# -*- coding: utf-8 -*-
from __future__ import print_function
"""This module defines an interface to CASTEP for
use by the ASE (Webpage: http://wiki.fysik.dtu.dk/ase)
Authors:
Max Hoffmann, max.hoffmann@ch.tum.de
Jörg Meyer, joerg.meyer@ch.tum.de
"""
__all__ = [
'Castep',
'CastepCell',
'CastepParam',
'create_castep_keywords']
contact_email = 'max.hoffmann@ch.tum.de'
from copy import deepcopy
import difflib
import numpy as np
import os
import re
import shutil
import subprocess
import sys
import tempfile
import time
import ase
from ase.calculators.general import Calculator
from ase.constraints import FixCartesian
from ase.parallel import paropen
# Adapt import path to give local versions of castep_keywords
# a higher priority, assuming that personal folder will be
# standardized at ~/.ase, watch [ase-developers]
sys.path = ['',
os.path.expanduser('~/.ase'),
os.path.join(ase.__path__[0], 'calculators')] + sys.path
[docs]class Castep(Calculator):
r"""
CASTEP Interface Documentation
Introduction
============
CASTEP_ [1]_ W_ is a software package which uses density functional theory to
provide a good atomic-level description of all manner of materials and
molecules. CASTEP can give information about total energies, forces and
stresses on an atomic system, as well as calculating optimum geometries, band
structures, optical spectra, phonon spectra and much more. It can also perform
molecular dynamics simulations.
The CASTEP calculator interface class offers intuitive access to all CASTEP
settings and most results. All CASTEP specific settings are accessible via
attribute access (*i.e*. ``calc.param.keyword = ...`` or
``calc.cell.keyword = ...``)
Getting Started:
================
Set the environment variables appropriately for your system.
>>> export CASTEP_COMMAND=' ... '
>>> export CASTEP_PP_PATH=' ... '
Note: alternatively to CASTEP_PP_PATH one can set PSPOT_DIR
as CASTEP consults this by default, i.e.
>>> export PSPOT_DIR=' ... '
Running the Calculator
======================
The default initialization command for the CASTEP calculator is
.. class:: Castep(directory='CASTEP', label='castep')
To do a minimal run one only needs to set atoms, this will use all
default settings of CASTEP, meaning LDA, singlepoint, etc..
With a generated castep_keywords.py in place all options are accessible
by inspection, *i.e.* tab-completion. This works best when using ``ipython``.
All options can be accessed via ``calc.param.<TAB>`` or ``calc.cell.<TAB>``
and documentation is printed with ``calc.param.<keyword> ?`` or
``calc.cell.<keyword> ?``. All options can also be set directly
using ``calc.keyword = ...`` or ``calc.KEYWORD = ...`` or even
``calc.KeYwOrD`` or directly as named arguments in the call to the constructor
(*e.g.* ``Castep(task='GeometryOptimization')``).
All options that go into the ``.param`` file are held in an ``CastepParam``
instance, while all options that go into the ``.cell`` file and don't belong
to the atoms object are held in an ``CastepCell`` instance. Each instance can
be created individually and can be added to calculators by attribute
assignment, *i.e.* ``calc.param = param`` or ``calc.cell = cell``.
All internal variables of the calculator start with an underscore (_).
All cell attributes that clearly belong into the atoms object are blocked.
Setting ``calc.atoms_attribute`` (*e.g.* ``= positions``) is sent directly to
the atoms object.
Arguments:
==========
========================= ====================================================
Keyword Description
========================= ====================================================
``directory`` The relative path where all input and output files
will be placed. If this does not exist, it will be
created. Existing directories will be moved to
directory-TIMESTAMP unless self._rename_existing_dir
is set to false.
``label`` The prefix of .param, .cell, .castep, etc. files.
========================= ====================================================
Additional Settings
===================
========================= ====================================================
Internal Setting Description
========================= ====================================================
``_castep_command`` (``=castep``): the actual shell command used to
call CASTEP.
``_check_checkfile`` (``=True``): this makes write_param() only
write a continue or reuse statement if the
addressed .check or .castep_bin file exists in the
directory.
``_copy_pspots`` (``=False``): if set to True the calculator will
actually copy the needed pseudo-potential (\*.usp)
file, usually it will only create symlinks.
``_export_settings`` (``=True``): if this is set to
True, all calculator internal settings shown here
will be included in the .param in a comment line (#)
and can be read again by merge_param. merge_param
can be forced to ignore this directive using the
optional argument ``ignore_internal_keys=True``.
``_force_write`` (``=True``): this controls wether the \*cell and
\*param will be overwritten.
``_prepare_input_only`` (``=False``): If set to True, the calculator will
create \*cell und \*param file but not
start the calculation itself.
If this is used to prepare jobs locally
and run on a remote cluster it is recommended
to set ``_copy_pspots = True``.
``_castep_pp_path`` (``='.'``) : the place where the calculator
will look for pseudo-potential files.
``_rename_existing_dir`` (``=True``) : when using a new instance
of the calculator, this will move directories out of
the way that would be overwritten otherwise,
appending a date string.
``_set_atoms`` (``=False``) : setting this to True will overwrite
any atoms object previously attached to the
calculator when reading a \.castep file. By de-
fault, the read() function will only create a new
atoms object if none has been attached and other-
wise try to assign forces etc. based on the atom's
positions. ``_set_atoms=True`` could be necessary
if one uses CASTEP's internal geometry optimization
(``calc.param.task='GeometryOptimization'``)
because then the positions get out of sync.
*Warning*: this option is generally not recommended
unless one knows one really needs it. There should
never be any need, if CASTEP is used as a
single-point calculator.
``_track_output`` (``=False``) : if set to true, the interface
will append a number to the label on all input
and output files, where n is the number of calls
to this instance. *Warning*: this setting may con-
sume a lot more disk space because of the additio-
nal \*check files.
``_try_reuse`` (``=_track_output``) : when setting this, the in-
terface will try to fetch the reuse file from the
previous run even if _track_output is True. By de-
fault it is equal to _track_output, but may be
overridden.
Since this behavior may not always be desirable for
single-point calculations. Regular reuse for *e.g.*
a geometry-optimization can be achieved by setting
``calc.param.reuse = True``.
========================= ====================================================
Special features:
=================
``.dryrun_ok()``
Runs ``castep_command seed -dryrun`` in a temporary directory return True if
all variables initialized ok. This is a fast way to catch errors in the
input. Afterwards _kpoints_used is set.
``.merge_param()``
Takes a filename or filehandler of a .param file or CastepParam instance and
merges it into the current calculator instance, overwriting current settings
``.keyword.clear()``
Can be used on any option like ``calc.param.keyword.clear()`` or
``calc.cell.keyword.clear()`` to return to the CASTEP default.
``.initialize()``
Creates all needed input in the ``_directory``. This can then copied to and
run in a place without ASE or even python.
``.set_pspot('<library>')``
This automatically sets the pseudo-potential for all present species to
*<Species>_<library>.usp*. Make sure that ``_castep_pp_path`` is set
correctly.
``print(calc)``
Prints a short summary of the calculator settings and atoms.
``ase.io.castep.read_seed('path-to/seed')``
Given you have a combination of seed.{param,cell,castep} this will return an
atoms object with the last ionic positions in the .castep file and all other
settings parsed from the .cell and .param file. If no .castep file is found
the positions are taken from the .cell file. The output directory will be
set to the same directory, only the label is preceded by 'copy_of\_' to
avoid overwriting.
Notes/Issues:
==============
* Currently *only* the FixAtoms *constraint* is fully supported for
reading and writing.
* There is no support for the CASTEP *unit system*. Units of eV and Angstrom
are used throughout. In particular when converting total energies from
different calculators, one should check that the same CODATA_ version is
used for constants and conversion factors, respectively.
.. _CASTEP: http://www.castep.org/
.. _W: http://en.wikipedia.org/wiki/CASTEP
.. _CODATA: http://physics.nist.gov/cuu/Constants/index.html
.. [1] S. J. Clark, M. D. Segall, C. J. Pickard, P. J. Hasnip, M. J. Probert,
K. Refson, M. C. Payne Zeitschrift für Kristallographie 220(5-6)
pp.567- 570 (2005) PDF_.
.. _PDF: http://goo.gl/wW50m
End CASTEP Interface Documentation
"""
# Class attributes !
# keys set through atoms object
atoms_keys = [
'charge',
'ionic_constraints',
'lattice_abs',
'lattice_cart',
'positions_abs',
'positions_abs_final',
'positions_abs_intermediate',
'positions_frac',
'positions_frac_final',
'positions_frac_intermediate',
]
atoms_obj_keys = [
'dipole',
'energy_free',
'energy_zero',
'fermi',
'forces',
'nbands',
'positions',
'stress',
]
internal_keys = [
'_castep_command',
'_check_checkfile',
'_copy_pspots',
'_directory',
'_export_settings',
'_force_write',
'_label',
'_prepare_input_only',
'_castep_pp_path',
'_rename_existing_dir',
'_set_atoms',
'_track_output',
'_try_reuse',
]
def __init__(self, directory='CASTEP', label='castep',
castep_command=None, check_castep_version=False,
castep_pp_path=None,
**kwargs):
self.__name__ = 'Castep'
# initialize the ase.calculators.general calculator
Calculator.__init__(self)
from ase.io.castep import write_cell
self._write_cell = write_cell
castep_keywords = import_castep_keywords()
self.param = CastepParam()
self.cell = CastepCell()
###################################
# Calculator state variables #
###################################
self._calls = 0
self._castep_version = castep_keywords.castep_version
# collects warning from .castep files
self._warnings = []
# collects content from *.err file
self._error = None
# warnings raised by the ASE interface
self._interface_warnings = []
# store to check if recalculation is necessary
self._old_atoms = None
self._old_cell = None
self._old_param = None
###################################
# Internal keys #
# Allow to tweak the behavior #
###################################
self._opt = {}
self._castep_command = get_castep_command(castep_command)
self._castep_pp_path = get_castep_pp_path(castep_pp_path)
self._check_checkfile = True
self._copy_pspots = False
self._directory = os.path.abspath(directory)
self._export_settings = True
self._force_write = True
self._label = label
self._prepare_input_only = False
self._rename_existing_dir = True
self._set_atoms = False
self._track_output = False
self._try_reuse = False
# will be set on during runtime
self._seed = None
###################################
# (Physical) result variables #
###################################
self.atoms = None
# initialize result variables
self._forces = None
self._energy_total = None
self._energy_free = None
self._energy_0K = None
self._number_of_cell_constraints = None
self._output_verbosity = None
self._stress = None
self._unit_cell = None
self._kpoints = None
# pointers to other files used at runtime
self._check_file = None
self._castep_bin_file = None
# check version of CASTEP options module against current one
if check_castep_version:
local_castep_version = get_castep_version(self._castep_command)
if not hasattr(self, '_castep_version'):
print("No castep version found")
return
if not local_castep_version == self._castep_version:
print(('The options module was generated from version %s\n'
'while your are currently using CASTEP version %s') %
(self._castep_version,
get_castep_version(self._castep_command)))
self._castep_version = local_castep_version
# processes optional arguments in kw style
for keyword, value in kwargs.items():
# first fetch special keywords issued by ASE CLI
if keyword == 'kpts':
self.__setattr__('kpoint_mp_grid', '%s %s %s' % tuple(value))
elif keyword == 'xc':
self.__setattr__('xc_functional', str(value))
elif keyword == 'ecut':
self.__setattr__('cut_off_energy', str(value))
else: # the general case
self.__setattr__(keyword, value)
def _castep_find_last_record(self, castep_file):
"""Checks wether a given castep file has a regular
ending message following the last banner message. If this
is the case, the line number of the last banner is message
is return, otherwise False.
returns (record_start, record_end, end_found, last_record_complete)
"""
if isinstance(castep_file, str):
castep_file = paropen(castep_file, 'r')
file_opened = True
else:
file_opened = False
record_starts = []
while True:
line = castep_file.readline()
if 'Welcome' in line and 'CASTEP' in line:
record_starts = [castep_file.tell()] + record_starts
if not line:
break
if record_starts == []:
print("Could not find CASTEP label in result file: %s"
% castep_file)
print("Are you sure this is a .castep file?")
return
# search for regular end of file
end_found = False
# start to search from record beginning from the back
# and see if
record_end = -1
for record_nr, record_start in enumerate(record_starts):
castep_file.seek(record_start)
while True:
line = castep_file.readline()
if not line:
break
if 'warn' in line.lower():
self._warnings.append(line)
if 'Writing analysis data to' in line:
#if 'Writing model to' in line:
end_found = True
record_end = castep_file.tell()
break
if end_found:
break
if file_opened:
castep_file.close()
if end_found:
# record_nr == 0 corresponds to the last record here
if record_nr == 0:
return (record_start, record_end, True, True)
else:
return (record_start, record_end, True, False)
else:
return (0, record_end, False, False)
def read(self, castep_file=None):
"""Read a castep file into the current instance."""
if castep_file is None:
if self._castep_file:
castep_file = self._castep_file
else:
print('No CASTEP file specified')
return
if not os.path.exists(castep_file):
print('No CASTEP file found')
if self._seed is None:
self._seed = os.path.splitext(os.path.basename(castep_file))[0]
err_file = '%s.0001.err' % self._seed
if os.path.exists(err_file):
err_file = paropen(err_file)
self._error = err_file.read()
err_file.close()
# we return right-away because it might
# just be here from a previous run
# look for last result, if several CASTEP
# run are appended
out = paropen(castep_file, 'r')
record_start, record_end, end_found, _\
= self._castep_find_last_record(out)
if not end_found:
print("No regular end found in %s file" % castep_file)
print(self._error)
out.close()
return
# we return here, because the file has no a regular end
# now iterate over last CASTEP output in file to extract information
# could be generalized as well to extract trajectory from file
# holding several outputs
n_cell_const = 0
forces = []
stress = []
out.seek(record_start)
while True:
try:
line = out.readline()
if not line or out.tell() > record_end:
break
elif "output verbosity" in line:
iprint = int(line.split()[-1][1])
if int(iprint) != 1:
self.param.iprint = iprint
elif "Unit Cell" in line:
lattice_real = []
lattice_reci = []
while True:
line = out.readline()
fields = line.split()
if len(fields) == 6:
break
for i in range(3):
lattice_real.append([float(f) for f in fields[0:3]])
lattice_reci.append([float(f) for f in fields[3:7]])
line = out.readline()
fields = line.split()
elif "Cell Contents" in line:
while True:
line = out.readline()
if "Total number of ions in cell" in line:
n_atoms = int(line.split()[7])
if "Total number of species in cell" in line:
_ = int(line.split()[7])
fields = line.split()
if len(fields) == 0:
break
elif "Fractional coordinates of atoms" in line:
species = []
positions_frac = []
# positions_cart = []
while True:
line = out.readline()
fields = line.split()
if len(fields) == 7:
break
for n in range(n_atoms):
species.append(fields[1])
positions_frac.append([float(s) for s in fields[3:6]])
line = out.readline()
fields = line.split()
elif "Files used for pseudopotentials" in line:
while True:
line = out.readline()
if 'Pseudopotential generated on-the-fly' in line:
continue
fields = line.split()
if (len(fields) >= 2):
elem, pp_file = fields
self.cell.species_pot = (elem, pp_file)
else:
break
elif "k-Points For BZ Sampling" in line:
# TODO: generalize for non-Monkhorst Pack case
# (i.e. kpoint lists) -
# kpoints_offset cannot be read this way and
# is hence always set to None
while True:
line = out.readline()
if not line.strip():
break
if "MP grid size for SCF calculation" in line:
#kpoints = ' '.join(line.split()[-3:])
#self.kpoints_mp_grid = kpoints
#self.kpoints_mp_offset = '0. 0. 0.'
# not set here anymore because otherwise
# two calculator objects go out of sync
# after each calculation triggering unecessary
# recalculation
break
elif "Symmetry and Constraints" in line:
self.read_symops(castep_castep=out)
elif "Number of cell constraints" in line:
n_cell_const = int(line.split()[4])
elif "Final energy" in line:
self._energy_total = float(line.split()[-2])
elif "Final free energy" in line:
self._energy_free = float(line.split()[-2])
elif "NB est. 0K energy" in line:
self._energy_0K = float(line.split()[-2])
# remember to remove constraint labels in force components
# (lacking a space behind the actual floating point number in
# the CASTEP output)
elif "******************** Forces *********************"\
in line or\
"************** Symmetrised Forces ***************"\
in line:
fix = []
fix_cart = []
forces = []
while True:
line = out.readline()
fields = line.split()
if len(fields) == 7:
break
for n in range(n_atoms):
consd = np.array([0, 0, 0])
fxyz = [0, 0, 0]
for (i, force_component) in enumerate(fields[-4:-1]):
if force_component.count("(cons'd)") > 0:
consd[i] = 1
fxyz[i] = float(force_component.replace(
"(cons'd)", ""))
if consd.all():
fix.append(n)
elif consd.any():
fix_cart.append(FixCartesian(n, consd))
forces.append(fxyz)
line = out.readline()
fields = line.split()
elif "***************** Stress Tensor *****************"\
in line or\
"*********** Symmetrised Stress Tensor ***********"\
in line:
stress = []
while True:
line = out.readline()
fields = line.split()
if len(fields) == 6:
break
for n in range(3):
# print line
stress.append([float(s) for s in fields[2:5]])
line = out.readline()
fields = line.split()
elif "BFGS: starting iteration" in line \
or "BFGS: improving iteration" in line:
if n_cell_const < 6:
lattice_real = []
lattice_reci = []
species = []
positions_frac = []
#positions_cart = []
forces = []
stress = []
elif "BFGS: Final Configuration:" in line:
break
elif 'warn' in line.lower():
self._warnings.append(line)
except Exception as exception:
print(line, end=' ')
print("|-> line triggered exception: " + str(exception))
raise
out.close()
positions_frac_atoms = np.array(positions_frac)
forces_atoms = np.array(forces)
if self.atoms and not self._set_atoms:
# compensate for internal reordering of atoms by CASTEP
# to check if all atoms are assigned
atoms_assigned = [False] * len(self.atoms)
positions_frac_ase = (np.round(self.atoms.get_scaled_positions(),
6) % 1) % 1
positions_frac_castep = (np.array(positions_frac) % 1) % 1
# % is necessary because CASTEP output may contain fractional
# coordinates > 1, which does not affect the calculation though
# Source: http://goo.gl/xfwri
# And, yes, the % needs to be done twice, see
# ase.atoms.Atoms.get_scaled_positions
#
# np.round is used to catch the case that
# a float roundoff error occurs right on
# the border of the unit cell.
species_castep = list(species)
forces_castep = np.array(forces)
tolerance = 1E-5
for n in range(n_atoms):
for m in range(n_atoms):
if (np.linalg.norm(positions_frac_ase[n] \
- positions_frac_castep[m], 1) < tolerance):
if atoms_assigned[n]:
raise UserWarning('Castep().read() tried to' + \
' assign forces twice to the same' + \
' atom.\n Please file a bug report to %s' + \
' and attach your input files.' \
% contact_email)
species[n] = species_castep[m]
positions_frac_atoms[n] = \
np.array(positions_frac_castep[m])
forces_atoms[n] = np.array(forces_castep[m])
atoms_assigned[n] = True
if not all(atoms_assigned):
not_assigned = [i for (i, assigned)
in zip(range(len(atoms_assigned)),
atoms_assigned) if not assigned]
print('%s atoms not assigned.' % atoms_assigned.count(False))
print('DEBUGINFO: The following atoms where not assigned: %s'\
% not_assigned)
for atom in not_assigned:
print('%s: %s <--> %s' % (atom, positions_frac_ase[atom],
positions_frac_castep[atom]))
print('dist.: %s' % ((np.linalg.norm(positions_frac_ase[n]
- positions_frac_castep[m], 1))))
print('If you are trying to read a .castep where the atom\'s')
print('positions have changed with respect to the atoms')
print('object, set calc._set_atoms = True\n')
print('On the other hand _set_atoms = True is not')
print('recommended if CASTEP is only used as a single-point')
print('calculator (e.g. in an ASE geometry optimzation)')
print('as this might cause redundant recalculations.')
raise UserWarning('Castep().read() did not assign forces' + \
' and positions to all input atoms\n' + \
' Sometimes this is caused if a node\n' + \
' used in the calculation hits a\n' + \
' wallclock limit that the head node has not noticed\n' + \
' and accordingly tries to reread an unfinished\n' + \
' calculation.\n' + \
'If you think it should have assigned all of them,' + \
' please file a bug report with your input file(s)' + \
' to\n\n\t%s' % contact_email)
else:
# If no atoms, object has been previously defined
# we define it here and set the Castep() instance as calculator.
# This covers the case that we simply want to open a .castep file.
# The next time around we will have an atoms object, since
# set_calculator also set atoms in the calculator.
if self.atoms:
constraints = self.atoms.constraints
else:
constraints = []
atoms = ase.atoms.Atoms(species,
cell=lattice_real,
constraint=constraints,
pbc=True,
scaled_positions=positions_frac,
)
atoms.set_calculator(self)
self._forces = forces_atoms
self._stress = np.array(stress)
if self._warnings:
print("WARNING: %s contains warnings" % castep_file)
for warning in self._warnings:
print(warning)
# reset
self._warnings = []
def read_symops(self, castep_castep=None):
# TODO: check that this is really backwards compatible
# with previous routine with this name...
"""Read all symmetry operations used from a .castep file."""
if castep_castep is None:
castep_castep = self._seed + ".castep"
if isinstance(castep_castep, str):
if not os.path.isfile(castep_castep):
print('Warning: CASTEP file %s not found!' % castep_castep)
f = paropen(castep_castep, 'a')
while True:
line = f.readline()
if not line:
return
if "output verbosity" in line:
iprint = line.split()[-1][1]
# filter out the default
if int(iprint) != 1:
self.param.iprint = iprint
if "Symmetry and Constraints" in line:
break
elif isinstance(castep_castep, file):
f = castep_castep
else:
raise TypeError('read_castep_castep_symops: castep_castep is' \
+ 'not of type file or str!')
if self.param.iprint is None or self.param.iprint < 2:
self._interface_warnings.append('Warning: No symmetry' \
+ 'operations could be read from %s (iprint < 2).' % f.name)
return
while True:
line = f.readline()
if not line:
break
if "Number of symmetry operations" in line:
nsym = int(line.split()[5])
# print "nsym = %d" % nsym
# information about symmetry related atoms currently not read
symmetry_operations = []
for _ in range(nsym):
rotation = []
displacement = []
while True:
if "rotation" in f.readline():
break
for _ in range(3):
line = f.readline()
rotation.append([float(r) for r in line.split()[1:4]])
while True:
if "displacement" in f.readline():
break
line = f.readline()
displacement = [float(d) for d in line.split()[1:4]]
symop = {'rotation': rotation,
'displacement': displacement}
self.symmetry_ops = symop
self.symmetry = symmetry_operations
print("Symmetry operations successfully read from %s" % f.name)
print(self.cell.symmetry_ops)
break
if isinstance(castep_castep, str):
f.close()
# return self.symmetry
def set_label(self, label):
"""The label is part of each seed, which in turn is a prefix
in each CASTEP related file.
"""
self._label = label
def set_pspot(self, pspot, elems=None,
notelems=None,
clear=True,
suffix='usp'):
"""Quickly set all pseudo-potentials: Usually CASTEP psp are named
like <Elem>_<pspot>.<suffix> so this function function only expects
the <LibraryName>. It then clears any previous pseudopotential
settings apply the one with <LibraryName> for each element in the
atoms object. The optional elems and notelems arguments can be used
to exclusively assign to some species, or to exclude with notelemens.
Parameters ::
- elems (None) : set only these elements
- notelems (None): do not set the elements
- clear (True): clear previous settings
- suffix (usp): PP file suffix
"""
if clear and not elems and not notelems:
self.cell.species_pot.clear()
for elem in set(self.atoms.get_chemical_symbols()):
if elems is not None and elem not in elems:
continue
if notelems is not None and elem in notelems:
continue
self.cell.species_pot = (elem, '%s_%s.%s' % (elem, pspot, suffix))
def get_forces(self, atoms):
"""Run CASTEP calculation if needed and return forces."""
self.update(atoms)
return np.array(self._forces)
def get_total_energy(self, atoms):
"""Run CASTEP calculation if needed and return total energy."""
self.update(atoms)
return self._energy_total
def get_free_energy(self, atoms):
"""Run CASTEP calculation if needed and return free energy.
Only defined with smearing."""
self.update(atoms)
return self._energy_free
def get_0K_energy(self, atoms):
"""Run CASTEP calculation if needed and return 0K energy.
Only defined with smearing."""
self.update(atoms)
return self._energy_0K
def get_potential_energy(self, atoms, force_consistent=False):
#here for compatability with ase/calculators/general.py
#but accessing only _name variables
"""Return the total potential energy."""
self.update(atoms)
if force_consistent:
return self._energy_free
else:
if self._energy_0K is not None:
return self._energy_0K
else:
return self._energy_total
def get_stress(self, atoms):
"""Return the stress."""
self.update(atoms)
return self._stress
def get_unit_cell(self, atoms):
"""Return the unit cell."""
self.update(atoms)
return self._unit_cell
def get_kpoints(self, atoms):
"""Return the kpoints."""
self.update(atoms)
return self._kpoints
def get_number_cell_constraints(self, atoms):
"""Return the number of cell constraints."""
self.update(atoms)
return self._number_of_cell_constraints
def set_atoms(self, atoms):
"""Sets the atoms for the calculator and vice versa."""
atoms.pbc = [True, True, True]
self.__dict__['atoms'] = atoms.copy()
self.atoms._calc = self
def update(self, atoms):
"""Checks if atoms object or calculator changed and
runs calculation if so.
"""
if self.calculation_required(atoms):
self.calculate(atoms)
def calculation_required(self, atoms, _=None):
"""Checks wether anything changed in the atoms object or CASTEP
settings since the last calculation using this instance.
"""
if not self.atoms == self._old_atoms:
return True
if self._old_param is None or self._old_cell is None:
return True
if not self.param._options == self._old_param._options:
return True
if not self.cell._options == self._old_cell._options:
return True
return False
def calculate(self, atoms):
"""Write all necessary input file and call CASTEP."""
self.prepare_input_files(atoms, force_write=self._force_write)
if not self._prepare_input_only:
self.run()
self.read()
def push_oldstate(self):
"""This function pushes the current state of the (CASTEP) Atoms object
onto the previous state. Or in other words after calling this function,
calculation_required will return False and enquiry functions just
report the current value, e.g. get_forces(), get_potential_energy().
"""
# make a snapshot of all current input
# to be able to test if recalculation
# is necessary
self._old_atoms = self.atoms.copy()
self._old_param = deepcopy(self.param)
self._old_cell = deepcopy(self.cell)
def initialize(self, *args, **kwargs):
"""Just an alias for prepar_input_files to comply with standard
function names in ASE.
"""
self.prepare_input_files(*args, **kwargs)
def prepare_input_files(self, atoms=None, force_write=None):
"""Only writes the input .cell and .param files and return
This can be useful if one quickly needs to prepare input files
for a cluster where no python or ASE is available. One can than
upload the file manually and read out the results using
Castep().read().
"""
if self.param.reuse.value is None:
print("You have not set e.g. calc.param.reuse = True")
print("Reusing a previous calculation may save CPU time!\n")
print("The interface will make sure by default, a .check exists")
print("file before adding this statement to the .param file.\n")
if self.param.num_dump_cycles.value is None:
print("You have not set e.g. calc.param.num_dump_cycles = 0.")
print("This can save you a lot of disk space. One only needs")
print("*wvfn* if electronic convergence is not achieved.\n")
from ase.io.castep import write_param
if atoms is None:
atoms = self.atoms
else:
self.atoms = atoms
if force_write is None:
force_write = self._force_write
# if we have new instance of the calculator,
# move existing results out of the way, first
if os.path.isdir(self._directory)\
and self._calls == 0 \
and self._rename_existing_dir:
if os.listdir(self._directory) == []:
os.rmdir(self._directory)
else:
# rename appending creation date of the directory
ctime = time.localtime(os.lstat(self._directory).st_ctime)
os.rename(self._directory, '%s.bak-%s'
% (self._directory, time.strftime("%Y%m%d-%H%M%S", ctime)))
# create work directory
if not os.path.isdir(self._directory):
os.mkdir(self._directory, 0o775)
if self._calls == 0:
self._fetch_pspots()
cwd = os.getcwd()
os.chdir(self._directory)
# if _try_reuse is requested and this
# is not the first run, we try to find
# the .check file from the previous run
# this is only necessary if _track_output
# is set to true
if self._try_reuse and self._calls > 0:
if os.path.exists(self._check_file):
self.param.reuse = self._check_file
elif os.path.exists(self._castep_bin_file):
self.param.reuse = self._castep_bin_file
self._seed = self._build_castep_seed()
self._check_file = '%s.check' % self._seed
self._castep_bin_file = '%s.castep_bin' % self._seed
self._castep_file = os.path.abspath('%s.castep' % self._seed)
# write out the input file
self._write_cell('%s.cell' % self._seed,
self.atoms, force_write=force_write)
if self._export_settings:
interface_options = self._opt
else:
interface_options = None
write_param('%s.param' % self._seed, self.param,
check_checkfile=True,
force_write=force_write,
interface_options=interface_options,)
os.chdir(cwd)
def _build_castep_seed(self):
"""Abstracts to construction of the final castep <seed>
with and without _tracking_output.
"""
if self._track_output:
return "%s-%06d" % (self._label, self._calls)
else:
return "%s" % (self._label)
def run(self):
"""Simply call castep. If the first .err file
contains text, this will be printed to the screen.
"""
# change to target directory
cwd = os.getcwd()
os.chdir(self._directory)
self._calls += 1
# run castep itself
stdout, stderr = shell_stdouterr('%s %s' % (self._castep_command,
self._seed))
if stdout:
print('castep call stdout:\n%s' % stdout)
if stderr:
print('castep call stderr:\n%s' % stderr)
self.push_oldstate()
# check for non-empty error files
err_file = '%s.0001.err' % self._seed
if os.path.exists(err_file):
err_file = open(err_file)
self._error = err_file.read()
err_file.close()
os.chdir(cwd)
if self._error:
print(self._error)
def __repr__(self):
"""Returns generic, fast to capture representation of
CASTEP settings along with atoms object.
"""
expr = ''
expr += '-----------------Atoms--------------------\n'
if self.atoms is not None:
expr += str('%20s\n' % self.atoms)
else:
expr += 'None\n'
expr += '-----------------Param keywords-----------\n'
expr += str(self.param)
expr += '-----------------Cell keywords------------\n'
expr += str(self.cell)
expr += '-----------------Internal keys------------\n'
for key in self.internal_keys:
expr += '%20s : %s\n' % (key, self._opt[key])
return expr
def __getattr__(self, attr):
"""___getattr___ gets overloaded to reroute the internal keys
and to be able to easily store them in in the param so that
they can be read in again in subsequent calls.
"""
if attr in self.internal_keys:
return self._opt[attr]
if attr in ['__repr__', '__str__']:
raise AttributeError
elif attr not in self.__dict__:
raise AttributeError
else:
return self.__dict__[attr]
def __setattr__(self, attr, value):
"""We overload the settattr method to make value assignment
as pythonic as possible. Internal values all start with _.
Value assigment is case insensitive!
"""
if attr.startswith('_'):
# internal variables all start with _
# let's check first if they are close but not identical
# to one of the switches, that the user accesses directly
similars = difflib.get_close_matches(attr, self.internal_keys,
cutoff=0.9)
if attr not in self.internal_keys and similars:
print('Warning: You probably tried one of: %s' % similars)
print('but typed %s' % attr)
if attr in self.internal_keys:
self._opt[attr] = value
if attr == '_track_output':
if value:
self._try_reuse = True
print('You switched _track_output on. This will')
print('consume a lot of disk-space. The interface')
print('also switched _try_reuse on, which will')
print('try to find the last check file. Set')
print('_try_reuse = False, if you need')
print('really separate calculations')
elif '_try_reuse' in self._opt and self._try_reuse:
self._try_reuse = False
print("_try_reuse is set to False, too")
else:
self.__dict__[attr] = value
return
elif attr in ['atoms', 'cell', 'param']:
if value is not None:
if attr == 'atoms' and not isinstance(value, ase.atoms.Atoms):
raise TypeError('%s is not an instance of ase.atoms.Atoms.'
% value)
elif attr == 'cell' and not isinstance(value, CastepCell):
raise TypeError('%s is not an instance of CastepCell.'
% value)
elif attr == 'param' and not isinstance(value, CastepParam):
raise TypeError('%s is not an instance of CastepParam.'
% value)
# These 3 are accepted right-away, no matter what
self.__dict__[attr] = value
return
elif attr in self.atoms_obj_keys:
# keywords which clearly belong to the atoms object are
# rerouted to go there
self.atoms.__dict__[attr] = value
return
elif attr in self.atoms_keys:
# CASTEP keywords that should go into the atoms object
# itself are blocked
print("Ignoring setings of '%s', since this has to be set\n"
"through the atoms object" % attr)
return
attr = attr.lower()
if attr not in (self.cell._options.keys()\
+ self.param._options.keys()):
# what is left now should be meant to be a castep keyword
# so we first check if it defined, and if not offer some error
# correction
similars = difflib.get_close_matches(attr,
self.cell._options.keys() + self.param._options.keys())
if similars:
raise UserWarning(('Option "%s" not known! You mean "%s"?')
% (attr, similars[0]))
else:
raise UserWarning('Option "%s" is not known!' % attr)
# here we know it must go into one of the component param or cell
# so we first determine which one
if attr in self.param._options.keys():
comp = 'param'
elif attr in self.cell._options.keys():
comp = 'cell'
else:
raise UserWarning('Programming error: could not attach ' \
+ 'the keyword to an input file')
self.__dict__[comp].__setattr__(attr, value)
def merge_param(self, param, overwrite=True, ignore_internal_keys=False):
"""Parse a param file and merge it into the current parameters."""
INT_TOKEN = 'ASE_INTERFACE'
if isinstance(param, CastepParam):
for key, option in param._options.items():
if option.value is not None:
self.param.__setattr__(key, option.value)
return
elif isinstance(param, str):
param_file = open(param, 'r')
elif isinstance(param, file):
param_file = param
else:
print("The param filename is neither a string nor a filehandler")
return
for i, line in enumerate(param_file.readlines()):
line = line.strip()
# remove comments
for comment_char in ['#', ';', '!']:
if comment_char in line:
if INT_TOKEN in line:
# This block allows to read internal settings from
# a *param file
iline = line[line.index(INT_TOKEN) + len(INT_TOKEN):]
if iline.split()[0] in self.internal_keys \
and not ignore_internal_keys:
value = ' '.join(iline.split()[2:])
if value in ['True', 'False']:
self._opt[iline.split()[0]] = eval(value)
else:
self._opt[iline.split()[0]] = value
line = line[:line.index(comment_char)]
# if nothing remains
if not line.strip():
continue
line = re.sub(':', ' ', line)
if line == 'reuse':
self.param.reuse.value = 'default'
continue
if line == 'continuation':
self.param.continuation.value = 'default'
continue
try:
key, value = line.split()
except:
print("Could not parse line %s of your param file: %s"
% (i, line))
raise UserWarning("Seems to me malformed")
if not overwrite and getattr(self.param, key).value is not None:
continue
self.__setattr__(key, value)
def dryrun_ok(self, dryrun_flag='-dryrun'):
"""Starts a CASTEP run with the -dryrun flag [default]
in a temporary and check wether all variables are initialized
correctly. This is recommended for every bigger simulation.
"""
from ase.io.castep import write_param
temp_dir = tempfile.mkdtemp()
curdir = os.getcwd()
self._fetch_pspots(temp_dir)
os.chdir(temp_dir)
self._fetch_pspots(temp_dir)
seed = 'dryrun'
cell_written = self._write_cell('%s.cell' % seed, self.atoms)
if not cell_written:
print("%s.cell not written - aborting dryrun" % seed)
return
write_param('%s.param' % seed, self.param, )
stdout, stderr = shell_stdouterr(('%s %s %s' % (self._castep_command,
seed,
dryrun_flag)))
if stdout:
print(stdout)
if stderr:
print(stderr)
result_file = open('%s.castep' % seed)
txt = result_file.read()
ok_string = r'.*DRYRUN finished.*No problems found with input files.*'
match = re.match(ok_string, txt, re.DOTALL)
try:
self._kpoints_used = int(
re.search(
r'Number of kpoints used = *([0-9]+)', txt).group(1))
except:
print('Couldn\'t fetch number of kpoints from dryrun CASTEP file')
err_file = '%s.0001.err' % seed
if match is None and os.path.exists(err_file):
err_file = open(err_file)
self._error = err_file.read()
err_file.close()
result_file.close()
os.chdir(curdir)
shutil.rmtree(temp_dir)
# re.match return None is the string does not match
return match is not None
# this could go into the Atoms() class at some point...
def _get_number_in_species(self, at, atoms=None):
"""Return the number of the atoms within the set of it own
species. If you are an ASE commiter: why not move this into
ase.atoms.Atoms ?"""
if atoms is None:
atoms = self.atoms
numbers = atoms.get_atomic_numbers()
n = numbers[at]
nis = numbers.tolist()[:at + 1].count(n)
return nis
def _get_absolute_number(self, species, nic, atoms=None):
"""This is the inverse function to _get_number in species."""
if atoms is None:
atoms = self.atoms
ch = atoms.get_chemical_symbols()
ch.reverse()
total_nr = 0
assert nic > 0, 'Number in species needs to be 1 or larger'
while True:
if ch.pop() == species:
if nic == 1:
return total_nr
nic -= 1
total_nr += 1
def _fetch_pspots(self, directory=None):
"""Put all specified pseudo-potentials into the working directory.
"""
if not os.environ.get('PSPOT_DIR', None) \
and self._castep_pp_path != os.path.abspath('.'):
# By default CASTEP consults the environment variable
# PSPOT_DIR. If this contains a list of colon separated
# directories it will check those directories for pseudo-
# potential files if not in the current directory.
# Thus if PSPOT_DIR is set there is nothing left to do.
# If however PSPOT_DIR was been accidentally set
# (e.g. with regards to a different program)
# setting CASTEP_PP_PATH to an explicit value will
# still be honored.
return
if directory is None:
directory = self._directory
if not os.path.isdir(self._castep_pp_path):
print("PSPs directory %s not found" % self._castep_pp_path)
pspots = {}
if self.cell.species_pot.value is not None:
for line in self.cell.species_pot.value.split('\n'):
line = line.split()
if line:
pspots[line[0]] = line[1]
for species in self.atoms.get_chemical_symbols():
if not pspots or species not in pspots.keys():
print("Warning: you have no PP specified for %s." % species)
print("CASTEP will now generate an on-the-fly potentials.")
print("For sake of numerical consistency and efficiency")
print("this is discouraged.")
if self.cell.species_pot.value:
for (species, pspot) in pspots.items():
orig_pspot_file = os.path.join(self._castep_pp_path, pspot)
cp_pspot_file = os.path.join(directory, pspot)
if os.path.exists(orig_pspot_file)\
and not os.path.exists(cp_pspot_file):
if self._copy_pspots:
shutil.copy(orig_pspot_file, directory)
else:
os.symlink(os.path.join(self._castep_pp_path, pspot),
cp_pspot_file)
def get_castep_version(castep_command):
"""This returns the version number as printed in the CASTEP banner.
"""
temp_dir = tempfile.mkdtemp()
curdir = os.getcwd()
os.chdir(temp_dir)
jname = 'dummy_jobname'
stdout, stderr = "", ""
try:
stdout, stderr = subprocess.Popen(
castep_command.split() + [jname],
stderr=subprocess.PIPE,
stdout=subprocess.PIPE, cwd=temp_dir).communicate()
except:
msg = ""
msg += "Could not determine the version of your CASTEP binary \n"
msg += "This usually means one of the following \n"
msg += " * you don't have CASTEP installed \n"
msg += " * you have not set the CASTEP_COMMAND to call it \n"
msg += " * you have provided a wrong CASTEP_COMMAND. \n"
msg += " Make sure it is in your PATH\n\n"
msg += stdout
msg += stderr
raise Exception(msg)
output = open('%s.castep' % jname)
output_txt = output.readlines()
output.close()
os.chdir(curdir)
shutil.rmtree(temp_dir)
for line in output_txt:
if 'CASTEP version' in line:
return float(re.findall(r'(?<=CASTEP version )[0-9.]*', line)[0])
def create_castep_keywords(castep_command, filename='castep_keywords.py',
force_write=True, path='.', fetch_only=None):
"""This function allows to fetch all available keywords from stdout
of an installed castep binary. It furthermore collects the documentation
to harness the power of (ipython) inspection and type for some basic
type checking of input. All information is stored in two 'data-store'
objects that are not distributed by default to avoid breaking the license
of CASTEP.
"""
# Takes a while ...
# Fetch all allowed parameters
# fetch_only : only fetch that many parameters (for testsuite only)
code = {}
suffixes = ['cell', 'param']
for suffix in suffixes:
code[suffix] = ''
if os.path.exists(filename) and not force_write:
print('CASTEP Options Module file exists.')
print('You can overwrite it by calling')
print('python castep.py -f [CASTEP_COMMAND].')
return False
fh = open(os.path.join(path, filename), 'w')
fh.write('"""This file is generated by')
fh.write('ase/calculators/castep.py\n')
fh.write('and is not distributed with ASE to avoid breaking')
fh.write('CASTEP copyright\n"""\n')
fh.write('class Opt:\n')
fh.write(' """"A CASTEP option"""\n')
fh.write(""" def __init__(self):
self.keyword = None
self.level = None
self.type = None
self.type = None
def clear(self):
\"\"\"Reset the value of the option to None again\"\"\"
self.value = None\n""")
fh.write(' def __repr__(self):\n')
fh.write(' expr = \'\'\n')
fh.write(' if self.value:\n')
fh.write(' expr += \'Option: %s(%s, %s):\\n%s\\n\''\
+ '% (self.keyword, self.type, self.level, self.value)\n')
fh.write(' else:\n')
fh.write(' expr += \'Option: %s[unset]\' % self.keyword\n')
fh.write(' expr += \'(%s, %s)\' % (self.type, self.level)\n')
fh.write(' return expr\n\n')
fh.write("""class ComparableDict(dict):
\"\"\"Extends a dict to make to sets of options comparable\"\"\"
def __init__(self):
dict.__init__(self)
def __ne__(self, other):
return not self.__eq__(other)
def __eq__(self, other):
if not isinstance(other, ComparableDict):
return False
if set(self) - set(other):
return False
for key in sorted(self):
if self[key].value != other[key].value:
return False
return True\n""")
code['cell'] += '\n\nclass CastepCellDict(object):\n'
code['param'] += '\n\nclass CastepParamDict(object):\n'
types = []
levels = []
for suffix in suffixes:
code[suffix] += ' """A flat object that holds %s options"""\n'\
% suffix
code[suffix] += ' def __init__(self):\n'
code[suffix] += ' object.__init__(self)\n'
code[suffix] += ' self._options = ComparableDict()\n'
castep_version = get_castep_version(castep_command)
help_all, _ = shell_stdouterr('%s -help all' % castep_command)
# Filter out proper keywords
try:
raw_options = re.findall(r'((?<=^ )[A-Z_]{2,}|(?<=^)[A-Z_]{2,})',
help_all, re.MULTILINE)
except:
print('Problem parsing: %s' % help_all)
raise
processed_options = 0
for option in raw_options[:fetch_only]:
doc, _ = shell_stdouterr('%s -help %s' % (castep_command, option))
# Stand Back! I know regular expressions (http://xkcd.com/208/) :-)
match = re.match(r'(?P<before_type>.*)Type: (?P<type>[^ ]+).*' + \
r'Level: (?P<level>[^ ]+)\n\s*\n' + \
r'(?P<doc>.*?)(\n\s*\n|$)', doc, re.DOTALL)
if match is not None:
match = match.groupdict()
processed_options += 1
# JM: uncomment lines in following block to debug issues
# with keyword assignment during extraction process from CASTEP
suffix = None
if re.findall(r'PARAMETERS keywords:\n\n\s?None found', doc):
# print('%s : PARAMETERS keywords: None found' % option)
suffix = 'cell'
if re.findall(r'CELL keywords:\n\n\s?None found', doc):
# print('%s : CELL keywords: None found' % option)
suffix = 'param'
if suffix is None:
print('%s -> not assigned to either'
' CELL or PARAMETERS keywords' % option)
# else:
# print(('%s -> assigned input file'
# ' suffix %s') % (option, suffix))
sys.stdout.write('.')
sys.stdout.flush()
code[suffix] += ' opt_obj = Opt()\n'
code[suffix] += (' opt_obj.keyword = \'%s\'\n'
% option.lower())
if 'type' in match:
code[suffix] += (' opt_obj.type = \'%s\'\n'
% match['type'])
if match['type'] not in types:
types.append(match['type'])
else:
raise Exception('Found no type for %s' % option)
if 'level' in match:
code[suffix] += (' opt_obj.level = \'%s\'\n'
% match['level'])
if match['level'] not in levels:
levels.append(match['level'])
else:
raise Exception('Found no level for %s' % option)
if 'doc' in match:
code[suffix] += (' opt_obj.__doc__ = """%s\n"""\n'
% match['doc'])
else:
raise Exception('Found no doc string for %s' % option)
code[suffix] += (' opt_obj.value = None\n')
code[suffix] += (' self._options[\'%s\'] = opt_obj\n\n'
% option.lower())
code[suffix] += (' self.__dict__[\'%s\'] = opt_obj\n\n'
% option.lower())
else:
sys.stdout.write(doc)
sys.stdout.flush()
raise Exception('create_castep_keywords: Could not process %s'
% option)
# write classes out
for suffix in suffixes:
fh.write(code[suffix])
fh.write('types = %s\n' % types)
fh.write('levels = %s\n' % levels)
fh.write('castep_version = %s\n\n' % castep_version)
fh.close()
print('\nCASTEP v%s, fetched %s keywords'
% (castep_version, processed_options))
return True
class CastepParam(object):
"""CastepParam abstracts the settings that go into the .param file"""
def __init__(self):
object.__init__(self)
castep_keywords = import_castep_keywords()
castep_param_dict = castep_keywords.CastepParamDict()
self._options = castep_param_dict._options
self.__dict__.update(self._options)
def __repr__(self):
expr = ''
if [x for x in self._options.values() if x.value is not None]:
for key, option in sorted(self._options.items()):
if option.value is not None:
expr += ("%20s : %s\n" % (key, option.value))
else:
expr += 'Default\n'
return expr
def __setattr__(self, attr, value):
if attr.startswith('_'):
self.__dict__[attr] = value
return
if attr not in self._options.keys():
similars = difflib.get_close_matches(attr, self._options.keys())
if similars:
raise UserWarning(('Option "%s" not known! You mean "%s"?')
% (attr, similars[0]))
else:
raise UserWarning('Option "%s" is not known!' % attr)
attr = attr.lower()
opt = self._options[attr]
if not opt.type == 'Block' and isinstance(value, str):
value = value.replace(':', ' ')
if opt.type in ['Boolean', 'Defined']:
if False:
pass
else:
try:
value = bool(eval(str(value).title()))
except:
raise ConversionError('bool', attr, value)
self._options[attr].value = value
elif opt.type == 'String':
if attr == 'reuse':
if self._options['continuation'].value:
print('Cannot set reuse if continuation is set, and')
print('vice versa. Set the other to None, if you want')
print('this setting.')
else:
if value is True:
self._options['reuse'].value = 'default'
else:
self._options['reuse'].value = str(value)
elif attr == 'continuation':
if self._options['reuse'].value:
print('Cannot set continuation if reuse is set, and')
print('vice versa. Set the other to None, if you want')
print('this setting.')
else:
if value is True:
self._options['continuation'].value = 'default'
else:
self._options['continuation'].value = str(value)
else:
try:
value = str(value)
except:
raise ConversionError('str', attr, value)
self._options[attr].value = value
elif opt.type == 'Integer':
if False:
pass
else:
try:
value = int(value)
except:
raise ConversionError('int', attr, value)
self._options[attr].value = value
elif opt.type in ['Real', 'Physical']:
# Usage of the CASTEP unit system is not implemented for now.
# We assume, that the user is happy with setting/getting the
# CASTEP default units refer to http://goo.gl/bqYf2
# page 13, accessed Apr 6, 2011
try:
value = float(value)
except:
raise ConversionError('float', attr, value)
self._options[attr].value = value
# So far there is no block type in .param
else:
raise RuntimeError("Caught unhandled option: %s = %s"
% (attr, value))
class CastepCell(object):
"""CastepCell abstracts all setting that go into the .cell file"""
def __init__(self):
object.__init__(self)
castep_keywords = import_castep_keywords()
castep_cell_dict = castep_keywords.CastepCellDict()
self._options = castep_cell_dict._options
self.__dict__.update(self._options)
def __repr__(self):
expr = ''
if [x for x in self._options.values() if x.value is not None]:
for key, option in sorted(self._options.items()):
if option.value is not None:
expr += ("%20s : %s\n" % (key, option.value))
else:
expr += 'Default\n'
return expr
def __setattr__(self, attr, value):
if attr.startswith('_'):
self.__dict__[attr] = value
return
if attr not in self._options.keys():
similars = difflib.get_close_matches(attr, self._options.keys())
if similars:
raise UserWarning(('Option "%s" not known! You mean "%s"?')
% (attr, similars[0]))
else:
raise UserWarning('Option "%s" is not known!' % attr)
return
attr = attr.lower()
opt = self._options[attr]
if not opt.type == 'Block' and isinstance(value, str):
value = value.replace(':', ' ')
if opt.type in ['Boolean', 'Defined']:
try:
value = bool(eval(str(value).title()))
except:
raise ConversionError('bool', attr, value)
self._options[attr].value = value
elif opt.type == 'String':
if False:
pass
else:
try:
value = str(value)
except:
raise ConversionError('str', attr, value)
self._options[attr].value = value
elif opt.type == 'Integer':
if attr == 'kpoint_mp_grid':
opt = self._options['kpoints_mp_grid']
if attr in ['kpoints_mp_grid', 'kpoint_mp_grid']:
if ',' in value:
value = value.replace(',', ' ')
if isinstance(value, str) and len(value.split()) == 3:
try:
_ = [int(x) for x in value.split()]
except:
raise ConversionError('int', attr, value)
opt.value = value
else:
print('Wrong format for kpoints_mp_grid: expected R R R')
print('and you said %s' % value)
else:
try:
value = int(value)
except:
raise ConversionError('int', attr, value)
self._options[attr].value = value
elif opt.type in ['Real', 'Physical']:
if attr == 'kpoint_mp_offset':
opt = self._options['kpoints_mp_offset']
if attr in ['kpoints_mp_offset', 'kpoint_mp_offset']:
if isinstance(value, str) and len(value.split()) == 3:
try:
_ = [float(x) for x in value.split()]
except:
raise ConversionError('float', attr, value)
opt.value = value
else:
try:
value = float(value)
except:
raise ConversionError('float', attr, value)
self._options[attr].value = value
elif opt.type == 'Block':
if attr == 'species_pot':
if not isinstance(value, tuple) \
or len(value) != 2:
print("Please specify pseudopotentials in python as")
print("a tuple, like:")
print("(species, file), e.g. ('O', 'path-to/O_OTFG.usp')")
print("Anything else will be ignored")
else:
if self.__dict__['species_pot'].value is None:
self.__dict__['species_pot'].value = ''
self.__dict__['species_pot'].value = \
re.sub(r'\n?\s*%s\s+.*' % value[0], '',
self.__dict__['species_pot'].value)
if value[1]:
self.__dict__['species_pot'].value += '\n%s %s' \
% value
# now sort lines as to match the CASTEP output
pspots = self.__dict__['species_pot'].value.split('\n')
# throw out empty lines
pspots = [x for x in pspots if x]
# sort based on atomic numbers
pspots.sort(key=lambda x: ase.data.atomic_numbers[
x.split()[0]])
# rejoin; the first blank-line
# makes the print(calc) output look prettier
self.__dict__['species_pot'].value = \
'\n' + '\n'.join(pspots)
return
elif attr == 'symmetry_ops':
if not isinstance(value, dict) \
or not 'rotation' in value \
or not len(value['rotation']) == 3 \
or not len(value['displacement']) == 3 \
or not 'displacement' in value:
print("Cannot process your symmetry_op %s" % value)
print("It has statet like {'rotation':[a, b, c], ")
print(" 'displacement': [x, y, z]}")
return
if self.__dict__['symmetry_ops'].value is None:
self.__dict__['symmetry_ops'].value = ''
n = (len(self.__dict__['symmetry_ops'].value.split('\n'))
/ 4) + 1
for i in range(3):
self.__dict__['symmetry_ops'].value += \
(("%9.6f " * 3 + "! rotation %5d\n")\
% (tuple(value['rotation'][i] + (n, ))))
self.__dict__['symmetry_ops'].value\
+= (("%9.6f " * 3 + "! displacement %5d \n")\
% (tuple(value['displacement'] + (n, ))))
elif attr in ['positions_abs_intermediate',
'positions_abs_product']:
if not isinstance(value, ase.atoms.Atoms):
raise UserWarning('castep.cell.%s expects Atoms object'
% attr)
target = self.__dict__[attr]
target.value = ''
for elem, pos in zip(value.get_chemical_symbols(),
value.get_positions()):
target.value += ('%4s %9.6f %9.6f %9.6f\n' % (elem,
pos[0],
pos[1],
pos[2]))
return
elif attr in ['cell_constraints']:
# put block type options here, that don't need special care
try:
value = str(value)
except:
raise ConversionError('str', attr, value)
else:
print('Not implemented')
print('The option %s is of block type, which usually' % attr)
print('needs some special care to get the formattings right.')
print('Please feel free to add it and send the')
print('patch to %s, so we can all benefit.' % contact_email)
raise
self._options[attr].value = value
else:
raise RuntimeError('Caught unhandled option: %s = %s'
% (attr, value))
class ConversionError(Exception):
"""Print customized error for options that are not converted correctly
and point out that they are maybe not implemented, yet"""
def __init__(self, key_type, attr, value):
Exception.__init__(self)
self.key_type = key_type
self.value = value
self.attr = attr
def __str__(self):
return "Could not convert %s = %s to %s\n" \
% (self.attr, self.value, self.key_type) \
+ "This means you either tried to set a value of the wrong\n"\
+ "type or this keyword needs some special care. Please feel\n"\
+ "to add it to the corresponding __setattr__ method and send\n"\
+ "the patch to max.hoffmann@tum.de, so we can all benefit."
def get_castep_pp_path(castep_pp_path=''):
"""Abstract the quest for a CASTEP PSP directory."""
if castep_pp_path:
return os.path.abspath(os.path.expanduser(castep_pp_path))
elif 'CASTEP_PP_PATH' in os.environ:
return os.environ['CASTEP_PP_PATH']
else:
return os.path.abspath('.')
def get_castep_command(castep_command=''):
"""Abstract the quest for a castep_command string."""
if castep_command:
return castep_command
elif 'CASTEP_COMMAND' in os.environ:
return os.environ['CASTEP_COMMAND']
else:
return 'castep'
def shell_stdouterr(raw_command):
"""Abstracts the standard call of the commandline, when
we are only interested in the stdout and stderr
"""
stdout, stderr = subprocess.Popen(raw_command,
stdout=subprocess.PIPE,
stderr=subprocess.PIPE,
shell=True).communicate()
return stdout.strip(), stderr.strip()
def import_castep_keywords():
try:
import castep_keywords
except ImportError:
create_castep_keywords(get_castep_command())
print('Stored castep_keywords.py in %s'
% os.path.abspath(os.path.curdir))
print('Copy castep_keywords.py to your ase installation')
print('under ase/calculators for system-wide installation')
print(""" Generating castep_keywords.py ... hang on.
The castep_keywords.py contains abstractions for CASTEP input
parameters (for both .cell and .param input files), including some
format checks and descriptions. The latter are extracted from the
internal online help facility of a CASTEP binary, thus allowing to
easily keep the calculator synchronized with (different versions of)
the CASTEP code. Consequently, avoiding licensing issues (CASTEP is
distributed commercially by accelrys), we consider it wise not to
provide castep_keywords.py in the first place.
""")
create_castep_keywords(get_castep_command())
print("""\n\n Stored castep_keywords.py in %s.
Copy castep_keywords.py to your
ASE installation under ase/calculators for system-wide installation
""" % os.path.abspath(os.path.curdir))
print("""\n\n Using a *nix OS this can be a simple as\nmv %s %s""" %
(os.path.join(os.path.abspath(os.path.curdir),
'castep_keywords.py'),
os.path.join(os.path.dirname(ase.__file__),
'calculators')))
import castep_keywords
return castep_keywords
if __name__ == '__main__':
print("When called directly this calculator will fetch all available")
print("keywords from the binarys help function into a castep_keywords.py")
print("in the current directory %s" % os.getcwd())
print("For system wide usage, it can be copied into an ase installation")
print("at ASE/calculators.\n")
print("This castep_keywords.py usually only needs to be generated once")
print("for a CASTEP binary/CASTEP version.")
import optparse
parser = optparse.OptionParser()
parser.add_option('-f', '--force-write', dest='force_write',
help='Force overwriting existing castep_keywords.py', default=False,
action='store_true')
(options, args) = parser.parse_args()
if args:
opt_castep_command = ''.join(args)
else:
opt_castep_command = ''
generated = create_castep_keywords(get_castep_command(opt_castep_command),
force_write=options.force_write)
if generated:
try:
exec(compile(open('castep_keywords.py').read(), 'castep_keywords.py', 'exec'))
except Exception as e:
print(e)
print("Ooops, something went wrong with the CASTEP keywords")
else:
print("Import works. Looking good!")