Ejemplo n.º 1
0
def o_orbital_symmetries(file='output.dat'):
    #gives occupied orbital symmetries from a specified output file
    with open(file, 'r') as f:
        output = f.read()
    f = open(file)
    lines = f.readlines()
    section = lines[sedre.Parser(program='qchem', filename=file).
                    data['sections']['TDDFT']['occ_orbitals']['hits'][0][0]:
                    sedre.Parser(program='qchem', filename=file).
                    data['sections']['TDDFT']['occ_orbitals']['hits'][0][1]]
    cleaner_section = ''.join(section)
    return clean_orbital_list(cleaner_section, file)
Ejemplo n.º 2
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def clean_orbital_list(section, file='output.dat'):
    #takes a section found by sedre and returns a list of orbital symmetries
    if sedre.Parser(program='qchem', filename=file
                    ).data['properties']['TDDFT']['pg']['vals'][0][0] == 'C1':
        return None
    else:
        lst1 = section.split('\n')
        lst2 = []
        for item in lst1:
            for i in range(len(item.split())):
                lst2.append(item.split()[i])
        lst3 = []
        lst4 = []
        lst5 = []
        for item in lst2:
            if item.strip(' -') == '':
                continue
            else:
                lst3.append(item)
        for item in lst3:
            if item == '':
                continue
            else:
                lst5.append(item)
        for item in lst5:
            for i in range(len(item)):
                if item[0] in [
                        '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'V',
                        '-'
                ]:
                    continue
                else:
                    lst4.append(item)
                    break
        return lst4
Ejemplo n.º 3
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    def test1(self):
        test_parser = sedre.Parser()
        test_parser.content['str'] =\
         """Lorem ipsum dolor sit amet, consectetur 
			adipiscing elit, sed do eiusmod tempor incididunt 
			ut labore et dolore magna aliqua. Ut enim ad minim 
			veniam, quis nostrud exercitation ullamco laboris 
			nisi ut aliquip ex ea commodo consequat. Duis aute 
			irure dolor in reprehenderit in voluptate velit esse 
			cillum dolore eu fugiat nulla pariatur. Excepteur 
			sint occaecat cupidatat non proident, 
			sunt in culpa qui officia deserunt mollit anim 
			id est laborum."""
        o = test_parser.look_for('Lorem')
        self.assertEqual(o, ['Lorem'])
Ejemplo n.º 4
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def func():
    myp = sedre.Parser(program='psi4', filename='./data/test_psi4_opt.dat')
    return myp.data['properties']['opt']['iteration']['vals'][0]
Ejemplo n.º 5
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def func():
    myp = sedre.Parser(program='psi4', filename='./data/test_load.dat')
    return myp.data['energy']['HF']['raw']['vals'][0][0]
Ejemplo n.º 6
0
def orbTest():
    myp = sedre.Parser(program='qchem',
                       filename='data/qchem_orbital_eigenvalue.dat')
    eigs = myp.data['properties']['orbitals']['alpha']['occ']['e']['vals'][0]
    return eigs
Ejemplo n.º 7
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def func():
    myp = sedre.Parser(program='molpro', filename='data/test_molpro_rhf.dat')
    return myp.data['energy']['RHF']['raw']['vals'][0]
Ejemplo n.º 8
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def return_trans_sym(file='output.dat'):
    # returns a list of transition symmetries from a qchem TDDFT output.dat file in order of increasing excitation energies

    # if the molecule is C1, all transitions are of A symmetry...
    # this will return a list of As of the appropriate length
    # if the point group is detected to be C1
    if sedre.Parser(program='qchem', filename=file
                    ).data['properties']['TDDFT']['pg']['vals'][0][0] == 'C1':
        return ['A'] * len(
            sedre.Parser(
                program='qchem',
                filename=file).data['energy']['TDDFT']['exc']['vals'][0])
    else:
        lst_1 = []
        lst_2 = []
        lst_3 = []
        lst4 = []
        property_list = []

        # read the file and temporarily save the lines
        with open(file, 'r') as f:
            output = f.read()
        f = open(file)
        lines = f.readlines()

        # iterate through each line in lines
        # remove extraneous spaces
        # append cleaned line to lst_1
        for line in list(lines):
            new_line = line.strip(' ')
            lst_1.append(new_line)

        # iterate through each cleaned line in lst_1
        # append the line 5 lines after any line that contains the word 'Excited' to lst_2
        # (this is the line that contains the D() --> V() information)
        for i in range(len(lst_1)):
            if 'Excited' in lst_1[i].split(' '):
                lst_2.append(lst_1[i + 5])

        # finds the point group of the molecule with sedre in the output.dat file
        # uses sedre functions to get the symmetries of the occupied, virtual, and all orbitals
        pg = sedre.Parser(
            program='qchem',
            filename=file).data['properties']['TDDFT']['pg']['vals'][0][0]
        occ_orb_sym = sedre.o_orbital_symmetries(file)
        vir_orb_sym = sedre.v_orbital_symmetries(file)
        all_orb_sym = sedre.orbital_symmetries(file)

        # grabs the orbital numbers from D(m) --> V(n) line
        # remove extraneous spaces
        # append orbital numbers m, n to lst_3
        for item in lst_2:
            orbitals = [
                int((item[2] + item[3] + item[4]).strip(' ')),
                int((item[13] + item[14] + item[15]).strip(' '))
            ]
            lst_3.append(orbitals)

        # re-indexes the orbital numbers so that each orbital has a unique number
        # virtual orbitals start at ('number of occupied orbitals' + 1)
        for i in range(len(lst_3)):
            num_occ_orb = len(occ_orb_sym)
            new_item = [int(lst_3[i][0]), int(lst_3[i][1]) + num_occ_orb]
            lst4.append(new_item)

        # appends the symmetries of the origin orbital, destination orbital,
        # and transition (product of the previous two symmetries)
        for i in range(len(lst4)):
            lst4[i].append(all_orb_sym[int(lst4[i][0]) - 1])
            lst4[i].append(all_orb_sym[int(lst4[i][1]) - 1])
            lst4[i].append(sedre.reduction_formula(pg, lst4[i][2], lst4[i][3]))
            property_list.append(lst4[i][4])
        return property_list
Ejemplo n.º 9
0
def ParserLoad():
    myp = sedre.Parser(filename='./data/test_load.dat')
    myp.program = 'psi4'
    myp.psi4()
    myp.load()
    return len(myp.content['list'])
Ejemplo n.º 10
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def func():
    myp = sedre.Parser(program='psi4',filename='./data/psi4_freq.dat')
    return myp.data['properties']['freq']['entry']['vals'][0]
Ejemplo n.º 11
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    "o": 8,
    "f": 9,
    "ne": 10
}

freq_rstr = "Freq \[cm\^-1\]" + space + canynum + space + canynum + space + canynum
rmass_rstr = "Reduced mass \[u\]" + space + canynum + space + canynum + space + canynum
frc_rstr = "Force const \[mDyne/A\]" + space + canynum + space + canynum + space + canynum
int_rstr = "IR activ \[km/mol\]" + space + canynum + space + canynum + space + canynum
disp_rstr = "\s+[0-9]   " + "([A-Za-z]+)" + (space + canynum + space +
                                             canynum + space + canynum) * 3
geom_rstr = "([A-Z]|[A-Z][A-Z])" + (space + canynum) * 3

with open('output.dat', 'r') as f:
    cont = f.read()
myp = sedre.Parser(program="psi4")
geom = myp.data['properties']['GEOM']['cart']['vals'][-1]
freq = re.findall(freq_rstr, cont)
rmass = re.findall(rmass_rstr, cont)
frc = re.findall(frc_rstr, cont)
intens = re.findall(int_rstr, cont)
disps = re.findall(disp_rstr, cont)
natom = len(geom)
ostr = ""
ostr += header
ostr += compline
ostr += input_orientation
for idx, atom in enumerate(geom):
    num = atlookup[atom[0].strip().lower()]
    ostr += gline.format(idx + 1, num, 0, *atom[1:])
ostr += sep