def test_rwStr_pdb_CdSe(self):
"""check conversion to PDB file format"""
stru = self.stru
stru.read(datafile('CdSe_bulk.stru'), 'pdffit')
#print stru.description
s = stru.writeStr(self.format)
# all lines should be 80 characters long
linelens = [ len(l) for l in s.split('\n') if l != "" ]
self.assertEqual(linelens, len(linelens)*[80])
# now clean and re-read structure
stru = Structure()
stru.readStr(s, self.format)
#print stru.description
s_els = [a.symbol for a in stru]
f_els = ['Cd', 'Cd', 'Se', 'Se']
self.assertEqual(s_els, f_els)
s_lat = [ stru.lattice.a, stru.lattice.b, stru.lattice.c,
stru.lattice.alpha, stru.lattice.beta, stru.lattice.gamma ]
f_lat = [ 4.235204, 4.235204, 6.906027, 90.0, 90.0, 120.0 ]
self.assertListAlmostEqual(s_lat, f_lat)
a0 = stru[0]
s_Uii = [ a0.U[i,i] for i in range(3) ]
f_Uii = [ 0.01303035, 0.01303035, 0.01401959 ]
self.assertListAlmostEqual(s_Uii, f_Uii)
s_sigUii = [ a0.sigU[i,i] for i in range(3) ]
f_sigUii = [ 0.00011127, 0.00011127, 0.00019575 ]
self.assertListAlmostEqual(s_sigUii, f_sigUii)
s_title = stru.description
f_title = "Cell structure file of CdSe #186"
self.assertEqual(s_title, f_title)
def test_rwStr_pdb_CdSe(self):
"""check conversion to PDB file format"""
stru = self.stru
stru.read(datafile('CdSe_bulk.stru'), 'pdffit')
#print stru.description
s = stru.writeStr(self.format)
# all lines should be 80 characters long
linelens = [len(l) for l in s.split('\n') if l != ""]
self.assertEqual(linelens, len(linelens) * [80])
# now clean and re-read structure
stru = Structure()
stru.readStr(s, self.format)
#print stru.description
s_els = [a.symbol for a in stru]
f_els = ['Cd', 'Cd', 'Se', 'Se']
self.assertEqual(s_els, f_els)
s_lat = [
stru.lattice.a, stru.lattice.b, stru.lattice.c, stru.lattice.alpha,
stru.lattice.beta, stru.lattice.gamma
]
f_lat = [4.235204, 4.235204, 6.906027, 90.0, 90.0, 120.0]
self.assertListAlmostEqual(s_lat, f_lat)
a0 = stru[0]
s_Uii = [a0.U[i, i] for i in range(3)]
f_Uii = [0.01303035, 0.01303035, 0.01401959]
self.assertListAlmostEqual(s_Uii, f_Uii)
s_sigUii = [a0.sigU[i, i] for i in range(3)]
f_sigUii = [0.00011127, 0.00011127, 0.00019575]
self.assertListAlmostEqual(s_sigUii, f_sigUii)
s_title = stru.description
f_title = "Cell structure file of CdSe #186"
self.assertEqual(s_title, f_title)
def parseLines(self, lines):
"""Parse list of lines in RAWXYZ format.
Return Structure object or raise StructureFormatError.
"""
linefields = [l.split() for l in lines]
# prepare output structure
stru = Structure()
# find first valid record
start = 0
for field in linefields:
if len(field) == 0 or field[0] == "#":
start += 1
else:
break
# find the last valid record
stop = len(lines)
while stop > start and len(linefields[stop - 1]) == 0:
stop -= 1
# get out for empty structure
if start >= stop:
return stru
# here we have at least one valid record line
# figure out xyz layout from the first line for plain and raw formats
floatfields = [isfloat(f) for f in linefields[start]]
nfields = len(linefields[start])
if nfields not in (3, 4):
emsg = ("%d: invalid RAWXYZ format, expected 3 or 4 columns" %
(start + 1))
raise StructureFormatError(emsg)
if floatfields[:3] == [True, True, True]:
el_idx, x_idx = (None, 0)
elif floatfields[:4] == [False, True, True, True]:
el_idx, x_idx = (0, 1)
else:
emsg = "%d: invalid RAWXYZ format" % (start + 1)
raise StructureFormatError(emsg)
# now try to read all record lines
try:
p_nl = start
for fields in linefields[start:]:
p_nl += 1
if fields == []:
continue
elif len(fields) != nfields:
emsg = ('%d: all lines must have ' +
'the same number of columns') % p_nl
raise StructureFormatError, emsg
symbol = el_idx is not None and fields[el_idx] or ""
xyz = [float(f) for f in fields[x_idx:x_idx + 3]]
if len(xyz) == 2:
xyz.append(0.0)
stru.addNewAtom(symbol, xyz=xyz)
except ValueError:
emsg = "%d: invalid number" % p_nl
exc_type, exc_value, exc_traceback = sys.exc_info()
raise StructureFormatError, emsg, exc_traceback
return stru
def parseLines(self, lines):
"""Parse list of lines in RAWXYZ format.
Return Structure object or raise StructureFormatError.
"""
linefields = [l.split() for l in lines]
# prepare output structure
stru = Structure()
# find first valid record
start = 0
for field in linefields:
if len(field) == 0 or field[0] == "#":
start += 1
else:
break
# find the last valid record
stop = len(lines)
while stop > start and len(linefields[stop-1]) == 0:
stop -= 1
# get out for empty structure
if start >= stop:
return stru
# here we have at least one valid record line
# figure out xyz layout from the first line for plain and raw formats
floatfields = [ isfloat(f) for f in linefields[start] ]
nfields = len(linefields[start])
if nfields not in (3, 4):
emsg = ("%d: invalid RAWXYZ format, expected 3 or 4 columns" %
(start + 1))
raise StructureFormatError(emsg)
if floatfields[:3] == [True, True, True]:
el_idx, x_idx = (None, 0)
elif floatfields[:4] == [False, True, True, True]:
el_idx, x_idx = (0, 1)
else:
emsg = "%d: invalid RAWXYZ format" % (start + 1)
raise StructureFormatError(emsg)
# now try to read all record lines
try:
p_nl = start
for fields in linefields[start:] :
p_nl += 1
if fields == []:
continue
elif len(fields) != nfields:
emsg = ('%d: all lines must have ' +
'the same number of columns') % p_nl
raise StructureFormatError, emsg
symbol = el_idx is not None and fields[el_idx] or ""
xyz = [ float(f) for f in fields[x_idx:x_idx+3] ]
if len(xyz) == 2:
xyz.append(0.0)
stru.addNewAtom(symbol, xyz=xyz)
except ValueError:
emsg = "%d: invalid number" % p_nl
exc_type, exc_value, exc_traceback = sys.exc_info()
raise StructureFormatError, emsg, exc_traceback
return stru
def setUp(self):
# load test structures once
if TestSuperCell.stru_cdse is None:
cdsefile = os.path.join(testdata_dir, "CdSe_bulk.stru")
TestSuperCell.stru_cdse = Structure(filename=cdsefile)
if TestSuperCell.stru_ni is None:
nifile = os.path.join(testdata_dir, "Ni.stru")
TestSuperCell.stru_ni = Structure(filename=nifile)
# bring them to the instance
self.stru_cdse = TestSuperCell.stru_cdse
self.stru_ni = TestSuperCell.stru_ni
return
def __init__(self, *args, **kwargs):
Structure.__init__(self, *args, **kwargs)
# do not overwrite self.pdffit, when instantiated as a copy
# of existing PDFFitStructure
if not hasattr(self, 'pdffit'):
self.pdffit = {
'scale': 1.0,
'delta1': 0.0,
'delta2': 0.0,
'sratio': 1.0,
'rcut': 0.0,
'spcgr': 'P1',
'spdiameter': 0.0,
'stepcut': 0.0,
'dcell': 6 * [0.0],
'ncell': [1, 1, 1, 0],
}
return
def __init__(self, *args, **kwargs):
Structure.__init__(self, *args, **kwargs)
# do not overwrite self.pdffit, when instantiated as a copy
# of existing PDFFitStructure
if not hasattr(self, 'pdffit'):
self.pdffit = {
'scale' : 1.0,
'delta1' : 0.0,
'delta2' : 0.0,
'sratio' : 1.0,
'rcut' : 0.0,
'spcgr' : 'P1',
'spdiameter' : 0.0,
'stepcut' : 0.0,
'dcell' : 6*[0.0],
'ncell' : [1, 1, 1, 0],
}
return
def test_rwStr_xcfg_CdSe(self):
"""check conversion to XCFG file format"""
stru = self.stru
stru.read(datafile('CdSe_bulk.stru'), 'pdffit')
s = stru.writeStr(self.format)
stru = Structure()
stru.readStr(s, self.format)
s_els = [a.symbol for a in stru]
f_els = ['Cd', 'Cd', 'Se', 'Se']
self.assertEqual(s_els, f_els)
s_lat = [ stru.lattice.a, stru.lattice.b, stru.lattice.c,
stru.lattice.alpha, stru.lattice.beta, stru.lattice.gamma ]
f_lat = [ 4.235204, 4.235204, 6.906027, 90.0, 90.0, 120.0 ]
self.assertListAlmostEqual(s_lat, f_lat)
a0 = stru[0]
s_Uii = [ a0.U[i,i] for i in range(3) ]
f_Uii = [ 0.01303035, 0.01303035, 0.01401959 ]
self.assertListAlmostEqual(s_Uii, f_Uii)
def test_writeStr_xyz_Supercell(self):
at1 = Atom('Al', [0.0, 0.0, 0.0])
at2 = Atom('Al', [0.0, 0.5, 0.5])
at3 = Atom('Al', [0.5, 0.0, 0.5])
at4 = Atom('Al', [0.5, 0.5, 0.0])
self.stru4 = Structure([at1, at2, at3, at4],
lattice=Lattice(4.05, 4.05, 4.05, 90, 90, 90),
sgid=225)
from danse.ins.matter.expansion import supercell
al_333 = supercell(self.stru4, (3, 3, 3))
s1 = al_333.writeStr(self.format)
def readStr(self, s, format='auto'):
"""Same as Structure.readStr, but update spcgr value in
self.pdffit when parser can get spacegroup.
Return instance of StructureParser used to load the data.
See Structure.readStr() for more info.
"""
p = Structure.readStr(self, s, format)
sg = getattr(p, 'spacegroup', None)
if sg: self.pdffit['spcgr'] = sg.short_name
return p
def readStr(self, s, format='auto'):
"""Same as Structure.readStr, but update spcgr value in
self.pdffit when parser can get spacegroup.
Return instance of StructureParser used to load the data.
See Structure.readStr() for more info.
"""
p = Structure.readStr(self, s, format)
sg = getattr(p, 'spacegroup', None)
if sg: self.pdffit['spcgr'] = sg.short_name
return p
def test_rwStr_xcfg_CdSe(self):
"""check conversion to XCFG file format"""
stru = self.stru
stru.read(datafile('CdSe_bulk.stru'), 'pdffit')
s = stru.writeStr(self.format)
stru = Structure()
stru.readStr(s, self.format)
s_els = [a.symbol for a in stru]
f_els = ['Cd', 'Cd', 'Se', 'Se']
self.assertEqual(s_els, f_els)
s_lat = [
stru.lattice.a, stru.lattice.b, stru.lattice.c, stru.lattice.alpha,
stru.lattice.beta, stru.lattice.gamma
]
f_lat = [4.235204, 4.235204, 6.906027, 90.0, 90.0, 120.0]
self.assertListAlmostEqual(s_lat, f_lat)
a0 = stru[0]
s_Uii = [a0.U[i, i] for i in range(3)]
f_Uii = [0.01303035, 0.01303035, 0.01401959]
self.assertListAlmostEqual(s_Uii, f_Uii)
def test_al_supercell(self):
"""check supercell expansion for Al.
"""
at1 = Atom('Al', [0.0, 0.0, 0.0])
at2 = Atom('Al', [0.0, 0.5, 0.5])
at3 = Atom('Al', [0.5, 0.0, 0.5])
at4 = Atom('Al', [0.5, 0.5, 0.0])
self.stru4 = Structure([at1, at2, at3, at4],
lattice=Lattice(4.05, 4.05, 4.05, 90, 90, 90),
sgid=225)
al_sup = supercell(self.stru4, (3, 3, 3))
#print al_sup
return
def test_naI_supercell(self):
"""check supercell expansion for Al.
"""
at1 = Atom('Na', [0.0, 0.0, 0.0])
at2 = Atom('Na', [0.0, 0.5, 0.5])
at3 = Atom('Na', [0.5, 0.0, 0.5])
at4 = Atom('Na', [0.5, 0.5, 0.0])
at5 = Atom('I', [0.5, 0.5, 0.5])
at6 = Atom('I', [0.0, 0.0, 0.5])
at7 = Atom('I', [0.0, 0.5, 0.0])
at8 = Atom('I', [0.5, 0.0, 0.0])
naI = Structure([at1, at2, at3, at4, at5, at6, at7, at8],
lattice=Lattice(6.482, 6.482, 6.482, 90, 90, 90),
sgid=225)
for sym, pos in zip(naI.symbols, naI.xyz_cartn):
print sym + ' %f %f %f' % tuple(pos)
print
naI_sup = supercell(naI, (2, 2, 2))
for sym, pos in zip(naI_sup.symbols, naI_sup.xyz_cartn):
print sym + ' %f %f %f' % tuple(pos)
def setUp(self):
self.stru = Structure()
self.format = "rawxyz"
def parseLines(self, lines):
"""Parse list of lines in PDB format.
Return Structure object or raise StructureFormatError.
"""
xcfg_Number_of_particles = None
xcfg_A = None
xcfg_H0 = numpy.zeros((3, 3), dtype=float)
xcfg_H0_set = numpy.zeros((3, 3), dtype=bool)
xcfg_NO_VELOCITY = False
xcfg_entry_count = None
xcfg_auxiliary = []
p_nl = 0
p_auxiliary_re = re.compile(r"^auxiliary\[(\d+)\] =")
p_auxiliary = {}
try:
stru = Structure()
# ignore trailing blank lines
stop = len(lines)
while stop > 0 and lines[stop - 1].strip() == "":
stop -= 1
ilines = iter(lines[:stop])
# read XCFG header
for line in ilines:
p_nl += 1
stripped_line = line.strip()
# blank lines and lines starting with # are ignored
if stripped_line == "" or line[0] == '#':
continue
elif xcfg_Number_of_particles is None:
if line.find("Number of particles =") != 0:
emsg = ("%d: first line must " +
"contain 'Number of particles ='") % p_nl
raise StructureFormatError(emsg)
xcfg_Number_of_particles = int(line[21:].split(None, 1)[0])
p_natoms = xcfg_Number_of_particles
elif line.find("A =") == 0:
xcfg_A = float(line[3:].split(None, 1)[0])
elif line.find("H0(") == 0:
i, j = (int(line[3]) - 1, int(line[5]) - 1)
xcfg_H0[i, j] = float(line[10:].split(None, 1)[0])
xcfg_H0_set[i, j] = True
elif line.find(".NO_VELOCITY.") == 0:
xcfg_NO_VELOCITY = True
elif line.find("entry_count =") == 0:
xcfg_entry_count = int(line[13:].split(None, 1)[0])
elif p_auxiliary_re.match(line):
m = p_auxiliary_re.match(line)
idx = int(m.group(1))
p_auxiliary[idx] = line[m.end():].split(None, 1)[0]
else:
break
# check header for consistency
if numpy.any(xcfg_H0_set == False):
emsg = "H0 tensor is not properly defined"
raise StructureFormatError(emsg)
p_auxnum = len(p_auxiliary) and max(p_auxiliary.keys()) + 1
for i in range(p_auxnum):
if not i in p_auxiliary:
p_auxiliary[i] = "aux%d" % i
sorted_aux_keys = p_auxiliary.keys()
sorted_aux_keys.sort()
if p_auxnum != 0:
stru.xcfg = {
'auxiliaries': [p_auxiliary[k] for k in sorted_aux_keys]
}
if 6 - 3 * xcfg_NO_VELOCITY + len(p_auxiliary) != xcfg_entry_count:
emsg = ("%d: auxiliary fields " +
"not consistent with entry_count") % p_nl
raise StructureFormatError(emsg)
# define proper lattice
stru.lattice.setLatBase(xcfg_H0)
# build p_assign_atom function to assign entries to proper fields
p_exprs = [
"a.xyz[0]=fields[0]", "a.xyz[1]=fields[1]",
"a.xyz[2]=fields[2]"
]
if not xcfg_NO_VELOCITY:
p_exprs += [
"a.v=numpy.zeros(3, dtype=float)", "a.v[0]=fields[3]",
"a.v[1]=fields[4]", "a.v[2]=fields[5]"
]
for idx in sorted_aux_keys:
prop = p_auxiliary[idx]
col = idx + 6 - 3 * xcfg_NO_VELOCITY
if prop == "Uiso":
p_exprs.append("a.U[0,0]=a.U[1,1]=a.U[2,2]=" +
"fields[%d]" % col)
elif re.match(r"^U\d\d$", prop) \
and 1<=int(prop[1])<=3 and 1<=int(prop[2])<=3 :
i, j = int(prop[1]) - 1, int(prop[2]) - 1
if i == j:
p_exprs.append("a.U[%i,%i]=fields[%d]" % (i, j, col))
else:
p_exprs.append("a.U[%i,%i]=a.U[%i,%i]=fields[%d]" % \
(i, j, j, i, col) )
else:
p_exprs.append( "a.__dict__[%r]=fields[%d]" % \
(prop, col) )
p_assign_expr = "pass; " + "; ".join(p_exprs[3:])
exec "def p_assign_atom(a, fields) : %s" % p_assign_expr
# here we are inside data
p_element = None
p_nl -= 1
for line in lines[p_nl:stop]:
p_nl += 1
words = line.split()
# ignore atom mass
if len(words) == 1 and isfloat(words[0]):
continue
# parse element allowing empty symbol
elif len(words) <= 1:
w = line.strip()
p_element = w[:1].upper() + w[1:].lower()
elif len(words) == xcfg_entry_count and p_element is not None:
fields = [float(w) for w in words]
stru.addNewAtom(p_element, fields[:3])
a = stru.getLastAtom()
a.xyz *= xcfg_A
p_assign_atom(a, fields)
else:
emsg = "%d: invalid record" % p_nl
raise StructureFormatError(emsg)
if len(stru) != p_natoms:
emsg = "expected %d atoms, read %d" % (p_natoms, len(stru))
raise StructureFormatError(emsg)
except (ValueError, IndexError):
emsg = "%d: file is not in XCFG format" % p_nl
exc_type, exc_value, exc_traceback = sys.exc_info()
raise StructureFormatError, emsg, exc_traceback
return stru
def parseLines(self, lines):
"""Parse list of lines in PDB format.
Return Structure object or raise StructureFormatError.
"""
xcfg_Number_of_particles = None
xcfg_A = None
xcfg_H0 = numpy.zeros((3,3), dtype=float)
xcfg_H0_set = numpy.zeros((3,3), dtype=bool)
xcfg_NO_VELOCITY = False
xcfg_entry_count = None
xcfg_auxiliary = []
p_nl = 0
p_auxiliary_re = re.compile(r"^auxiliary\[(\d+)\] =")
p_auxiliary = {}
try:
stru = Structure()
# ignore trailing blank lines
stop = len(lines)
while stop>0 and lines[stop-1].strip() == "":
stop -= 1
ilines = iter(lines[:stop])
# read XCFG header
for line in ilines:
p_nl += 1
stripped_line = line.strip()
# blank lines and lines starting with # are ignored
if stripped_line == "" or line[0] == '#':
continue
elif xcfg_Number_of_particles is None:
if line.find("Number of particles =") != 0:
emsg = ("%d: first line must " +
"contain 'Number of particles ='") % p_nl
raise StructureFormatError(emsg)
xcfg_Number_of_particles = int(line[21:].split(None, 1)[0])
p_natoms = xcfg_Number_of_particles
elif line.find("A =") == 0:
xcfg_A = float(line[3:].split(None, 1)[0])
elif line.find("H0(") == 0:
i, j = ( int(line[3])-1 , int(line[5])-1 )
xcfg_H0[i,j] = float(line[10:].split(None, 1)[0])
xcfg_H0_set[i,j] = True
elif line.find(".NO_VELOCITY.") == 0:
xcfg_NO_VELOCITY = True
elif line.find("entry_count =") == 0:
xcfg_entry_count = int(line[13:].split(None, 1)[0])
elif p_auxiliary_re.match(line):
m = p_auxiliary_re.match(line)
idx = int(m.group(1))
p_auxiliary[idx] = line[m.end():].split(None, 1)[0]
else:
break
# check header for consistency
if numpy.any(xcfg_H0_set == False):
emsg = "H0 tensor is not properly defined"
raise StructureFormatError(emsg)
p_auxnum = len(p_auxiliary) and max(p_auxiliary.keys())+1
for i in range(p_auxnum):
if not i in p_auxiliary:
p_auxiliary[i] = "aux%d" % i
sorted_aux_keys = p_auxiliary.keys()
sorted_aux_keys.sort()
if p_auxnum != 0:
stru.xcfg = {
'auxiliaries' : [ p_auxiliary[k]
for k in sorted_aux_keys ]
}
if 6-3*xcfg_NO_VELOCITY+len(p_auxiliary) != xcfg_entry_count:
emsg = ("%d: auxiliary fields " +
"not consistent with entry_count") % p_nl
raise StructureFormatError(emsg)
# define proper lattice
stru.lattice.setLatBase(xcfg_H0)
# build p_assign_atom function to assign entries to proper fields
p_exprs = [ "a.xyz[0]=fields[0]",
"a.xyz[1]=fields[1]",
"a.xyz[2]=fields[2]" ]
if not xcfg_NO_VELOCITY:
p_exprs += [ "a.v=numpy.zeros(3, dtype=float)",
"a.v[0]=fields[3]",
"a.v[1]=fields[4]",
"a.v[2]=fields[5]" ]
for idx in sorted_aux_keys:
prop = p_auxiliary[idx]
col = idx + 6 - 3*xcfg_NO_VELOCITY
if prop == "Uiso":
p_exprs.append("a.U[0,0]=a.U[1,1]=a.U[2,2]=" +
"fields[%d]" % col)
elif re.match(r"^U\d\d$", prop) \
and 1<=int(prop[1])<=3 and 1<=int(prop[2])<=3 :
i, j = int(prop[1])-1, int(prop[2])-1
if i==j:
p_exprs.append("a.U[%i,%i]=fields[%d]" % (i, j, col) )
else:
p_exprs.append("a.U[%i,%i]=a.U[%i,%i]=fields[%d]" % \
(i, j, j, i, col) )
else:
p_exprs.append( "a.__dict__[%r]=fields[%d]" % \
(prop, col) )
p_assign_expr = "pass; " + "; ".join(p_exprs[3:])
exec "def p_assign_atom(a, fields) : %s" % p_assign_expr
# here we are inside data
p_element = None
p_nl -= 1
for line in lines[p_nl:stop]:
p_nl += 1
words = line.split()
# ignore atom mass
if len(words) == 1 and isfloat(words[0]):
continue
# parse element allowing empty symbol
elif len(words) <= 1:
w = line.strip()
p_element = w[:1].upper() + w[1:].lower()
elif len(words) == xcfg_entry_count and p_element is not None:
fields = [ float(w) for w in words ]
stru.addNewAtom(p_element, fields[:3])
a = stru.getLastAtom()
a.xyz *= xcfg_A
p_assign_atom(a, fields)
else:
emsg = "%d: invalid record" % p_nl
raise StructureFormatError(emsg)
if len(stru) != p_natoms:
emsg = "expected %d atoms, read %d" % (p_natoms, len(stru))
raise StructureFormatError(emsg)
except (ValueError, IndexError):
emsg = "%d: file is not in XCFG format" % p_nl
exc_type, exc_value, exc_traceback = sys.exc_info()
raise StructureFormatError, emsg, exc_traceback
return stru
def setUp(self):
self.stru = Structure()
self.format = "pdb"
self.places = 3
def setUp(self):
self.stru = Structure()
self.format = 'xyz'
import tempfile
handle, self.tmpname = tempfile.mkstemp()
os.close(handle)
def setUp(self):
self.stru = Structure()
self.format = "xcfg"
self.places = 6