Esempio n. 1
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def parse_all(input_file):
    contents = open(input_file).read()
    time = None
    if 'Normal termination of Gaussian 09' not in contents:
        pass
    else:
        m = re.search(
            'Job cpu time: +(\S+) +days +(\S+) +hours +(\S+) +minutes +(\S+) +seconds',
            contents)
        time = float(m.group(1)) * 24 * 60 * 60 + float(
            m.group(2)) * 60 * 60 + float(m.group(3)) * 60 + float(m.group(4))

    energies = []
    atom_frames = []
    start = 0
    while True:
        try:
            start = contents.index('SCF Done', start)
            energy_this_step = float(
                re.search('SCF Done: +\S+ += +(\S+)',
                          contents[start:]).group(1))
            start = contents.find('Input orientation:', start)
            next_coordinates = contents.index('Coordinates (Angstroms)', start)
        except:
            break
        start = contents.index('---\n', next_coordinates) + 4
        end = contents.index('\n ---', start)
        lines = contents[start:end].splitlines()
        start = end

        atoms = []
        for line in lines:
            columns = line.split()
            element = columns[1]
            x, y, z = columns[3:6]
            atoms.append(
                utils.Atom(element=element, x=float(x), y=float(y),
                           z=float(z)))
        atom_frames.append(atoms)
        energies.append(energy_this_step)

    return energies, atom_frames, time
Esempio n. 2
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def read_cml(name, parameter_file='oplsaa.prm', extra_parameters={}, test_charges=True, allow_errors=False, pair_style='lj/cut'):
	if not name.endswith('.cml'):
		name += '.cml'
	tree = xml.parse(name)
	root = tree.getroot()

	# If periodic box information was passed to cml file, first root is the periodic box
	# If no periodic box info, first root is atomArray
	# Fill appropriate section when it is found
	atoms, bonds, angles, dihedrals = [], [], [], []

	for child in root:
		# Skip crystal information
		if child.tag == 'crystal':
			continue

		# Add atoms
		if child.tag == 'atomArray':
			for atom in child:
				a = utils.Atom( element=atom.attrib['elementType'], x=float(atom.attrib['x3']), y=float(atom.attrib['y3']), z=float(atom.attrib['z3']) )
				a.bonded = []
				a.index = int(atom.attrib['id'][1:])
				#if 'formalCharge' in atom.attrib:
				#	a.type_index = int(atom.attrib['formalCharge'])
				if 'label' in atom.attrib:
					a.type_index = int(atom.attrib['label'])
				atoms.append(a)

		# Add atoms
		if child.tag == 'bondArray':
			for bond in child:
				a, b = [int(n[1:]) for n in bond.attrib['atomRefs2'].split()]
				bonds.append( utils.Bond(atoms[a-1],atoms[b-1]) )
				atoms[a-1].bonded.append( atoms[b-1] )
				atoms[b-1].bonded.append( atoms[a-1] )
			angles, dihedrals = utils.get_angles_and_dihedrals(atoms)

	if parameter_file:
		atoms, bonds, angles, dihedrals = set_forcefield_parameters(atoms, bonds=bonds, angles=angles, dihedrals=dihedrals, name=name, parameter_file=parameter_file, extra_parameters=extra_parameters, test_charges=test_charges, allow_errors=allow_errors, pair_style=pair_style)

	return atoms, bonds, angles, dihedrals
Esempio n. 3
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def read_xyz(name):
	if not name.endswith('.xyz') and '.' not in name:
		name += '.xyz'
	lines = open(name).readlines()
	atom_count = int(lines[0].split()[0])
	lines_by_frame = [ lines[i:i+atom_count+2] for i in range(0,len(lines),atom_count+2) ]

	frames = []
	for frame in lines_by_frame:
		atoms = []
		for line in frame[2:]:
			columns = line.split()
			if len(columns)>=4:
				x,y,z = [float(s) for s in columns[1:4]]
				atoms.append( utils.Atom(element=columns[0], x=x, y=y, z=z, index=len(atoms)+1) )
		if len(atoms)>0: frames.append(atoms)

	if len(frames)==1:
		return frames[0]
	else:
		return frames
Esempio n. 4
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def parse_scan(input_file):
    contents = open(input_file).read()
    if 'Normal termination of Gaussian 09' not in contents:
        return None
    scan_steps = contents.split('on scan point')
    energy_list = []
    atoms_list = []

    scan_steps = [
        scan_steps[i] for i in range(1,
                                     len(scan_steps) - 1)
        if scan_steps[i][:10].split()[0] != scan_steps[i + 1][:10].split()[0]
    ]
    #print [int(s[:10].split()[0]) for s in scan_steps]
    #print len(scan_steps)

    for scan_step in scan_steps:
        energy_line = scan_step[scan_step.rindex('SCF Done'):scan_step.
                                index('\n', scan_step.rindex('SCF Done'))]
        energy = float(
            re.search('SCF Done: +\S+ += +(\S+)', energy_line).group(1))

        last_coordinates = scan_step.rindex('Coordinates (Angstroms)')

        start = scan_step.index('---\n', last_coordinates) + 4
        end = scan_step.index('\n ---', start)
        atoms = []
        for line in scan_step[start:end].splitlines():
            columns = line.split()
            element = columns[1]
            x, y, z = [float(s) for s in columns[3:6]]
            atoms.append(
                utils.Atom(element=utils.elements_by_atomic_number[int(
                    columns[1])],
                           x=x,
                           y=y,
                           z=z))
        energy_list.append(energy)
        atoms_list.append(atoms)
    return energy_list, atoms_list
Esempio n. 5
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def inp_to_xyz(name, write=False, outName=None):
	warn(
		"this function is not used and will be removed soon.",
		DeprecationWarning
	)
	data = open("gaussian/"+name+".inp",'r').read().split('\n')

	# Get start of data
	for i,s in enumerate(data):
		try:
			if(s.split()[0]=='run'): break
		except:
			pass
	i += 3

	# Get end of data
	for j,s in enumerate(data[i:]):
		if s == '': break

	data = data[i:j+i]

	if write:
		if outName == None: f = open('inp_'+name+'.xyz','w')
		else: f = open(outName,'w')
		f.write(str(len(data))+'\n')
		f.write('Atoms'+'\n')
		for s in data: f.write(s+'\n')
		f.write('\n')
		f.close()

	atoms = []
	for i,d in enumerate(data):
		d = d.split()
		atoms.append(utils.Atom(element=d[0], x=float(d[1]), y=float(d[2]), z=float(d[3]), index=i))

	return atoms
Esempio n. 6
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def parse_atoms(input_file,
                get_atoms=True,
                get_energy=True,
                check_convergence=True,
                get_time=False,
                counterpoise=False):
    if input_file[-4:] != '.log':
        input_file = 'gaussian/' + input_file + '.log'

    contents = open(input_file).read()
    if check_convergence and get_energy and 'Normal termination of Gaussian 09' not in contents:
        return None

    if 'Summary of Optimized Potential Surface Scan' in contents:
        end_section = contents[
            contents.rindex('Summary of Optimized Potential Surface Scan'):]
        energy_lines = re.findall('Eigenvalues -- ([^\\n]+)', end_section)
        energy = [
            float(s) for line in energy_lines
            for s in re.findall('-[\d]+\.[\d]+', line)
        ]

        minima = re.split('Stationary point found', contents)
        atoms = []
        for m in minima[1:]:
            coordinates = m.index('Coordinates (Angstroms)')

            start = m.index('---\n', coordinates) + 4
            end = m.index('\n ---', start)
            atoms.append([])
            for line in m[start:end].splitlines():
                columns = line.split()
                element = columns[1]
                x, y, z = [float(s) for s in columns[3:6]]
                atoms[-1].append(
                    utils.Atom(element=utils.elements_by_atomic_number[int(
                        columns[1])],
                               x=x,
                               y=y,
                               z=z,
                               index=len(atoms[-1]) + 1))

        if get_energy:
            return energy, atoms

    elif get_energy:
        if ' MP2/' in contents:  # MP2 files don't have just SCF energy
            energy = float(
                re.findall('EUMP2 = +(\S+)', contents)[-1].replace('D', 'e'))
        elif ' CCSD/' in contents:
            energy = float(re.findall('E\(CORR\)= +(\S+)', contents)[-1])
        else:
            if not counterpoise:
                try:
                    energy_line = contents[
                        contents.rindex('SCF Done'):contents.
                        index('\n', contents.rindex('SCF Done'))]
                except ValueError:
                    raise Exception('No SCF for ' + input_file)
                energy = float(
                    re.search('SCF Done: +\S+ += +(\S+)',
                              energy_line).group(1))
            else:
                energy = float(
                    re.findall('Counterpoise: corrected energy = +(\S+)',
                               contents)[-1])

    if get_time:
        m = re.search(
            'Job cpu time: +(\S+) +days +(\S+) +hours +(\S+) +minutes +(\S+) +seconds',
            contents)
        time = float(m.group(1)) * 24 * 60 * 60 + float(
            m.group(2)) * 60 * 60 + float(m.group(3)) * 60 + float(m.group(4))

    if get_energy and not get_atoms:
        if get_time:
            return energy, time
        else:
            return energy

    #get coordinates
    last_coordinates = contents.rindex('Input orientation:')
    last_coordinates = contents.index('Coordinates (Angstroms)',
                                      last_coordinates)
    start = contents.index('---\n', last_coordinates) + 4
    end = contents.index('\n ---', start)
    atoms = []
    for line in contents[start:end].splitlines():
        columns = line.split()
        element = columns[1]
        x, y, z = [float(s) for s in columns[3:6]]
        atoms.append(
            utils.Atom(element=utils.elements_by_atomic_number[int(
                columns[1])],
                       x=x,
                       y=y,
                       z=z,
                       index=len(atoms) + 1))

    #get forces
    if 'Forces (Hartrees/Bohr)' in contents:
        last_forces = contents.rindex('Forces (Hartrees/Bohr)')
        start = contents.index('---\n', last_forces) + 4
        end = contents.index('\n ---', start)
        for i, line in enumerate(contents[start:end].splitlines()):
            columns = line.split()
            atoms[i].fx, atoms[i].fy, atoms[i].fz = [
                float(s) for s in columns[2:5]
            ]

    #return the appropriate values
    if get_time:
        if get_atoms:
            return energy, atoms, time
        else:
            return energy, time
    if get_energy:
        return energy, atoms
    else:
        return atoms
Esempio n. 7
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def parse_atoms(input_file,
                get_atoms=True,
                get_energy=True,
                check_convergence=True,
                get_time=False,
                counterpoise=False,
                parse_all=False):
    """
	@input_file [str] : string name of log file

	Returns: (? energy, ? atoms, ? time) | None
	@energy [float] : If get_energy or parse_all, otherwise return omitted.
	@atoms |[atom list] : Iff parse_all, returns atom list list.
		   |[atom list list] : Iff not parse_all and get_atoms, atom list. Otherwise omitted.
	@time [float] : If get_time returns float (seconds). Otherwise, return omitted.

	Note that None may be returned in the event that Gaussian did not terminate normally (see 7 lines down).
	"""
    if input_file[-4:] != '.log':
        input_file = 'gaussian/' + input_file + '.log'
    contents = open(input_file).read()
    time = None

    if check_convergence and get_energy and not parse_all and 'Normal termination of Gaussian 09' not in contents:
        return None
    if ('Normal termination of Gaussian 09'
            in contents) and (get_time | parse_all):
        m = re.search(
            'Job cpu time: +(\S+) +days +(\S+) +hours +(\S+) +minutes +(\S+) +seconds',
            contents)
        try:
            time = float(m.group(1)) * 24 * 60 * 60 + float(
                m.group(2)) * 60 * 60 + float(m.group(3)) * 60 + float(
                    m.group(4))
        except:
            pass

    if 'Summary of Optimized Potential Surface Scan' in contents and not parse_all:
        end_section = contents[
            contents.rindex('Summary of Optimized Potential Surface Scan'):]
        energy_lines = re.findall('Eigenvalues -- ([^\\n]+)', end_section)
        energy = [
            float(s) for line in energy_lines
            for s in re.findall('-[\d]+\.[\d]+', line)
        ]

        minima = re.split('Stationary point found', contents)
        atoms = []
        for m in minima[1:]:
            coordinates = m.index('Coordinates (Angstroms)')

            start = m.index('---\n', coordinates) + 4
            end = m.index('\n ---', start)
            atoms.append([])
            for line in m[start:end].splitlines():
                columns = line.split()
                element = columns[1]
                x, y, z = [float(s) for s in columns[3:6]]
                atoms[-1].append(
                    utils.Atom(element=constants.PERIODIC_TABLE[int(
                        columns[1])]['sym'],
                               x=x,
                               y=y,
                               z=z,
                               index=len(atoms[-1]) + 1))

        if get_energy:
            return energy, atoms

    elif get_energy and not parse_all:
        if ' MP2/' in contents:  # MP2 files don't have just SCF energy
            energy = float(
                re.findall('EUMP2 = +(\S+)', contents)[-1].replace('D', 'e'))
        elif ' CCSD/' in contents:
            energy = float(re.findall('E\(CORR\)= +(\S+)', contents)[-1])
        else:
            if not counterpoise:
                try:
                    energy_line = contents[
                        contents.rindex('SCF Done'):contents.
                        index('\n', contents.rindex('SCF Done'))]
                except ValueError:
                    raise Exception('No SCF for ' + input_file)
                energy = float(
                    re.search('SCF Done: +\S+ += +(\S+)',
                              energy_line).group(1))
            else:
                energy = float(
                    re.findall('Counterpoise: corrected energy = +(\S+)',
                               contents)[-1])

    if parse_all:
        energies = []
        atom_frames = []
        start = 0
        orientation = 'Input orientation:'
        while True:
            try:  #match energy
                input_orientation = contents.find(orientation, start)
                if input_orientation == -1:
                    orientation = 'Standard orientation'
                    #print("\nWarning - No available Input Orientation, defaulting to Standard")
                    input_orientation = contents.find(orientation, start)
                if input_orientation >= 0:
                    start = input_orientation
                next_coordinates = contents.index('Coordinates (Angstroms)',
                                                  start)
                start = contents.index('SCF Done', start)
                energies.append(
                    float(
                        re.search('SCF Done: +\S+ += +(\S+)',
                                  contents[start:]).group(1)))
            except:
                break
            start = contents.index('---\n', next_coordinates) + 4
            end = contents.index('\n ---', start)
            lines = contents[start:end].splitlines()
            start = end

            atoms = []
            for line in lines:
                columns = line.split()
                element = columns[1]
                x, y, z = columns[3:6]
                atoms.append(
                    utils.Atom(element=element,
                               x=float(x),
                               y=float(y),
                               z=float(z)))
            atom_frames.append(atoms)
        return energies, atom_frames, time

    if get_energy and not get_atoms:
        if get_time:
            return energy, time
        else:
            return energy

    #get coordinates
    try:
        last_coordinates = contents.rindex('Input orientation:')
        last_coordinates = contents.index('Coordinates (Angstroms)',
                                          last_coordinates)
    except ValueError:
        last_coordinates = contents.rindex('Coordinates (Angstroms)')
    start = contents.index('---\n', last_coordinates) + 4
    end = contents.index('\n ---', start)
    atoms = []
    for line in contents[start:end].splitlines():
        columns = line.split()
        element = columns[1]
        x, y, z = [float(s) for s in columns[3:6]]
        atoms.append(
            utils.Atom(element=constants.PERIODIC_TABLE[int(
                columns[1])]['sym'],
                       x=x,
                       y=y,
                       z=z,
                       index=len(atoms) + 1))

    #get forces
    if 'Forces (Hartrees/Bohr)' in contents:
        last_forces = contents.rindex('Forces (Hartrees/Bohr)')
        start = contents.index('---\n', last_forces) + 4
        end = contents.index('\n ---', start)
        for i, line in enumerate(contents[start:end].splitlines()):
            columns = line.split()
            atoms[i].fx, atoms[i].fy, atoms[i].fz = [
                float(s) for s in columns[2:5]
            ]

    #return the appropriate values
    if get_time:
        if get_atoms:
            return energy, atoms, time
        else:
            return energy, time
    if get_energy:
        return energy, atoms
    else:
        return atoms
Esempio n. 8
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def read_lammpstrj_legacy(name, read_atoms=True, read_timesteps=True, read_num_atoms=True, read_box_bounds=True, last_frame=False):
	if not name.endswith('.lammpstrj') and '.' not in name:
		name += '.lammpstrj'
	# If file does not exist, return empty lammpstrj object
	if not os.path.isfile(name):
		warn('Expected lammps trajectory file does not exist at %s' % (name))
		data = ''
	else:
		data = open(name,'r').read()

	# Compile data from only the last frame if last_frame=True
	if last_frame:
		s = 'ITEM: TIMESTEP'
		section = data
		while (s in section):
			section = section[section.find(s)+len(s):]

		# Rewrite data to only include last frame
		data = section

	# Determine coordinate type
	coords = ''
	if read_atoms:
		section = data
		if 'x y z' in section:
			if verbose: print('%s: Reading wrapped, unscaled atom coordinates' % (name))
			coords = 'x y z'

		elif 'xs ys zs' in section:
			if verbose: print('%s: Reading warpped, scaled atom coordinates' % (name))
			coords = 'xs ys zs'

		elif 'xu yu zu' in section:
			if verbose: print('%s: Reading unwrapped, unscaled atom coordinates' % (name))
			coords = 'xu yu zu'

		elif 'xsu ysu zsu' in section:
			if verbose: print('%s: Reading unwrapped, scaled atom coordinates' % (name))
			coords = 'xsu ysu zsu'

		else:
			print('No valid coordinates found')

	# Get all the positions
	section, frames = data, []
	s = 'ITEM: ATOMS id type ' + coords
	while read_atoms and (s in section):
		section = section[section.find(s)+len(s):]
		atom_block = section[:section.find('\nITEM: TIMESTEP')].split('\n')[1:]
		frame = []
		for line in atom_block:
			a = line.split()

			# Check if atom has expected number of characteristics
			if len(a) == 5:
				frame.append(utils.Atom(a[1],float(a[2]),float(a[3]),float(a[4]),index=a[0]))
			else:
				print('Atom skipped due to missing information')

		frames.append(frame)

	if frames:
		atoms = frames[-1]
	else:
		atoms = None

	# Get all timesteps
	section, timesteps = data, []
	s = 'ITEM: TIMESTEP'
	while read_timesteps and (s in section):
		num = section.find(s)+len(s)
		print(num)
		section = section[num:]
		tmp = section[:section.find('\nITEM: NUMBER OF ATOMS')].split('\n')[1:]
		for line in tmp:
			a = line.split()
			timesteps.append(int(a[0]))

	if len(timesteps) > 0:
		final_timestep = timesteps[-1]
	else:
		final_timestep = None

	# Get number of atoms. Useful if number of atoms change during simulation, such as during a deposition
	section, atom_counts = data, []
	s = 'ITEM: NUMBER OF ATOMS'
	while read_num_atoms and (s in section):
		section = section[section.find(s)+len(s):]
		tmp = section[:section.find('\nITEM: BOX BOUNDS')].split('\n')[1:]
		for line in tmp:
			a = line.split()
			atom_counts.append(int(a[0]))

	if len(atom_counts) > 0:
		atom_count = atom_counts[-1]
	else:
		atom_count = None

	# Get box bounds
	# Currently only imports orthorhombic crystal information aka all angles = 90 degrees
	section, box_bounds_list = data, []
	s = 'ITEM: BOX BOUNDS'
	while read_box_bounds and (s in section):
		section = section[section.find(s)+len(s):]
		tmp = section[:section.find('\nITEM: ATOMS')].split('\n')[1:]
		box_bounds = utils.Struct(xlo=None, xhi=None, ylo=None, yhi=None, zlo=None, zhi=None)

		for line in tmp:
			a = line.split()
			if box_bounds.xlo is None:
				box_bounds.xlo = float(a[0])
				box_bounds.xhi = float(a[1])
			elif box_bounds.ylo is None:
				box_bounds.ylo = float(a[0])
				box_bounds.yhi = float(a[1])
			elif box_bounds.zlo is None:
				box_bounds.zlo = float(a[0])
				box_bounds.zhi = float(a[1])

		box_bounds_list.append(box_bounds)

	if len(box_bounds_list) > 0:
		box_bounds = box_bounds_list[-1]
	else:
		box_bounds = None

	# Create object to store all results
	data = utils.sim_out(name, 'lammps')

	# Record all lammps trajectory data into results object
	data.frames = frames
	data.atoms = atoms
	data.timesteps = timesteps
	data.final_timestep = final_timestep
	data.atom_counts = atom_counts
	data.atom_count = atom_count
	data.box_bounds_list = box_bounds_list
	data.box_bounds = box_bounds
	data.last_modified = 'Null' # Stores when lammpstrj was last modified in seconds

	return data
Esempio n. 9
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def read_lammpstrj(name, read_atoms=True, read_timesteps=True, read_num_atoms=True, read_box_bounds=True, verbose=True, last_frame_only=False):
	if not name.endswith('.lammpstrj') and '.' not in name:
		name += '.lammpstrj'
	# If file does not exist, return empty lammpstrj object
	if not os.path.isfile(name):
		warn('Expected lammps trajectory file does not exist at %s' % (name))
		data = ''

	# Initialize variables
	timesteps, atom_counts, box_bounds_list, frames = [], [], [], []

	# Initialize atom attributes list
	atom_attrs = []

	# Use these flags to determine what section you are in
	sect_timesteps, sect_num_atoms, sect_box_bounds, sect_atoms = False, False, False, False

	# Flag to keep track if this is the first step analyzed
	first_step = True

	# Skip the listed number of frames then reset
	# Set to 0 for no skpping
	#skip_set = range(2**5 - 1)
	#skip_set = [x+2 for x in skip_set]

	skip_set = [0]
	skip_count = 0

	# Iterate file line by line. This reduces the memory required since it only loads the current line
	with open(name) as f:
		for line in f:

			# Check for new section
			if 'ITEM: TIMESTEP' in line:
				# If skipped previous frame, reset skip counter
				if skip_count == max(skip_set):
					skip_count = 0

				# Increment skip counter and skip if necessary
				skip_count = skip_count + 1
				if skip_count in skip_set:
					continue

				sect_timesteps, sect_num_atoms, sect_box_bounds, sect_atoms = False, False, False, False
				sect_timesteps = True

				# Add previous timestep to list of frames. Do not try for first time step since you have not read any atoms yet.
				# Do not add if only looking for final frame
				if not first_step and not last_frame_only:
					frames.append(frame)

				continue

			# If it is not the timestep section, and a skip has triggered, skip all lines till next timestep
			elif skip_count in skip_set:
					continue

			elif 'ITEM: NUMBER OF ATOMS' in line:
				sect_timesteps, sect_num_atoms, sect_box_bounds, sect_atoms = False, False, False, False
				sect_num_atoms = True
				continue

			elif 'ITEM: BOX BOUNDS' in line:
				sect_timesteps, sect_num_atoms, sect_box_bounds, sect_atoms = False, False, False, False
				sect_box_bounds = True
				box_bounds = utils.Struct(xlo=None, xhi=None, ylo=None, yhi=None, zlo=None, zhi=None)
				continue

			elif 'ITEM: ATOMS' in line:
				sect_timesteps, sect_num_atoms, sect_box_bounds, sect_atoms = False, False, False, False
				sect_atoms = True
				box_bounds_list.append(box_bounds)
				frame = []

				# Determine atom attributes in lammpstrj file and add to list
				if first_step:
					a = line.split()
					atom_attrs = a[2:]

				# If this is the first time step analyzed, report the coordinates style
				if first_step and verbose:
					if 'x y z' in line:
						print('%s: Reading wrapped, unscaled atom coordinates' % (name))

					elif 'xs ys zs' in line:
						print('%s: Reading wrapped, scaled atom coordinates' % (name))

					elif 'xu yu zu' in line:
						print('%s: Reading unwrapped, unscaled atom coordinates' % (name))

					elif 'xsu ysu zsu' in line:
						print('%s: Reading unwrapped, scaled atom coordinates' % (name))

					else:
						print('No valid coordinates found')

				first_step = False
				continue

			# Record information as required by the section
			if sect_timesteps and read_timesteps:
				a = line.split()
				timesteps.append(int(a[0]))

			if sect_num_atoms and read_num_atoms:
				a = line.split()
				atom_counts.append(int(a[0]))

			if sect_box_bounds and read_box_bounds:
				a = line.split()
				if box_bounds.xlo is None:
					box_bounds.xlo = float(a[0])
					box_bounds.xhi = float(a[1])
				elif box_bounds.ylo is None:
					box_bounds.ylo = float(a[0])
					box_bounds.yhi = float(a[1])
				elif box_bounds.zlo is None:
					box_bounds.zlo = float(a[0])
					box_bounds.zhi = float(a[1])

			if sect_atoms and read_atoms:
				a = line.split()

				# Initialize all atom values
				index, lammps_type, x, y, z, vx, vy, vz, fx, fy, fz = 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0

				# Assign atom attributes
				for (value, attr) in zip(a, atom_attrs):
					if attr == 'id':
						index = int(value)
					elif attr == 'type':
						lammps_type = value
					elif attr in ['x','xs','xu','xsu']:
						x = float(value)
					elif attr in ['y','ys','yu','ysu']:
						y = float(value)
					elif attr in ['z','zs','zu','zsu']:
						z = float(value)
					elif attr == 'vx':
						vx = float(value)
					elif attr == 'vy':
						vy = float(value)
					elif attr == 'vz':
						vz = float(value)
					elif attr == 'fx':
						fx = float(value)
					elif attr == 'fy':
						fy = float(value)
					elif attr == 'fz':
						fz = float(value)

				# Check if atom has expected number of characteristics
				if len(a) == len(atom_attrs):
					frame.append(utils.Atom(lammps_type,x,y,z,index=index,vx=vx,vy=vy,vz=vz,fx=fx,fy=fy,fz=fz))
				else:
					print('Atom skipped due to missing information')

	# Add final frame
	frames.append(frame)

	# Record final data point as necessary
	if len(timesteps) > 0:
		final_timestep = timesteps[-1]
	else:
		final_timestep = None

	if len(atom_counts) > 0:
		atom_count = atom_counts[-1]
	else:
		atom_count = None

	if len(box_bounds_list) > 0:
		box_bounds = box_bounds_list[-1]
	else:
		box_bounds = None

	if frames:
		atoms = frames[-1]
	else:
		atoms = None

	# If only looking for final frame, erase all other timesteps
	if last_frame_only:
		timesteps = [timesteps[-1]]
		atom_counts = [atom_counts[-1]]
		box_bounds_list = [box_bounds_list[-1]]
		frames = [frames[-1]]

	# Create object to store all results
	data = utils.sim_out(name, 'lammps')

	# Record all lammps trajectory data into results object
	data.frames = frames
	data.atoms = atoms
	data.timesteps = timesteps
	data.final_timestep = final_timestep
	data.atom_counts = atom_counts
	data.atom_count = atom_count
	data.box_bounds_list = box_bounds_list
	data.box_bounds = box_bounds
	data.last_modified = 'Null' # Stores when lammpstrj was last modified in seconds

	return data