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dft_tools/python/converters/plovasp/vaspio.py

710 lines
24 KiB
Python

################################################################################
#
# TRIQS: a Toolbox for Research in Interacting Quantum Systems
#
# Copyright (C) 2011 by M. Ferrero, O. Parcollet
#
# DFT tools: Copyright (C) 2011 by M. Aichhorn, L. Pourovskii, V. Vildosola
#
# PLOVasp: Copyright (C) 2015 by O. E. Peil
#
# TRIQS is free software: you can redistribute it and/or modify it under the
# terms of the GNU General Public License as published by the Free Software
# Foundation, either version 3 of the License, or (at your option) any later
# version.
#
# TRIQS is distributed in the hope that it will be useful, but WITHOUT ANY
# WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
# FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
# details.
#
# You should have received a copy of the GNU General Public License along with
# TRIQS. If not, see <http://www.gnu.org/licenses/>.
#
################################################################################
r"""
vasp.vaspio
===========
Input of required VASP data.
Six VASP files are required:
- PROJCAR
- LOCPROJ
- POSCAR
- IBZKPT
- EIGENVAL
- DOSCAR
"""
import numpy as np
import re
#import plocar_io.c_plocar_io as c_plocar_io
def read_lines(filename):
r"""
Generator of lines for a file
Parameters
----------
filename (str) : name of the file
"""
with open(filename, 'r') as f:
for line in f:
yield line
################################################################################
################################################################################
#
# class VaspData
#
################################################################################
################################################################################
class VaspData:
"""
Container class for all VASP data.
"""
def __init__(self, vasp_dir, read_all=True, efermi_required=True):
self.vasp_dir = vasp_dir
self.plocar = Plocar()
self.poscar = Poscar()
self.kpoints = Kpoints()
self.eigenval = Eigenval()
self.doscar = Doscar()
if read_all:
self.plocar.from_file(vasp_dir)
self.poscar.from_file(vasp_dir)
self.kpoints.from_file(vasp_dir)
try:
self.eigenval.from_file(vasp_dir)
except (IOError, StopIteration):
self.eigenval.eigs = None
self.eigenval.ferw = None
print "!!! WARNING !!!: Error reading from EIGENVAL, trying LOCPROJ"
try:
self.doscar.from_file(vasp_dir)
except (IOError, StopIteration):
if efermi_required:
# raise Exception("Efermi cannot be read from DOSCAR")
pass
else:
# TODO: This a hack. Find out a way to determine ncdij without DOSCAR
print "!!! WARNING !!!: Error reading from DOSCAR, taking Efermi from config"
self.doscar.ncdij = self.plocar.nspin
################################################################################
################################################################################
#
# class Plocar
#
################################################################################
################################################################################
class Plocar:
r"""
Class containing raw PLO data from VASP.
Properties
----------
- *plo* (numpy.array((nion, ns, nk, nb, nlmmax))) : raw projectors
- *params* (dict) : parameters read from PLOCAR
- *ferw* (array(nion, ns, nk, nb)) : Fermi weights from VASP
"""
def from_file(self, vasp_dir='./', plocar_filename='PLOCAR'):
r"""
Reads non-normalized projectors from a binary file (`PLOCAR' by default)
generated by VASP PLO interface.
Parameters
----------
vasp_dir (str) : path to the VASP working directory [default = `./']
plocar_filename (str) : filename [default = `PLOCAR']
"""
# Add a slash to the path name if necessary
if vasp_dir[-1] != '/':
vasp_dir += '/'
# self.params, self.plo, self.ferw = c_plocar_io.read_plocar(vasp_dir + plocar_filename)
# self.proj_params, self.plo = self.temp_parser(projcar_filename=vasp_dir + "PROJCAR", locproj_filename=vasp_dir + "LOCPROJ")
self.proj_params, self.plo = self.locproj_parser(locproj_filename=vasp_dir + "LOCPROJ")
def temp_parser(self, projcar_filename='PROJCAR', locproj_filename='LOCPROJ'):
r"""
Parses PROJCAR (and partially LOCPROJ) to get VASP projectors.
This is a prototype parser that should eventually be written in C for
better performance on large files.
Returns projector parameters (site/orbital indices etc.) and an array
with projectors.
"""
orb_labels = ["s", "py", "pz", "px", "dxy", "dyz", "dz2", "dxz", "dx2-y2",
"fz3", "fxz2", "fyz2", "fz(x2-y2)", "fxyz", "fx(x2-3y2)", "fy(3x2-y2)"]
def lm_to_l_m(lm):
l = int(np.sqrt(lm))
m = lm - l*l
return l, m
# Read the first line of LOCPROJ to get the dimensions
with open(locproj_filename, 'rt') as f:
line = f.readline()
nproj, nspin, nk, nband = map(int, line.split())
plo = np.zeros((nproj, nspin, nk, nband), dtype=np.complex128)
proj_params = [{} for i in xrange(nproj)]
iproj_site = 0
is_first_read = True
with open(projcar_filename, 'rt') as f:
line = self.search_for(f, "^ *ISITE")
while line:
isite = int(line.split()[1])
if not is_first_read:
for il in xrange(norb):
ip_new = iproj_site * norb + il
ip_prev = (iproj_site - 1) * norb + il
proj_params[ip_new]['label'] = proj_params[ip_prev]['label']
proj_params[ip_new]['isite'] = isite
proj_params[ip_new]['l'] = proj_params[ip_prev]['l']
proj_params[ip_new]['m'] = proj_params[ip_prev]['m']
for ispin in xrange(nspin):
for ik in xrange(nk):
# Parse the orbital labels and convert them to l,m-indices
line = self.search_for(f, "^ *band")
if is_first_read:
cpatt = re.compile("lm= *([^\s]+)")
labels = re.findall(cpatt, line)
norb = len(labels)
for il, label in enumerate(labels):
lm = orb_labels.index(label)
l, m = lm_to_l_m(lm)
# For the first read 'iproj_site = 0' and only orbital index 'il' is used
proj_params[il]['label'] = label
proj_params[il]['isite'] = isite
proj_params[il]['l'] = l
proj_params[il]['m'] = m
is_first_read = False
# Read the block of nk * ns * nband complex numbers
for ib in xrange(nband):
line = f.readline()
rtmp = map(float, line.split()[1:])
for il in xrange(norb):
ctmp = complex(rtmp[2 * il], rtmp[2 * il + 1])
plo[iproj_site * norb + il, ispin, ik, ib] = ctmp
# End of site-block
iproj_site += 1
line = self.search_for(f, "^ *ISITE")
print "Read parameters:"
for il, par in enumerate(proj_params):
print il, " -> ", par
return proj_params, plo
def locproj_parser(self, locproj_filename='LOCPROJ'):
r"""
Parses LOCPROJ (for VASP >= 5.4.2) to get VASP projectors.
This is a prototype parser that should eventually be written in C for
better performance on large files.
Returns projector parameters (site/orbital indices etc.) and an array
with projectors.
"""
orb_labels = ["s", "py", "pz", "px", "dxy", "dyz", "dz2", "dxz", "dx2-y2",
"fy(3x2-y2)", "fxyz", "fyz2", "fz3", "fxz2", "fz(x2-y2)", "fx(x2-3y2)"]
def lm_to_l_m(lm):
l = int(np.sqrt(lm))
m = lm - l*l
return l, m
# Read the first line of LOCPROJ to get the dimensions
with open(locproj_filename, 'rt') as f:
line = f.readline()
line = line.split("#")[0]
sline = line.split()
self.ncdij, nk, self.nband, nproj = map(int, sline[:4])
self.nspin = 1 if self.ncdij == 1 else 2
self.nspin_band = 2 if self.ncdij == 2 else 1
self.efermi = float(sline[4])
plo = np.zeros((nproj, self.nspin, nk, self.nband), dtype=np.complex128)
proj_params = [{} for i in xrange(nproj)]
iproj_site = 0
is_first_read = True
# First read the header block with orbital labels
line = self.search_for(f, "^ *ISITE")
ip = 0
while line:
sline = line.split(':')
isite = int(sline[1].split()[0])
label = sline[-1].strip()
lm = orb_labels.index(label)
l, m = lm_to_l_m(lm)
# ip_new = iproj_site * norb + il
# ip_prev = (iproj_site - 1) * norb + il
proj_params[ip]['label'] = label
proj_params[ip]['isite'] = isite
proj_params[ip]['l'] = l
proj_params[ip]['m'] = m
ip += 1
line = f.readline().strip()
assert ip == nproj, "Number of projectors in the header is wrong in LOCPROJ"
self.eigs = np.zeros((nk, self.nband, self.nspin_band))
self.ferw = np.zeros((nk, self.nband, self.nspin_band))
patt = re.compile("^orbital")
# FIXME: fix spin indices for NCDIJ = 4 (non-collinear)
assert self.ncdij < 4, "Non-collinear case is not implemented"
for ispin in xrange(self.nspin):
for ik in xrange(nk):
for ib in xrange(self.nband):
line = ""
while not line:
line = f.readline().strip()
sline = line.split()
isp_, ik_, ib_ = map(int, sline[1:4])
assert isp_ == ispin + 1 and ik_ == ik + 1 and ib_ == ib + 1, "Inconsistency in reading LOCPROJ"
self.eigs[ik, ib, ispin] = float(sline[4])
self.ferw[ik, ib, ispin] = float(sline[5])
for ip in xrange(nproj):
line = f.readline()
sline = line.split()
ctmp = complex(float(sline[1]), float(sline[2]))
plo[ip, ispin, ik, ib] = ctmp
print "Read parameters:"
for il, par in enumerate(proj_params):
print il, " -> ", par
return proj_params, plo
def search_for(self, f, patt):
r"""
Reads file 'f' until pattern 'patt' is encountered and returns
the corresponding line.
"""
cpatt = re.compile(patt)
line = "x"
while not re.match(cpatt, line) and line:
line = f.readline()
return line
################################################################################
################################################################################
#
# class Poscar
#
################################################################################
################################################################################
class Poscar:
"""
Class containing POSCAR data from VASP.
Properties
----------
nq (int) : total number of ions
ntypes ([int]) : number of ion types
nions (int) : a list of number of ions of each type
a_brav (numpy.array((3, 3), dtype=float)) : lattice vectors
q_types ([numpy.array((nions, 3), dtype=float)]) : a list of
arrays each containing fractional coordinates of ions of a given type
"""
def __init__(self):
self.q_cart = None
self.b_rec = None
def from_file(self, vasp_dir='./', poscar_filename='POSCAR'):
"""
Reads POSCAR and returns a dictionary.
Parameters
----------
vasp_dir (str) : path to the VASP working directory [default = `./']
plocar_filename (str) : filename [default = `PLOCAR']
"""
# Convenince local function
def readline_remove_comments():
return f.next().split('!')[0].strip()
# Add a slash to the path name if necessary
if vasp_dir[-1] != '/':
vasp_dir += '/'
f = read_lines(vasp_dir + poscar_filename)
# Comment line
comment = f.next().rstrip()
print " Found POSCAR, title line: %s"%(comment)
# Read scale
sline = readline_remove_comments()
ascale = float(sline)
# Read lattice vectors
self.a_brav = np.zeros((3, 3))
for ia in xrange(3):
sline = readline_remove_comments()
self.a_brav[ia, :] = map(float, sline.split())
# Negative scale means that it is a volume scale
if ascale < 0:
vscale = -ascale
vol = np.linalg.det(self.a_brav)
ascale = (vscale / vol)**(1.0/3)
self.a_brav *= ascale
# Depending on the version of VASP there could be
# an extra line with element names
sline = readline_remove_comments()
try:
# Old v4.6 format: no element names
self.nions = map(int, sline.split())
self.el_names = ['El%i'%(i) for i in xrange(len(self.nions))]
except ValueError:
# New v5.x format: read element names first
self.el_names = sline.split()
sline = readline_remove_comments()
self.nions = map(int, sline.split())
# Set the number of atom sorts (types) and the total
# number of atoms in the unit cell
self.ntypes = len(self.nions)
self.nq = sum(self.nions)
# Check for the line 'Selective dynamics' (and ignore it)
sline = readline_remove_comments()
if sline[0].lower() == 's':
sline = readline_remove_comments()
# Check whether coordinates are cartesian or fractional
cartesian = (sline[0].lower() in 'ck')
if cartesian:
brec = np.linalg.inv(self.a_brav.T)
# Read atomic positions
self.q_types = []
self.type_of_ion = []
for it in xrange(self.ntypes):
# Array mapping ion index to type
self.type_of_ion += self.nions[it] * [it]
q_at_it = np.zeros((self.nions[it], 3))
for iq in xrange(self.nions[it]):
sline = readline_remove_comments()
qcoord = map(float, sline.split()[:3])
if cartesian:
qcoord = np.dot(brec, qcoord)
q_at_it[iq, :] = qcoord
self.q_types.append(q_at_it)
print " Total number of ions:", self.nq
print " Number of types:", self.ntypes
print " Number of ions for each type:", self.nions
# print
# print " Coords:"
# for it in xrange(ntypes):
# print " Element:", el_names[it]
# print q_at[it]
################################################################################
################################################################################
#
# class Kpoints
#
################################################################################
################################################################################
class Kpoints:
"""
Class describing k-points and optionally tetrahedra.
Properties
----------
- nktot (int) : total number of k-points in the IBZ
- kpts (numpy.array((nktot, 3), dtype=float)) : k-point vectors (fractional coordinates)
- ntet (int) : total number of k-point tetrahedra
- itet (numpy.array((ntet, 5), dtype=float) : array of tetrahedra
- volt (float) : volume of a tetrahedron (the k-grid is assumed to
be uniform)
"""
#
# Reads IBZKPT file
#
def from_file(self, vasp_dir='./', ibz_filename='IBZKPT'):
"""
Reads from IBZKPT: k-points and optionally
tetrahedra topology (if present).
Parameters
----------
vasp_dir (str) : path to the VASP working directory [default = `./']
plocar_filename (str) : filename [default = `PLOCAR']
"""
# Add a slash to the path name if necessary
if vasp_dir[-1] != '/':
vasp_dir += '/'
ibz_file = read_lines(vasp_dir + ibz_filename)
# Skip comment line
line = ibz_file.next()
# Number of k-points
line = ibz_file.next()
self.nktot = int(line.strip().split()[0])
print
print " {0:>26} {1:d}".format("Total number of k-points:", self.nktot)
self.kpts = np.zeros((self.nktot, 3))
self.kwghts = np.zeros((self.nktot))
# Skip comment line
line = ibz_file.next()
for ik in xrange(self.nktot):
line = ibz_file.next()
sline = line.strip().split()
self.kpts[ik, :] = map(float, sline[:3])
self.kwghts[ik] = float(sline[3])
self.kwghts /= self.nktot
# Attempt to read tetrahedra
# Skip comment line ("Tetrahedra")
try:
line = ibz_file.next()
# Number of tetrahedra and volume = 1/(6*nkx*nky*nkz)
line = ibz_file.next()
sline = line.split()
self.ntet = int(sline[0])
self.volt = float(sline[1])
print " {0:>26} {1:d}".format("Total number of tetrahedra:", self.ntet)
# Traditionally, itet[it, 0] contains multiplicity
self.itet = np.zeros((self.ntet, 5), dtype=int)
for it in xrange(self.ntet):
line = ibz_file.next()
self.itet[it, :] = map(int, line.split()[:5])
except StopIteration, ValueError:
print " No tetrahedron data found in %s. Skipping..."%(ibz_filename)
self.ntet = 0
# data = { 'nktot': nktot,
# 'kpts': kpts,
# 'ntet': ntet,
# 'itet': itet,
# 'volt': volt }
#
# return data
################################################################################
################################################################################
#
# class Eigenval
#
################################################################################
################################################################################
class Eigenval:
"""
Class containing Kohn-Sham-eigenvalues data from VASP (EIGENVAL file).
"""
def __init__(self):
self.eigs = None
self.ferw = None
def from_file(self, vasp_dir='./', eig_filename='EIGENVAL'):
"""
Reads eigenvalues from EIGENVAL. Note that the file also
contains k-points with weights. They are also stored and
then used to check the consistency of files read.
"""
# Add a slash to the path name if necessary
if vasp_dir[-1] != '/':
vasp_dir += '/'
f = read_lines(vasp_dir + eig_filename)
# First line: only the first and the last number out of four
# are used; these are 'nions' and 'ispin'
sline = f.next().split()
self.nq = int(sline[0])
self.ispin = int(sline[3])
# Second line: cell volume and lengths of lattice vectors (skip)
sline = f.next()
# Third line: temperature (skip)
sline = f.next()
# Fourth and fifth line: useless
sline = f.next()
sline = f.next()
# Sixth line: NELECT, NKTOT, NBTOT
sline = f.next().split()
self.nelect = int(sline[0])
self.nktot = int(sline[1])
self.nband = int(sline[2])
# Set of eigenvalues and k-points
self.kpts = np.zeros((self.nktot, 3))
self.kwghts = np.zeros((self.nktot,))
self.eigs = np.zeros((self.nktot, self.nband, self.ispin))
self.ferw = np.zeros((self.nktot, self.nband, self.ispin))
for ik in xrange(self.nktot):
sline = f.next() # Empty line
sline = f.next() # k-point info
tmp = map(float, sline.split())
self.kpts[ik, :] = tmp[:3]
self.kwghts[ik] = tmp[3]
for ib in xrange(self.nband):
sline = f.next().split()
tmp = map(float, sline)
assert len(tmp) == 2 * self.ispin + 1, "EIGENVAL file is incorrect (probably from old versions of VASP)"
self.eigs[ik, ib, :] = tmp[1:self.ispin+1]
self.ferw[ik, ib, :] = tmp[self.ispin+1:]
################################################################################
################################################################################
#
# class Doscar
#
################################################################################
################################################################################
class Doscar:
"""
Class containing some data from DOSCAR
"""
def from_file(self, vasp_dir='./', dos_filename='DOSCAR'):
"""
Reads only E_Fermi from DOSCAR.
"""
# Add a slash to the path name if necessary
if vasp_dir[-1] != '/':
vasp_dir += '/'
f = read_lines(vasp_dir + dos_filename)
# First line: NION, NION, JOBPAR, NCDIJ
sline = f.next().split()
self.ncdij = int(sline[3])
# Skip next 4 lines
for _ in xrange(4):
sline = f.next()
# Sixth line: EMAX, EMIN, NEDOS, EFERMI, 1.0
sline = f.next().split()
self.efermi = float(sline[3])
# TODO: implement output of SYMMCAR in VASP and read it here
################################################################
#
# Reads SYMMCAR
#
################################################################
def read_symmcar(vasp_dir, symm_filename='SYMMCAR'):
"""
Reads SYMMCAR.
"""
# Shorthand for simple parsing
def extract_int_par(parname):
return int(re.findall(parname + '\s*=\s*(\d+)', line)[-1])
# Add a slash to the path name if necessary
if vasp_dir[-1] != '/':
vasp_dir += '/'
symmcar_exist = False
sym_file = read_lines(vasp_dir + symm_filename)
line = sym_file.next()
nrot = extract_int_par('NROT')
line = sym_file.next()
ntrans = extract_int_par('NPCELL')
# Lmax
line = sym_file.next()
lmax = extract_int_par('LMAX')
mmax = 2 * lmax + 1
# Nion
line = sym_file.next()
nion = extract_int_par('NION')
print " {0:>26} {1:d}".format("Number of rotations:", nrot)
print " {0:>26} {1:d}".format("Number of translations:", ntrans)
print " {0:>26} {1:d}".format("Number of ions:", nion)
print " {0:>26} {1:d}".format("L_max:", lmax)
rot_mats = np.zeros((nrot, lmax+1, mmax, mmax))
rot_map = np.zeros((nrot, ntrans, nion), dtype=np.int32)
for irot in xrange(nrot):
# Empty line
line = sym_file.next()
# IROT index (skip it)
line = sym_file.next()
# ISYMOP matrix (can be also skipped)
line = sym_file.next()
line = sym_file.next()
line = sym_file.next()
# Skip comment " Permutation map..."
line = sym_file.next()
# Permutations (in chunks of 20 indices per line)
for it in xrange(ntrans):
for ibl in xrange((nion - 1) / 20 + 1):
i1 = ibl * 20
i2 = (ibl + 1) * 20
line = sym_file.next()
rot_map[irot, it, i1:i2] = map(int, line.split())
for l in xrange(lmax + 1):
mmax = 2 * l + 1
# Comment: "L = ..."
line = sym_file.next()
for m in xrange(mmax):
line = sym_file.next()
rot_mats[irot, l, m, :mmax] = map(float, line.split()[:mmax])
data.update({ 'nrot': nrot, 'ntrans': ntrans,
'lmax': lmax, 'nion': nion,
'sym_rots': rot_mats, 'perm_map': rot_map })