/usr/share/pyshared/ase/io/aims.py is in python-ase 3.6.0.2515-1.1.
This file is owned by root:root, with mode 0o644.
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"""Import FHI-aims geometry type files.
Reads unitcell, atom positions and constraints from
a geometry.in file.
"""
from ase import Atoms
from ase.constraints import FixAtoms, FixCartesian
import numpy as np
atoms = Atoms()
fd = open(filename, 'r')
lines = fd.readlines()
fd.close()
positions = []
cell = []
symbols = []
fix = []
fix_cart = []
xyz = np.array([0, 0, 0])
i = -1
n_periodic = -1
periodic = np.array([False, False, False])
for n, line in enumerate(lines):
inp = line.split()
if inp == []:
continue
if inp[0] == 'atom':
if xyz.all():
fix.append(i)
elif xyz.any():
fix_cart.append(FixCartesian(i, xyz))
floatvect = float(inp[1]), float(inp[2]), float(inp[3])
positions.append(floatvect)
symbols.append(inp[-1])
i += 1
xyz = np.array([0, 0, 0])
elif inp[0] == 'lattice_vector':
floatvect = float(inp[1]), float(inp[2]), float(inp[3])
cell.append(floatvect)
n_periodic = n_periodic + 1
periodic[n_periodic] = True
if inp[0] == 'constrain_relaxation':
if inp[1] == '.true.':
fix.append(i)
elif inp[1] == 'x':
xyz[0] = 1
elif inp[1] == 'y':
xyz[1] = 1
elif inp[1] == 'z':
xyz[2] = 1
if xyz.all():
fix.append(i)
elif xyz.any():
fix_cart.append(FixCartesian(i, xyz))
atoms = Atoms(symbols, positions)
if periodic.all():
atoms.set_cell(cell)
atoms.set_pbc(periodic)
if len(fix):
atoms.set_constraint([FixAtoms(indices=fix)]+fix_cart)
else:
atoms.set_constraint(fix_cart)
return atoms
def write_aims(filename, atoms):
"""Method to write FHI-aims geometry files.
Writes the atoms positions and constraints (only FixAtoms is
supported at the moment).
"""
from ase.constraints import FixAtoms, FixCartesian
import numpy as np
if isinstance(atoms, (list, tuple)):
if len(atoms) > 1:
raise RuntimeError("Don't know how to save more than "+
"one image to FHI-aims input")
else:
atoms = atoms[0]
fd = open(filename, 'w')
fd.write('#=======================================================\n')
fd.write('#FHI-aims file: '+filename+'\n')
fd.write('#Created using the Atomic Simulation Environment (ASE)\n')
fd.write('#=======================================================\n')
i = 0
if atoms.get_pbc().any():
for n, vector in enumerate(atoms.get_cell()):
fd.write('lattice_vector ')
for i in range(3):
fd.write('%16.16f ' % vector[i])
fd.write('\n')
fix_cart = np.zeros([len(atoms),3])
if atoms.constraints:
for constr in atoms.constraints:
if isinstance(constr, FixAtoms):
fix_cart[constr.index] = [1,1,1]
elif isinstance(constr, FixCartesian):
fix_cart[constr.a] = -constr.mask+1
for i, atom in enumerate(atoms):
fd.write('atom ')
for pos in atom.position:
fd.write('%16.16f ' % pos)
fd.write(atom.symbol)
fd.write('\n')
# (1) all coords are constrained:
if fix_cart[i].all():
fd.write('constrain_relaxation .true.\n')
# (2) some coords are constrained:
elif fix_cart[i].any():
xyz = fix_cart[i]
for n in range(3):
if xyz[n]:
fd.write('constrain_relaxation %s\n' % 'xyz'[n])
if atom.charge:
fd.write('initial_charge %16.6f\n' % atom.charge)
if atom.magmom:
fd.write('initial_moment %16.6f\n' % atom.magmom)
# except KeyError:
# continue
def read_energy(filename):
for line in open(filename, 'r'):
if line.startswith(' | Total energy corrected'):
E = float(line.split()[-2])
return E
def read_aims_output(filename, index = -1):
""" Import FHI-aims output files with all data available, i.e. relaxations,
MD information, force information etc etc etc. """
from ase import Atoms, Atom
from ase.calculators.singlepoint import SinglePointCalculator
from ase.units import Ang, fs
from ase.constraints import FixAtoms, FixCartesian
molecular_dynamics = False
fd = open(filename, 'r')
cell = []
images = []
fix = []
fix_cart = []
n_periodic = -1
f = None
pbc = False
found_aims_calculator = False
v_unit = Ang/(1000.0*fs)
while True:
line = fd.readline()
if not line:
break
if "List of parameters used to initialize the calculator:" in line:
fd.readline()
calc = read_aims_calculator(fd)
calc.out = filename
found_aims_calculator = True
if "Number of atoms" in line:
inp = line.split()
n_atoms = int(inp[5])
if "| Unit cell:" in line:
if not pbc:
pbc = True
for i in range(3):
inp = fd.readline().split()
cell.append([inp[1],inp[2],inp[3]])
if "Found relaxation constraint for atom" in line:
xyz = [0, 0, 0]
ind = int(line.split()[5][:-1])-1
if "All coordinates fixed" in line:
if ind not in fix:
fix.append(ind)
if "coordinate fixed" in line:
coord = line.split()[6]
constr_ind = 0
if coord == 'x':
xyz[0] = 1
elif coord == 'y':
xyz[1] = 1
elif coord == 'z':
xyz[2] = 1
keep = True
for n,c in enumerate(fix_cart):
if ind == c.a:
keep = False
constr_ind = n
if keep:
fix_cart.append(FixCartesian(ind, xyz))
else:
fix_cart[n].mask[xyz.index(1)] = 0
if "Atomic structure:" in line and not molecular_dynamics:
fd.readline()
atoms = Atoms()
for i in range(n_atoms):
inp = fd.readline().split()
atoms.append(Atom(inp[3],(inp[4],inp[5],inp[6])))
if "Complete information for previous time-step:" in line:
molecular_dynamics = True
if "Updated atomic structure:" in line and not molecular_dynamics:
fd.readline()
atoms = Atoms()
velocities = []
for i in range(n_atoms):
inp = fd.readline().split()
if 'lattice_vector' in inp[0]:
cell = []
for i in range(3):
cell += [[float(inp[1]),float(inp[2]),float(inp[3])]]
inp = fd.readline().split()
atoms.set_cell(cell)
inp = fd.readline().split()
atoms.append(Atom(inp[4],(inp[1],inp[2],inp[3])))
if molecular_dynamics:
inp = fd.readline().split()
if "Atomic structure (and velocities)" in line:
fd.readline()
atoms = Atoms()
velocities = []
for i in range(n_atoms):
inp = fd.readline().split()
atoms.append(Atom(inp[4],(inp[1],inp[2],inp[3])))
inp = fd.readline().split()
velocities += [[float(inp[1])*v_unit,float(inp[2])*v_unit,float(inp[3])*v_unit]]
atoms.set_velocities(velocities)
if len(fix):
atoms.set_constraint([FixAtoms(indices=fix)]+fix_cart)
else:
atoms.set_constraint(fix_cart)
images.append(atoms)
if "Total atomic forces" in line:
f = []
for i in range(n_atoms):
inp = fd.readline().split()
f.append([float(inp[2]),float(inp[3]),float(inp[4])])
if not found_aims_calculator:
e = images[-1].get_potential_energy()
images[-1].set_calculator(SinglePointCalculator(e,f,None,None,atoms))
e = None
f = None
if "Total energy corrected" in line:
e = float(line.split()[5])
if pbc:
atoms.set_cell(cell)
atoms.pbc = True
if not found_aims_calculator:
atoms.set_calculator(SinglePointCalculator(e,None,None,None,atoms))
if not molecular_dynamics:
if len(fix):
atoms.set_constraint([FixAtoms(indices=fix)]+fix_cart)
else:
atoms.set_constraint(fix_cart)
images.append(atoms)
e = None
if found_aims_calculator:
calc.set_results(images[-1])
images[-1].set_calculator(calc)
fd.close()
if molecular_dynamics:
images = images[1:]
# return requested images, code borrowed from ase/io/trajectory.py
if isinstance(index, int):
return images[index]
else:
step = index.step or 1
if step > 0:
start = index.start or 0
if start < 0:
start += len(images)
stop = index.stop or len(images)
if stop < 0:
stop += len(images)
else:
if index.start is None:
start = len(images) - 1
else:
start = index.start
if start < 0:
start += len(images)
if index.stop is None:
stop = -1
else:
stop = index.stop
if stop < 0:
stop += len(images)
return [images[i] for i in range(start, stop, step)]
def read_aims_calculator(file):
""" found instructions for building an FHI-aims calculator in the output file,
read its specifications and return it. """
from ase.calculators.aims import Aims
calc = Aims()
while True:
line = file.readline()
if "=======================================================" in line:
break
else:
args = line.split()
key = '#'
if len(args) > 0:
key = args[0]
if key == '#':
comment = True
elif calc.float_params.has_key(key):
calc.float_params[key] = float(args[1])
elif calc.exp_params.has_key(key):
calc.exp_params[key] = float(args[1])
elif calc.string_params.has_key(key):
calc.string_params[key] = args[1]
if len(args) > 2:
for s in args[2:]:
calc.string_params[key] += " "+s
elif calc.int_params.has_key(key):
calc.int_params[key] = int(args[1])
elif calc.bool_params.has_key(key):
try:
calc.bool_params[key] = bool(args[1])
except:
if key == 'vdw_correction_hirshfeld':
calc.bool_params[key] = True
elif calc.list_params.has_key(key):
if key == 'output':
# build output string from args:
out_option = ''
for arg in args[1:]:
out_option +=str(arg)+' '
if calc.list_params['output'] is not None:
calc.list_params['output'] += [out_option]
else:
calc.list_params['output'] = [out_option]
else:
calc.list_params[key] = list(args[1:])
elif '#' in key:
key = key[1:]
if calc.input_parameters.has_key(key):
calc.input_parameters[key] = args[1]
if len(args) > 2:
for s in args[2:]:
calc.input_parameters[key] += " "+s
else:
raise TypeError('FHI-aims keyword not defined in ASE: ' + key + '. Please check.')
return calc
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