Exemplo n.º 1
0
    def testAll(self):
        with open('symmetry_data.json') as f:
            data = json.load(f)
        messages = [
            'Expected external symmetry: {}, calculated: {}',
            'Expected internal symmetry: {}, calculated: {}',
            'Expected number of single events symmetry: {}, calculated: {}',
        ]
        for name in data:
            par = Parameters()
            qc = QuantumChemistry(par)
            mol = StationaryPoint(name, 0, 1, smiles=name)
            mol.characterize()
            kinbot.symmetry.calculate_symmetry(mol)

            sigma_int = 1
            for row in mol.sigma_int:
                for at in row:
                    sigma_int *= at
            calc = [mol.sigma_ext, sigma_int, mol.nopt]

            for i in range(3):
                cal = calc[i]
                exp = data[name]['expected_values'][i]
                self.assertEqual(exp, cal,
                                 name + ': ' + messages[i].format(exp, cal))
Exemplo n.º 2
0
 def testDihedralChangeHeptyl(self):
     """
     The generation of ring conformers requires qc calculations and is therefore slow!
     """
     if not os.path.exists('conf/'):
         os.mkdir('conf/')
     par = Parameters()
     qc = QuantumChemistry(par)
     smi = '[CH2]CCCCC'
     mol = StationaryPoint(smi, 0, 2, smiles=smi)
     mol.characterize()
     changes = [
         [0, 3, 4, 5, 25.],
         [3, 4, 5, 6, 25.],
         [4, 5, 6, 7, 25.],
         [5, 6, 7, 16, 25.],
     ]
     name = 'hexyl_dihedral'
     success, new_geom = kinbot.modify_geom.modify_coordinates(
         mol,
         name,
         mol.geom,
         changes,
         mol.bond,
         write_files=self.write_files)
Exemplo n.º 3
0
    def testAll(self):
        data = {
            'CC': [1, 0],
            'CCC': [2, 0],
            'CCCC': [3, 1],
            'C=C': [0, 0],
            'C=CC': [1, 0],
            'C=C[CH2]': [0, 0],
            'CC=C[CH2]': [1, 0],
            'C1CCCC1': [0, 0],
            'CO': [1, 0],
            'C=CO': [1, 1],
        }

        for name in data:
            par = Parameters()
            qc = QuantumChemistry(par)
            mol = StationaryPoint(name, 0, 1, smiles=name)
            mol.characterize()

            hir_exp = data[name][0]
            conf_exp = data[name][1]
            hir_calc = len(mol.dihed)
            conf_calc = len(mol.conf_dihed)
            self.assertEqual(
                hir_exp, hir_calc,
                name + ': HIR, expected: {}, calculated: {}'.format(
                    hir_exp, hir_calc))
            self.assertEqual(
                conf_exp, conf_calc,
                name + ': CONF, expected: {}, calculated: {}'.format(
                    conf_exp, conf_calc))
Exemplo n.º 4
0
    def testAll(self):
        with open('multimolecular_data.json') as f:
            data = json.load(f)
        for name in data:
            print name
            par = Parameters()
            qc = QuantumChemistry(par)
            structure = data[name]['structure']
            mol = StationaryPoint(name,0,1,structure = structure)
            mol.characterize()

            mols = mol.start_multi_molecular()
            calculated = len(mols)
            expected = data[name]['expected_value']
            self.assertEqual(calculated,expected, name + ': expected: {}, calculated: {}'.format(expected,calculated))
Exemplo n.º 5
0
    def testAll(self):
        data = {"C1=CC=CC=C1":2,
            "C1=CC=C(C)C=C1":2,
            "C=C[CH2]":2,
            "C=C=C":1,
            "C#C[CH2]":2,
            "S=S":1,
            "O=S=C":1,
            "O=S(C)[CH2]":3,
            "C1CC=CC=C1":1
            }

        for name in data:
            par = Parameters()
            qc = QuantumChemistry(par)
            mol = StationaryPoint(name,0,1,smiles = name)
            mol.characterize()

            cal = len(mol.bonds)
            exp = data[name]
            self.assertEqual(exp ,cal ,name + ': expected: {}, calculated: {}'.format(exp,cal))
Exemplo n.º 6
0
 def testBondChangeEthane(self):
     """
     The generation of a longer C-C bond in ethane
     """
     if not os.path.exists('conf/'):
         os.mkdir('conf/')
     par = Parameters()
     qc = QuantumChemistry(par)
     smi = 'CC'
     mol = StationaryPoint(smi, 0, 1, smiles=smi)
     mol.characterize()
     changes = [
         [0, 1, 1.8],
     ]
     name = 'ethane_bond_length_test'
     success, new_geom = kinbot.modify_geom.modify_coordinates(
         mol,
         name,
         mol.geom,
         changes,
         mol.bond,
         write_files=self.write_files)
Exemplo n.º 7
0
def main():
    try:
        input_file = sys.argv[1]
    except IndexError:
        print('To use KinBot, supply one argument being the input file!')
        sys.exit(-1)

    # print the license message to the console
    print(license_message.message)

    # initialize the parameters for this run
    masterpar = Parameters(input_file)
    par = masterpar.par
    input_file = masterpar.input_file
    # set up the logging environment
    if par['verbose']:
        logging.basicConfig(filename='kinbot.log', level=logging.DEBUG)
    else:
        logging.basicConfig(filename='kinbot.log', level=logging.INFO)

    # write the license message to the log file
    logging.info(license_message.message)
    logging.info('Input parameters')
    for param in par:
        logging.info('{} {}'.format(param, par[param]))
    # time stamp of the KinBot start
    logging.info('Starting KinBot at {}'.format(datetime.datetime.now()))

    # Make the necessary directories
    if not os.path.exists('perm'):
        os.makedirs('perm')
    if not os.path.exists('scratch'):
        os.makedirs('scratch')
    if not os.path.exists(par['single_point_qc']):
        os.mkdir(par['single_point_qc'])
    if par['rotor_scan'] == 1:
        if not os.path.exists('hir'):
            os.mkdir('hir')
        if not os.path.exists('hir_profiles'):
            os.mkdir('hir_profiles')
        if not os.path.exists('perm/hir/'):
            os.makedirs('perm/hir/')
    if par['conformer_search'] == 1:
        if not os.path.exists('conf'):
            os.mkdir('conf')
        if not os.path.exists('perm/conf'):
            os.makedirs('perm/conf')
    if not os.path.exists('me'):
        os.mkdir('me')

    # initialize the reactant
    well0 = StationaryPoint('well0',
                            par['charge'],
                            par['mult'],
                            smiles=par['smiles'],
                            structure=par['structure'])
    well0.short_name = 'w1'
    # write the initial reactant geometry to a file for visualization
    geom_out = open('geometry.xyz', 'w')
    geom_out.write('{}\n\n'.format(well0.natom))
    for i, at in enumerate(well0.atom):
        x, y, z = well0.geom[i]
        geom_out.write('{} {:.6f} {:.6f} {:.6f}\n'.format(at, x, y, z))
    geom_out.write('\n\n')
    geom_out.close()

    # characterize the initial reactant
    well0.characterize(dimer=par['dimer'])
    well0.name = str(well0.chemid)
    start_name = well0.name

    # initialize the qc instance
    qc = QuantumChemistry(par)
    # only run filecopying if PES is turned on
    # if par['pes']:
    # check if this well was calcualted before in another directory
    # this flag indicates that this kinbot run
    # should wait for the information from another
    # kinbot run to become available and copy the necessary information
    #    wait_for_well = 1
    #    while wait_for_well:
    #        wait_for_well = filecopying.copy_from_database_folder(well0.chemid, well0.chemid, qc)
    #        if wait_for_well:
    #            time.sleep(1)

    # start the initial optimization of the reactant
    logging.info('Starting optimization of intial well')
    qc.qc_opt(well0, well0.geom)
    err, well0.geom = qc.get_qc_geom(str(well0.chemid) + '_well',
                                     well0.natom,
                                     wait=1)
    err, well0.freq = qc.get_qc_freq(str(well0.chemid) + '_well',
                                     well0.natom,
                                     wait=1)
    if err < 0:
        logging.error('Error with initial structure optimization.')
        return
    if any(well0.freq[i] <= 0 for i in range(len(well0.freq))):
        logging.error('Found imaginary frequency for initial structure.')
        return

    # characterize again and look for differences
    well0.characterize(dimer=par['dimer'])
    well0.name = str(well0.chemid)
    if well0.name != start_name:
        logging.error(
            'The first well optimized to a structure different from the input.'
        )
        return

    # do an MP2 optimization of the reactant,
    # to compare some scan barrier heigths to
    if par['families'] == ['all'] or \
            'birad_recombination_R' in par['families'] or \
            'r12_cycloaddition' in par['families'] or \
            'r14_birad_scission' in par['families'] or \
            'R_Addition_MultipleBond' in par['families'] or \
            (par['skip_families'] != ['none'] and \
            ('birad_recombination_R' not in par['skip_families'] or \
            'r12_cycloaddition' not in par['skip_families'] or \
            'r14_birad_scission' not in par['skip_families'] or \
            'R_Addition_MultipleBond' not in par['skip_families'])) or \
            par['reaction_search'] == 0:
        logging.info('Starting MP2 optimization of intial well')
        qc.qc_opt(well0, well0.geom, mp2=1)
        err, geom = qc.get_qc_geom(
            str(well0.chemid) + '_well_mp2', well0.natom, 1)

    # comparison for barrierless scan
    if par['barrierless_saddle']:
        logging.info(
            'Optimization of intial well for barrierless at {}/{}'.format(
                par['barrierless_saddle_method'],
                par['barrierless_saddle_basis']))
        qc.qc_opt(well0, well0.geom, bls=1)
        err, geom = qc.get_qc_geom(
            str(well0.chemid) + '_well_bls', well0.natom, 1)

    # characterize again and look for differences
    well0.characterize(dimer=par['dimer'])
    well0.name = str(well0.chemid)

    err, well0.energy = qc.get_qc_energy(str(well0.chemid) + '_well', 1)
    err, well0.zpe = qc.get_qc_zpe(str(well0.chemid) + '_well', 1)

    well_opt = Optimize(well0, par, qc, wait=1)
    well_opt.do_optimization()
    if well_opt.shigh == -999:
        logging.error(
            'Error with high level optimization of initial structure.')
        return

    if par['pes']:
        filecopying.copy_to_database_folder(well0.chemid, well0.chemid, qc)

    if par['reaction_search'] == 1:
        logging.info('Starting reaction searches of intial well')
        rf = ReactionFinder(well0, par, qc)
        rf.find_reactions()
        rg = ReactionGenerator(well0, par, qc, input_file)
        rg.generate()

    if par['homolytic_scissions'] == 1:
        logging.info('Starting the search for homolytic scission products')
        well0.homolytic_scissions = HomolyticScissions(well0, par, qc)
        well0.homolytic_scissions.find_homolytic_scissions()

    if par['me'] > 0:  # it will be 2 for kinbots when the mess file is needed but not run
        mess = MESS(par, well0)
        mess.write_input(qc)

        if par['me'] == 1:
            logging.info('Starting Master Equation calculations')
            if par['me_code'] == 'mess':
                mess.run()

    postprocess.createSummaryFile(well0, qc, par)
    postprocess.createPESViewerInput(well0, qc, par)
    postprocess.creatMLInput(well0, qc, par)

    logging.info('Finished KinBot at {}'.format(datetime.datetime.now()))
    print("Done!")
Exemplo n.º 8
0
def main():
    try:
        input_file = sys.argv[1]
    except IndexError:
        print('To use KinBot, supply one argument being the input file!')
        sys.exit(-1)

    # print the license message to the console
    print(license_message.message)

    # initialize the parameters for this run
    par = Parameters(input_file)

    # set up the logging environment
    if par.par['verbose']:
        logging.basicConfig(filename='kinbot.log', level=logging.DEBUG)
    else:
        logging.basicConfig(filename='kinbot.log', level=logging.INFO)

    # write the license message to the log file
    logging.info(license_message.message)
    # time stamp of the KinBot start
    logging.info('Starting KinBot at {}'.format(datetime.datetime.now()))

    # Make the necessary directories
    if not os.path.exists('perm'):
        os.makedirs('perm')
    if not os.path.exists('scratch'):
        os.makedirs('scratch')
    if not os.path.exists(par.par['single_point_qc']):
        os.mkdir(par.par['single_point_qc'])
    if par.par['rotor_scan'] == 1:
        if not os.path.exists('hir'):
            os.mkdir('hir')
        if not os.path.exists('hir_profiles'):
            os.mkdir('hir_profiles')
        if not os.path.exists('perm/hir/'):
            os.makedirs('perm/hir/')
    if par.par['conformer_search'] == 1:
        if not os.path.exists('conf'):
            os.mkdir('conf')
        if not os.path.exists('perm/conf'):
            os.makedirs('perm/conf')
    if not os.path.exists('me'):
        os.mkdir('me')


    if par.par['pes'] and par.par['specific_reaction']:
        logging.error('Specific reaction cannot be searched in PES mode.')
        return

    # initialize the reactant
    well0 = StationaryPoint('well0',
                            par.par['charge'],
                            par.par['mult'],
                            smiles=par.par['smiles'],
                            structure=par.par['structure'])
    well0.short_name = 'w1'

    # wrtie the initial reactant geometry to a file for visualization
    geom_out = open('geometry.xyz', 'w')
    geom_out.write('{}\n\n'.format(well0.natom))
    for i, at in enumerate(well0.atom):
        x, y, z = well0.geom[i]
        geom_out.write('{} {:.6f} {:.6f} {:.6f}\n'.format(at, x, y, z))
    geom_out.write('\n\n')
    geom_out.close()

    # characterize the initial reactant
    well0.characterize(par.par['dimer'])
    well0.name = str(well0.chemid)
    start_name = well0.name

    # initialize the qc instance
    qc = QuantumChemistry(par)

    # start the initial optimization of the reactant
    logging.info('Starting optimization of intial well')
    qc.qc_opt(well0, well0.geom)
    err, well0.geom = qc.get_qc_geom(str(well0.chemid) + '_well',
                                     well0.natom, wait=1)
    err, well0.freq = qc.get_qc_freq(str(well0.chemid) + '_well',
                                     well0.natom, wait=1)
    if err < 0:
        logging.error('Error with initial structure optimization.')
        return
    if any(well0.freq[i] <= 0 for i in range(len(well0.freq))):
        logging.error('Found imaginary frequency for initial structure.')
        return

    # characterize again and look for differences
    well0.characterize(par.par['dimer'])
    well0.name = str(well0.chemid)
    if well0.name != start_name:
        logging.error('The first well optimized to a structure different from the input.')
        return

    # do an MP2 optimization of the reactant,
    # to compare Beta scission barrier heigths to
    logging.info('Starting MP2 optimization of intial well')
    qc.qc_opt(well0, well0.geom, mp2=1)
    err, geom = qc.get_qc_geom(str(well0.chemid) + '_well_mp2', well0.natom, 1)

    # characterize again and look for differences
    well0.characterize(par.par['dimer'])
    well0.name = str(well0.chemid)

    # read the energy and the zpe corrected energy
    err, well0.energy = qc.get_qc_energy(str(well0.chemid) + '_well', 1)
    err, well0.zpe = qc.get_qc_zpe(str(well0.chemid) + '_well', 1)

    well_opt = Optimize(well0, par, qc, wait=1)
    well_opt.do_optimization()
    if well_opt.shigh == -999:
        logging.error('Error with high level optimization of initial structure.')
        return

    # do the reaction search using heuristics
    if par.par['reaction_search'] == 1:
        logging.info('Starting reaction searches of intial well')
        rf = ReactionFinder(well0, par, qc)
        rf.find_reactions()
        rg = ReactionGenerator(well0, par, qc)
        rg.generate()
    # do the homolytic scission products search
    if par.par['homolytic_scissions'] == 1:
        logging.info('Starting the search for homolytic scission products')
        well0.homolytic_scissions = HomolyticScissions(well0, par, qc)
        well0.homolytic_scissions.find_homolytic_scissions()
    # initialize the master equation instance
    mess = MESS(par, well0)
    mess.write_input()
    mesmer = MESMER(par, well0)
    mesmer.write_input()
    if par.par['me'] == 1:
        logging.info('Starting Master Equation calculations')
        if par.par['me_code'] == 'mess':
            mess.run()
        elif par.par['me_code'] == 'mesmer':
            mesmer.run()
        else:
            logging.error('Cannot recognize me code {}'.format(par.par['me_code']))

    # postprocess the calculations
    postprocess.createSummaryFile(well0, qc, par)
    postprocess.createPESViewerInput(well0, qc, par)
    postprocess.creatMLInput(well0, qc, par)

    logging.info('Finished KinBot at {}'.format(datetime.datetime.now()))
    print("Done!")