mirror of
https://github.com/triqs/dft_tools
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432 lines
17 KiB
Python
432 lines
17 KiB
Python
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################################################################################
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#
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# TRIQS: a Toolbox for Research in Interacting Quantum Systems
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#
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# Copyright (C) 2011 by M. Aichhorn, L. Pourovskii, V. Vildosola
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#
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# TRIQS is free software: you can redistribute it and/or modify it under the
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# terms of the GNU General Public License as published by the Free Software
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# Foundation, either version 3 of the License, or (at your option) any later
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# version.
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#
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# TRIQS is distributed in the hope that it will be useful, but WITHOUT ANY
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# WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
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# FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
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# details.
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#
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# You should have received a copy of the GNU General Public License along with
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# TRIQS. If not, see <http://www.gnu.org/licenses/>.
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#
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################################################################################
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#=======================================================================================================================
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# #################################################################
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# Code for Transport/Optic calculations based on SumK_LDA... class
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# by Xiaoyu Deng <xiaoyu.deng@gmail.com>
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# The code read in files needed for transport/Optic calculations from Wien outputs.
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# including: symmetry, velocity, lattice constants.
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# The HDF convention is not adopted here since momentum file from Wien output is usually quite large
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# and it is not necessary to keep in in the HDF file.
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# #################################################################
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#=======================================================================================================================
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import numpy, sys, os.path
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def Read_Fortran_File (filename):
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""" Returns a generator that yields all numbers in the Fortran file as float, one by one"""
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import os.path
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if not(os.path.exists(filename)) : raise IOError, "File %s does not exists" % filename
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for line in open(filename, 'r') :
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for x in line.replace('D', 'E').split() :
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yield string.atof(x)
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class Velocity_k:
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"""momentum matrix for a single k points.
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"""
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def __init__(self):
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self.kp = [0.0, 0.0, 0.0]
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self.bandwin = [999, 0]
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# here a matrix for 3 vels. use list since the size of vel is to be determined.
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self.vel = []
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class Velocities:
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"""Class containig the velocities.
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Provides container for velocities
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as a function of k and method to read them from case.pmat Wien2k file
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use as ClassInstance.vks[ik].vel[iband][jband][ix]
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"""
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def __init__(self, wiencase, spinbl=""):
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if not(os.path.exists(wiencase + ".pmat" + spinbl)) : raise IOError, "File %s does not exists" % wiencase + ".pmat"
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# expected format:
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# k nu nu2 (k denotes k-point, nu1 starting band index, nu2 ending band index
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# kpos ( read in if needed.
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# (real, im) (of velocity for all nu <=nu_prime within nu1 and nu2)
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# ... ...
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# k nu nu2
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# ...
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f = open(wiencase + ".pmat" + spinbl)
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self.vks = []
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while 1:
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try:
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s = f.readline()
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if (s == ""):
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break
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except:
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break
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try:
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vec = Velocity_k()
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[k, nu1, nu2] = [int (x) for x in s.strip().split()]
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vec.bandwin[0] = nu1
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vec.bandwin[1] = nu2
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vec.kp = f.readline().strip().split()
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dim = vec.bandwin[1] - vec.bandwin[0] + 1
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shape = (dim, dim, 3)
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vxyz = numpy.zeros(shape, dtype=complex)
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for nu in xrange(dim):
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for nu_prime in xrange(nu, dim):
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for i in xrange(3):
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s = f.readline().strip("\n ()").split(',')
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vxyz[nu][nu_prime][i] = float(s[0]) + float(s[1]) * 1j
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if(nu_prime != nu):
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vxyz[nu_prime][nu][i] = vxyz[nu][nu_prime][i].conjugate()
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vec.vel = vxyz
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self.vks.append(vec)
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except IOError:
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print("Reading case.pmat error. Wrong format?\n ")
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raise
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f.close()
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def getvel(self, k):
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# should return array at a given k. use as [iband][jband][i]
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return self.vks[k].vel
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def plot(self):
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f = open("velband.dat", "w")
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bandid = numpy.array([vk.bandwin for vk in self.vks]).flatten()
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minb = bandid.min()
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maxb = bandid.max()
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for ib in range(minb, maxb + 1):
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ik = 0
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for vk in self.vks:
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if(vk.bandwin[0] <= ib and vk.bandwin[1] >= ib):
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f.write(str(ik) + " ")
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for i in range(3):
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f.write(str(vk.vel[ib - vk.bandwin[0]][ib - vk.bandwin[0]][i].real) + " ")
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f.write("\n")
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ik = ik + 1
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f.write("&\n")
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f.close()
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class SGsymmetry():
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""" read in symmetry of space group from wiencase.outputs other than wiencase.struct since
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in this file there are also symmetry operations in xyz coordinates..
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"""
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def __init__(self, wiencase):
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structfile = wiencase + ".outputs"
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self.nsymm = 1
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self.symm = []
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self.tau = []
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self.bravaismatrix = numpy.zeros((3, 3), dtype=numpy.float_)
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self.symmcartesian = []
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self.taucartesian = []
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with open(structfile, "r") as f:
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f.readline()
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f.readline()# bravais matrix
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for i in range(3):
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line = f.readline().strip().split()
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self.bravaismatrix[i, :] = numpy.array([numpy.float(item) for item in line])[:]
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print "bravais matrix", self.bravaismatrix
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while 1:
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s = f.readline().strip(" ").split()
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try:
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if(s[0] == "PGBSYM:"):
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self.nsymm = int(s[-1])
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break
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except:
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continue
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f.readline()
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f.readline()
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for i in range(self.nsymm):
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f.readline()
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## read symmcartesian
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symmt = numpy.zeros((3, 3), dtype=float)
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taut = numpy.zeros((3), dtype=float)
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for ir in range(3):
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s = f.readline().strip().split()
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for ic in range(3):
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symmt[ir, ic] = float(s[ic])
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s = f.readline().strip().split()
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for ir in range(3):
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taut[ir] = float(s[ir])
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self.symmcartesian.append(symmt)
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self.taucartesian.append(taut)
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##read symm
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symmt = numpy.zeros((3, 3), dtype=float)
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taut = numpy.zeros((3), dtype=float)
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for ir in range(3):
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s = f.readline().strip().split()
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for ic in range(3):
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symmt[ir, ic] = float(s[ic])
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taut[ir] = float(s[3])
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self.symm.append(symmt)
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self.tau.append(taut)
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f.readline()
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# end
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f.close()
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print "Read wiencase.outputs done!"
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def checksymmxyz(self):
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''' This is to check symm in cartesian coordinates and in primitive cell lattice
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For details of symm, one should check wien/SRC_symmetry/, latsym.f, pglsym.f,pgbsym.f
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In general, if a lattice is orthorhombic, then symmcartesian is the same as symmprimitive
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(at most different by a transpose (or inversion)). If a lattice is not orthorhombic, these two symms could
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be related by bravais matrix.
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One special case is CXZ lattice. In Wien CXZ lattice contains two cases: orthorhombic, and
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monoclinic (with only gamma not equal to 90). For CXZ lattice monoclinic, symmcartesian is also the same as
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symmprimitive (or with transpose (or inversion)).
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'''
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for i in range(self.nsymm):
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mat = self.symmcartesian[i].transpose() # according to wien2k, why?
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bm = self.bravaismatrix
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bminv = numpy.linalg.inv(bm)#.transpose()
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res = numpy.dot(bminv, numpy.dot(mat, bm)) - self.symm[i]
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print i, res
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def size(self):
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return self.nsymm
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def cellvolume(latticetype, latticeconstants, latticeangle):
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""" calculate cell volume: volumecc conventional cell, volumepc, primitive cell.
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"""
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for i in range(3):
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latticeangle[i] *= 1.0 / 180 * numpy.pi
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a = latticeconstants[0]
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b = latticeconstants[1]
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c = latticeconstants[2]
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c_al = numpy.cos(latticeangle[0])
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c_be = numpy.cos(latticeangle[1])
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c_ga = numpy.cos(latticeangle[2])
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volumecc = a * b * c * numpy.sqrt(1 + 2 * c_al * c_be * c_ga - c_al ** 2 - c_be * 82 - c_ga ** 2)
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det = {"P":1,
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"F":4,
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"B":2,
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"R":3,
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"H":1,
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"CXY":2,
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"CYZ":2,
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"CXZ":2
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}
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volumepc = volumecc / det[latticetype]
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return volumecc, volumepc
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class WienStruct():
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""" parsing Wien Struct file
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"""
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def __init__(self, wiencase):
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structfile = wiencase + ".struct"
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with open(structfile, "r") as infile:
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print "read in Wien case file %s" % structfile
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infile.readline()#title
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tem = infile.readline() #lattice
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self.latticetype = tem[0:10].split()[0]
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self.ineqvsite = int(tem[27:30])
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try:
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self.sgrnumber = int(tem[30:33])
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except:
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self.sgrnumber = None
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try:
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self.sgrlabel = tem[34:38]
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except:
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self.sgrlabel = None
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print self.latticetype, self.ineqvsite, self.sgrnumber, self.sgrlabel
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infile.readline()
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tem = infile.readline() # lattice constants
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self.latticeconstants = [float(tem[0:10]), float(tem[10:20]), float(tem[20:30])]
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self.latticeangle = [float(tem[30:40]), float(tem[40:50]), float(tem[50:60])]
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print "Cell"
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print self.latticeconstants[:]
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print self.latticeangle[:]
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self.positions = []
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self.atomsymbols = []
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self.multi = []
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self.atomnumbers = []
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self.locrotmatrix = []
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for isite in range(self.ineqvsite):
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tem = infile.readline()
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positions = []
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positions.append([float(tem[12:22]), float(tem[25:35]), float(tem[38:48])])
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tem = infile.readline()
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multi = int(tem[15:17])
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self.multi.append(multi)
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for im in range(multi - 1):
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tem = infile.readline()
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positions.append([float(tem[12:22]), float(tem[25:35]), float(tem[38:48])])
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#print positions
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self.positions.append(positions)
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#print self.positions
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tem = infile.readline().strip(" ").split()
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self.atomsymbols.append(tem[0])
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self.atomnumbers.append(float(tem[-1]))
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mat = numpy.zeros((3, 3), dtype=numpy.float_)
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tem = infile.readline().strip(" ").split()
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#print tem[-3:],mat[0,:]
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mat[0, :] = tem[-3:]
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tem = infile.readline().strip(" ").split()
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mat[1, :] = tem[-3:]
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tem = infile.readline().strip(" ").split()
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mat[2, :] = tem[-3:]
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self.locrotmatrix.append(mat)
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for ia in range(len(self.atomsymbols)):
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print "atom symbol : %s atom number: %d atom multi: %d" % (self.atomsymbols[ia], self.atomnumbers[ia], self.multi[ia])
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print "positions:"
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for im in self.positions[ia]:
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print im[:]
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# symmetry with lattice vector
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tem = infile.readline().strip(" ").split()
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self.symm = []
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self.tau = []
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self.Nsymm = int(tem[0])
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for isymm in range(self.Nsymm):
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symmt = numpy.zeros((3, 3), dtype=float)
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taut = numpy.zeros((3), dtype=float)
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for ir in range(3):
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s = infile.readline()
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for ic in range(3):
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symmt[ir][ic] = float(s[ic * 2:ic * 2 + 2])
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taut[ir] = float(s[7:17])
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self.symm.append(symmt)
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self.tau.append(taut)
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infile.readline()
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#############
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print "Read in %s.struct done!" % wiencase
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## convential Cell Volume and primitive Cell. In bohr^3 unit
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self.VolumeCC, self.VolumePC = cellvolume(self.latticetype, self.latticeconstants, self.latticeangle)
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def readSGsymm(self, wiencase):
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""" read in symmetry of space group from wiencase.outputs other than wiencase.struct since
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in this file there are also symmetry operations in xyz coordinates..
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"""
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structfile = wiencase + ".outputs"
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self.nsymm = 1
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self.symm = []
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self.tau = []
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# note bravaismatrix is not accurate enough in wiencase.outputs file. Just use it for test.
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self.bravaismatrix = numpy.zeros((3, 3), dtype=numpy.float_)
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self.symmcartesian = []
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self.taucartesian = []
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with open(structfile, "r") as f:
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f.readline()
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f.readline()# bravais matrix
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for i in range(3):
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line = f.readline().strip().split()
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self.bravaismatrix[i, :] = numpy.array([numpy.float(item) for item in line])[:]
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print "bravais matrix", self.bravaismatrix
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while 1:
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try:
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s = f.readline().strip(" ").split()
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if(s[0] == "PGBSYM:"):
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self.nsymm = int(s[-1])
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break
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except:
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assert "Error in read case.outputs"
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#f.readline()
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#f.readline()
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for i in range(self.nsymm):
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while 1:
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s = f.readline().strip().split()
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if s[0] == "Symmetry":
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break
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## read symmcartesian
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symmt = numpy.zeros((3, 3), dtype=float)
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taut = numpy.zeros((3), dtype=float)
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for ir in range(3):
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s = f.readline().strip().split()
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for ic in range(3):
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symmt[ir, ic] = float(s[ic])
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s = f.readline().strip().split()
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for ir in range(3):
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taut[ir] = float(s[ir])
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self.symmcartesian.append(symmt)
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self.taucartesian.append(taut)
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##read symm
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symmt = numpy.zeros((3, 3), dtype=float)
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taut = numpy.zeros((3), dtype=float)
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for ir in range(3):
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s = f.readline().strip().split()
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for ic in range(3):
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symmt[ir, ic] = numpy.float(s[ic])
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taut[ir] = numpy.float(s[3])
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self.symm.append(symmt)
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self.tau.append(taut)
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# end
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f.close()
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def checksymmxyz(self):
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''' This is to check symm in cartesian coordinates and in primitive cell lattice
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For details of symm, should check wien/SRC_symmetry/, latsym.f, pglsym.f,pgbsym.f
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In general, if a lattice is orthorhombic, then symmcartesian is the same as symmprimitive
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(at most different by a transpose (or inversion)). If a lattice is not orthorhombic, these two symms could
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be related by bravais matrix.
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One special case is CXZ lattice. In Wien CXZ lattice contains two cases: orthorhombic, and
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monoclinic (with only gamma not equal to 90). For CXZ lattice monoclinic, symmcartesian is also the same as
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symmprimitive (or with transpose (or inversion)).
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'''
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ortho = numpy.abs(numpy.array(self.latticeangle) - 90.0).sum() <= 1e-6
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for i in range(self.nsymm):
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mat = self.symmcartesian[i].transpose() # according to wien2k, why?
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res = mat
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if (not ortho) and (self.latticetype != "CXZ") :
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bm = self.bravaismatrix
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bminv = numpy.linalg.inv(bm)#.transpose()
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res = numpy.dot(bminv, numpy.dot(mat, bm))
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res -= self.symm[i]
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print i, numpy.abs(res).sum()
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## primitive cell vectors.+
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