing frozen core + nuclear repulsion energy in FCIDUMP format to ' + fname + '\n') e_fzc = ints.get_frozen_core_energy() e_nuc = molecule.nuclear_repulsion_energy(wfn.get_dipole_field_strength()) intdump.write('{: 29.20E} {:4d} {:4d} {:4d} {:4d}\n'.format(e_fzc + e_nuc, 0, 0, 0, 0)) core.print_out('Done generating {} with integrals in FCIDUMP format.\n'.format(fname))