Source code for triqs_tprf.wannier90

################################################################################
#
# TPRF: a Two-Particle Response Function Toolbox
#
# Copyright (C) 2018 by The Simons Foundation
# Author: H. U.R. Strand
#
# TPRF 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.
#
# TPRF 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
# TPRF. If not, see <http://www.gnu.org/licenses/>.
#
################################################################################

import numpy as np
from StringIO import StringIO
from collections import OrderedDict

# ----------------------------------------------------------------------

#import ase.units as units

class Units(object):
    Bohr = 0.5291772105638411
    Angstrom = 1.0

units = Units()

# ----------------------------------------------------------------------
[docs]def parse_hopping_from_wannier90_hr_dat(filename): r""" Wannier90 real space hopping parser of ``*_hr.dat`` files. Returns a dictionary where the keys are the real-space hopping vectors, in terms of multiples of the lattice vectors, and the values are ``num_wann * num_wann`` numpy ndarrays with the hopping integrals. Parameters ---------- filename : str Wannier90 ``*_hr.dat`` file to parse. Returns ------- hopp_dict : dict Dictionary of real space hoppings. num_wann : int Total number of Wannier functions per unit-cell. """ with open(filename, 'r') as fd: lines = fd.readlines() lines.pop(0) # pop time header num_wann = int(lines.pop(0)) nrpts = int(lines.pop(0)) #print 'num_wann =', num_wann #print 'nrpts =', nrpts nlines = int(np.ceil(float(nrpts / 15.))) deg = np.array([]) for line in lines[:nlines]: deg = np.concatenate((deg, np.loadtxt(StringIO(line), dtype=np.int, ndmin=1))) assert( deg.shape == (nrpts,) ) hopp = "".join(lines[nlines:]) hopp = np.loadtxt(StringIO(hopp)) assert( hopp.shape == (num_wann**2 * nrpts, 7) ) R = np.array(hopp[:, :3], dtype=np.int) # Lattice coordinates in multiples of lattice vectors nm = np.array(hopp[:, 3:5], dtype=np.int) - 1 # orbital index pairs, wannier90 counts from 1, fix by remove 1 t_re = hopp[:, 5] t_im = hopp[:, 6] t = t_re + 1.j * t_im # complex hopping amplitudes for each R, mn (H(R)_{mn}) # -- Dict with hopping matrices r_dict = OrderedDict() hopp_dict = {} for idx in xrange(R.shape[0]): r = tuple(R[idx]) if r not in r_dict: r_dict[r] = 1 else: r_dict[r] += 1 if r not in hopp_dict: hopp_dict[r] = np.zeros((num_wann, num_wann), dtype=np.complex) n, m = nm[idx] hopp_dict[r][n, m] = t[idx] # -- Account for degeneracy of the Wigner-Seitz points for r, weight in zip(r_dict.keys(), deg): hopp_dict[r] /= weight return hopp_dict, num_wann
# ----------------------------------------------------------------------
[docs]def parse_lattice_vectors_from_wannier90_wout(filename): r""" Wannier90 real space lattice vectors parser of ``*.wout`` files. Parameters ---------- filename : str Wannier90 ``*.wout`` file to parse. Returns ------- vectors : list of three three-tuples of floats Lattice vectors. """ with open(filename, 'r') as fd: lines = fd.readlines() # -- Find start of data in text file for idx, line in enumerate(lines): if 'Lattice Vectors' in line: if '(Ang)' in line: unit = units.Angstrom elif '(Bohr)' in line: unit = units.Bohr else: raise NotImplementedError break if not 'Lattice Vectors' in line: raise IOError lines = "".join(lines[idx+1:idx+4]) array = np.loadtxt(StringIO(lines), usecols=(1, 2, 3)) array *= unit # -- convert 3x3 array to list of tuples vectors = [] for idx in xrange(array.shape[0]): v = tuple(array[idx]) vectors.append(v) return vectors
# ----------------------------------------------------------------------
[docs]def parse_reciprocal_lattice_vectors_from_wannier90_wout(filename): r""" Wannier90 reciprocal space lattice vectors parser of ``*.wout`` files. Parameters ---------- filename : str Wannier90 ``*.wout`` file to parse. Returns ------- vectors : list of three three-tuples of floats Reciprocal lattice vectors. """ with open(filename, 'r') as fd: lines = fd.readlines() # -- Find start of data in text file for idx, line in enumerate(lines): if 'Reciprocal-Space Vectors (Ang^-1)' in line: break lines = "".join(lines[idx+1:idx+4]) array = np.loadtxt(StringIO(lines), usecols=(1, 2, 3)) # -- convert 3x3 array to list of tuples vectors = [] for idx in xrange(array.shape[0]): v = tuple(array[idx]) vectors.append(v) return vectors
# ----------------------------------------------------------------------
[docs]def parse_band_structure_from_wannier90_band_dat(filename): r""" Wannier90 band structure parser of ``*_band.dat``` files. Parameters ---------- filename : str Wannier90 ``*_band.dat`` file to parse. Returns ------- E : ndarray (2D) Band energies. w : ndarray (1D) k-space path points. """ with open(filename, 'r') as fd: lines = fd.readlines() # -- Count the number of empty lines num_wann = 0 for line in lines: if line.strip(' ') == '\n': num_wann += 1 lines = "".join(lines) data = np.loadtxt(StringIO(lines)).T n_pts = data.shape[-1] data = data.reshape(2, num_wann, n_pts/num_wann) w, E = data[0], data[1] return E, w