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 element = 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(element, 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 makeC60(): """Make the C60 molecule using diffpy.Structure.""" from diffpy.Structure import Structure stru = Structure() for line in c60xyz.splitlines(): if not line: continue xyz = map(float, line.split()) stru.addNewAtom("C", xyz) return stru
def test_bvrmsdiff(self): """check BVSCalculator.bvrmsdiff """ from math import sqrt self.assertEqual(0, self.bvc.bvrmsdiff) self.bvc(self.rutile) self.failUnless(self.bvc.bvrmsdiff > 0) self.assertAlmostEqual(sqrt(self.bvc.bvmsdiff), self.bvc.bvrmsdiff, 12) bvrmsd0 = self.bvc.bvrmsdiff # check mixed occupancy rutilemix = Structure(self.rutile) for a in self.rutile: rutilemix.addNewAtom(a) for a in rutilemix: a.occupancy = 0.5 self.bvc(rutilemix) self.assertEqual(12, len(self.bvc.value)) self.assertAlmostEqual(bvrmsd0, self.bvc.bvrmsdiff, 12) return
def test_bvrmsdiff(self): """check BVSCalculator.bvrmsdiff """ from math import sqrt self.assertEqual(0, self.bvc.bvrmsdiff) self.bvc(self.rutile) self.assertTrue(self.bvc.bvrmsdiff > 0) self.assertAlmostEqual(sqrt(self.bvc.bvmsdiff), self.bvc.bvrmsdiff, 12) bvrmsd0 = self.bvc.bvrmsdiff # check mixed occupancy rutilemix = Structure(self.rutile) for a in self.rutile: rutilemix.addNewAtom(a) for a in rutilemix: a.occupancy = 0.5 self.bvc(rutilemix) self.assertEqual(12, len(self.bvc.value)) self.assertAlmostEqual(bvrmsd0, self.bvc.bvrmsdiff, 12) return
def parseLines(self, lines): """Parse list of lines in PDB format. Return Structure instance or raise StructureFormatError. """ try: stru = Structure() scale = numpy.identity(3, dtype=float) scaleU = numpy.zeros(3, dtype=float) p_nl = 0 for line in lines: p_nl += 1 # skip blank lines if not line.strip(): continue # make sure line has 80 characters if len(line) < 80: line = "%-80s" % line words = line.split() record = words[0] if record == "TITLE": continuation = line[8:10] if continuation.strip(): stru.title += line[10:].rstrip() else: stru.title = line[10:].rstrip() elif record == "CRYST1": a = float(line[7:15]) b = float(line[15:24]) c = float(line[24:33]) alpha = float(line[33:40]) beta = float(line[40:47]) gamma = float(line[47:54]) stru.lattice.setLatPar(a, b, c, alpha, beta, gamma) scale = numpy.transpose(stru.lattice.recbase) elif record == "SCALE1": sc = numpy.zeros((3,3), dtype=float) sc[0,:] = [float(x) for x in line[10:40].split()] scaleU[0] = float(line[45:55]) elif record == "SCALE2": sc[1,:] = [float(x) for x in line[10:40].split()] scaleU[1] = float(line[45:55]) elif record == "SCALE3": sc[2,:] = [float(x) for x in line[10:40].split()] scaleU[2] = float(line[45:55]) base = numpy.transpose(numpy.linalg.inv(sc)) abcABGcryst = numpy.array(stru.lattice.abcABG()) stru.lattice.setLatBase(base) abcABGscale = numpy.array(stru.lattice.abcABG()) reldiff = numpy.fabs(1.0 - abcABGscale/abcABGcryst) if not numpy.all(reldiff < 1.0e-4): emsg = "%d: " % p_nl + \ "SCALE and CRYST1 are not consistent." raise StructureFormatError(emsg) if numpy.any(scaleU != 0.0): emsg = "Origin offset not yet implemented." raise NotImplementedError(emsg) elif record in ("ATOM", "HETATM"): name = line[12:16].strip() rc = [float(x) for x in line[30:54].split()] xyz = numpy.dot(scale, rc) + scaleU try: occupancy = float(line[54:60]) except ValueError: occupancy = 1.0 try: B = float(line[60:66]) U = numpy.identity(3)*B/(8*pi**2) except ValueError: U = numpy.zeros((3,3), dtype=float) element = line[76:78].strip() if element == "": # get element from the first 2 characters of name element = line[12:14].strip() element = element[0].upper() + element[1:].lower() stru.addNewAtom(element, occupancy=occupancy, label=name, U=U) last_atom = stru.getLastAtom() last_atom.xyz_cartn = rc elif record == "SIGATM": sigrc = [float(x) for x in line[30:54].split()] sigxyz = numpy.dot(scale, sigrc) try: sigo = float(line[54:60]) except ValueError: sigo = 0.0 try: sigB = float(line[60:66]) sigU = numpy.identity(3)*sigB/(8*pi**2) except ValueError: sigU = numpy.zeros((3,3), dtype=float) last_atom.sigxyz = sigxyz last_atom.sigo = sigo last_atom.sigU = sigU elif record == "ANISOU": Uij = [ float(x)*1.0e-4 for x in line[28:70].split() ] for i in range(3): last_atom.U[i,i] = Uij[i] last_atom.U[0,1] = last_atom.U[1,0] = Uij[3] last_atom.U[0,2] = last_atom.U[2,0] = Uij[4] last_atom.U[1,2] = last_atom.U[2,1] = Uij[5] elif record == "SIGUIJ": sigUij = [ float(x)*1.0e-4 for x in line[28:70].split() ] for i in range(3): last_atom.sigU[i,i] = sigUij[i] last_atom.sigU[0,1] = last_atom.sigU[1,0] = sigUij[3] last_atom.sigU[0,2] = last_atom.sigU[2,0] = sigUij[4] last_atom.sigU[1,2] = last_atom.sigU[2,1] = sigUij[5] elif record in P_pdb.validRecords: pass else: emsg = "%d: invalid record name '%r'" % (p_nl, record) raise StructureFormatError(emsg) except (ValueError, IndexError): emsg = "%d: invalid PDB record" % 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 p_nl = 0 p_auxiliary_re = re.compile(r"^auxiliary\[(\d+)\] =") p_auxiliary = {} stru = Structure() # ignore trailing blank lines stop = len(lines) for line in reversed(lines): if line.strip(): break stop -= 1 # iterator over the valid data lines ilines = iter(lines[:stop]) try: # 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 = sorted(p_auxiliary.keys()) if p_auxnum != 0: stru.xcfg = { 'auxiliaries': [p_auxiliary[k] for k in sorted_aux_keys] } ecnt = len(p_auxiliary) + (3 if xcfg_NO_VELOCITY else 6) if ecnt != xcfg_entry_count: emsg = ("%d: auxiliary fields are " "not consistent with entry_count") % p_nl raise StructureFormatError(emsg) # define proper lattice stru.lattice.setLatBase(xcfg_H0) # here we are inside the data block p_element = None for line in ilines: 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] xyz = [xcfg_A * xi for xi in fields[:3]] stru.addNewAtom(p_element, xyz=xyz) a = stru[-1] _assign_auxiliaries(a, fields, auxiliaries=p_auxiliary, no_velocity=xcfg_NO_VELOCITY) 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 XYZ 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 # first valid line gives number of atoms try: lfs = linefields[start] w1 = linefields[start][0] if len(lfs) == 1 and str(int(w1)) == w1: p_natoms = int(w1) #try to get lattice vectors from description line try: latticeVecs = list(map(float, linefields[start+1])) assert len(latticeVecs)==9, "Expect 9 numbers for the 3 basis vectors" reshaped = [latticeVecs[0:3], latticeVecs[3:6], latticeVecs[6:9]] stru.lattice = Lattice(base=reshaped) needsDescription = True except: import traceback as tb import warnings warnings.warn("Failed to parse lattice vectors: \n{}".format(tb.format_exc())) needsDescription = False stru.description = lines[start+1].strip() start += 2 else: emsg = ("%d: invalid XYZ format, missing number of atoms" % (start + 1)) raise StructureFormatError(emsg) except (IndexError, ValueError): exc_type, exc_value, exc_traceback = sys.exc_info() emsg = ("%d: invalid XYZ format, missing number of atoms" % (start + 1)) raise StructureFormatError(emsg).with_traceback(exc_traceback) # 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 p_natoms == 0 or start >= stop: return stru # here we have at least one valid record line nfields = len(linefields[start]) if nfields != 4 and nfields != 5: emsg = "%d: invalid XYZ format, expected 4 or 5 columns" % (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) != 4 and len(fields) !=5: emsg = ('%d: all lines must have ' + 'a symbol, position, and optionally charge') % p_nl raise StructureFormatError(emsg) symbol = fields[0] symbol = symbol[0].upper() + symbol[1:].lower() xyz = [ float(f) for f in fields[1:4] ] if len(fields)==5: charge = float(fields[4]) else: charge = 0.0 stru.addNewAtom(symbol, xyz=xyz) stru.getLastAtom().charge=charge except ValueError: exc_type, exc_value, exc_traceback = sys.exc_info() emsg = "%d: invalid number format" % p_nl raise StructureFormatError(emsg).with_traceback(exc_traceback) # finally check if all the atoms have been read if p_natoms is not None and len(stru) != p_natoms: emsg = "expected %d atoms, read %d" % (p_natoms, len(stru)) raise StructureFormatError(emsg) # if needsDescription: # stru.generateDescription() 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
# The placeInLattice method sets a new coordinate system while preserving # the same Cartesian positions of all atoms. stru2 = Structure(stru1) lattice2 = Lattice(5, 6, 7, 60, 70, 80) stru2.placeInLattice(lattice2) print "stru2 is a copy of stru1 placed in differenc lattice" print "stru2.lattice.abcABG()=" + str(stru2.lattice.abcABG()) listCoordinates(stru2) print # Finally to place atom at a given Cartesian position, one can # set its xyz_cartn attribute. lattice3 = Lattice(6, 8, 9, 90, 90, 90) stru3 = Structure(lattice=lattice3) # add 4 carbon atoms stru3.addNewAtom("C") stru3.getLastAtom().xyz_cartn = (0, 0, 0) stru3.addNewAtom("C") stru3[-1].xyz_cartn = (1, 1, 1) stru3.addNewAtom("C") stru3.getLastAtom().xyz_cartn = (1, 2, 3) stru3.addNewAtom("C") stru3.getLastAtom().xyz_cartn = (3, 2, 1) print "stru3 atom coordinates were defined using xyz_cartn" print "stru3.lattice.abcABG()=" + str(stru3.lattice.abcABG()) listCoordinates(stru3) print
def parseLines(self, lines): """Parse list of lines in XYZ 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 # first valid line gives number of atoms try: lfs = linefields[start] w1 = linefields[start][0] if len(lfs) == 1 and str(int(w1)) == w1: p_natoms = int(w1) stru.title = lines[start+1].strip() start += 2 else: emsg = ("%d: invalid XYZ format, missing number of atoms" % (start + 1)) raise StructureFormatError(emsg) except (IndexError, ValueError): exc_type, exc_value, exc_traceback = sys.exc_info() emsg = ("%d: invalid XYZ format, missing number of atoms" % (start + 1)) raise StructureFormatError, emsg, exc_traceback # 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 p_natoms == 0 or start >= stop: return stru # here we have at least one valid record line nfields = len(linefields[start]) if nfields != 4: emsg = "%d: invalid XYZ format, expected 4 columns" % (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) element = fields[0] element = element[0].upper() + element[1:].lower() xyz = [ float(f) for f in fields[1:4] ] stru.addNewAtom(element, xyz=xyz) except ValueError: exc_type, exc_value, exc_traceback = sys.exc_info() emsg = "%d: invalid number format" % p_nl raise StructureFormatError, emsg, exc_traceback # finally check if all the atoms have been read if p_natoms is not None and len(stru) != p_natoms: emsg = "expected %d atoms, read %d" % (p_natoms, len(stru)) raise StructureFormatError(emsg) return stru
def parseLines(self, lines): """Parse list of lines in XYZ 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 # first valid line gives number of atoms try: lfs = linefields[start] w1 = linefields[start][0] if len(lfs) == 1 and str(int(w1)) == w1: p_natoms = int(w1) #try to get lattice vectors from description line try: latticeVecs = map(float, linefields[start+1]) assert len(latticeVecs)==9 reshaped = [latticeVecs[0:3], latticeVecs[3:6], latticeVecs[6:9]] stru.lattice = Lattice(base=reshaped) needsDescription = True except: needsDescription = False stru.description = lines[start+1].strip() start += 2 else: emsg = ("%d: invalid XYZ format, missing number of atoms" % (start + 1)) raise StructureFormatError(emsg) except (IndexError, ValueError): exc_type, exc_value, exc_traceback = sys.exc_info() emsg = ("%d: invalid XYZ format, missing number of atoms" % (start + 1)) raise StructureFormatError, emsg, exc_traceback # 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 p_natoms == 0 or start >= stop: return stru # here we have at least one valid record line nfields = len(linefields[start]) if nfields != 4 and nfields != 5: emsg = "%d: invalid XYZ format, expected 4 or 5 columns" % (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) != 4 and len(fields) !=5: emsg = ('%d: all lines must have ' + 'a symbol, position, and optionally charge') % p_nl raise StructureFormatError(emsg) symbol = fields[0] symbol = symbol[0].upper() + symbol[1:].lower() xyz = [ float(f) for f in fields[1:4] ] if len(fields)==5: charge = float(fields[4]) else: charge = 0.0 stru.addNewAtom(symbol, xyz=xyz) stru.getLastAtom().charge=charge except ValueError: exc_type, exc_value, exc_traceback = sys.exc_info() emsg = "%d: invalid number format" % p_nl raise StructureFormatError, emsg, exc_traceback # finally check if all the atoms have been read if p_natoms is not None and len(stru) != p_natoms: emsg = "expected %d atoms, read %d" % (p_natoms, len(stru)) raise StructureFormatError(emsg) # if needsDescription: # stru.generateDescription() return stru
def parseLines(self, lines): """Parse list of lines in PDB format. Return Structure instance or raise StructureFormatError. """ try: stru = Structure() scale = numpy.identity(3, dtype=float) scaleU = numpy.zeros(3, dtype=float) p_nl = 0 for line in lines: p_nl += 1 # skip blank lines if not line.strip(): continue # make sure line has 80 characters if len(line) < 80: line = "%-80s" % line words = line.split() record = words[0] if record == "TITLE": continuation = line[8:10] if continuation.strip(): stru.title += line[10:].rstrip() else: stru.title = line[10:].rstrip() elif record == "CRYST1": a = float(line[7:15]) b = float(line[15:24]) c = float(line[24:33]) alpha = float(line[33:40]) beta = float(line[40:47]) gamma = float(line[47:54]) stru.lattice.setLatPar(a, b, c, alpha, beta, gamma) scale = numpy.transpose(stru.lattice.recbase) elif record == "SCALE1": sc = numpy.zeros((3, 3), dtype=float) sc[0, :] = [float(x) for x in line[10:40].split()] scaleU[0] = float(line[45:55]) elif record == "SCALE2": sc[1, :] = [float(x) for x in line[10:40].split()] scaleU[1] = float(line[45:55]) elif record == "SCALE3": sc[2, :] = [float(x) for x in line[10:40].split()] scaleU[2] = float(line[45:55]) base = numpy.transpose(numpy.linalg.inv(sc)) abcABGcryst = numpy.array(stru.lattice.abcABG()) stru.lattice.setLatBase(base) abcABGscale = numpy.array(stru.lattice.abcABG()) reldiff = numpy.fabs(1.0 - abcABGscale / abcABGcryst) if not numpy.all(reldiff < 1.0e-4): emsg = "%d: " % p_nl + \ "SCALE and CRYST1 are not consistent." raise StructureFormatError(emsg) if numpy.any(scaleU != 0.0): emsg = "Origin offset not yet implemented." raise NotImplementedError(emsg) elif record in ("ATOM", "HETATM"): name = line[12:16].strip() rc = [float(x) for x in line[30:54].split()] try: occupancy = float(line[54:60]) except ValueError: occupancy = 1.0 try: B = float(line[60:66]) uiso = B / (8 * pi**2) except ValueError: uiso = 0.0 element = line[76:78].strip() if element == "": # get element from the first 2 characters of name element = line[12:14].strip() element = element[0].upper() + element[1:].lower() stru.addNewAtom(element, occupancy=occupancy, label=name) last_atom = stru.getLastAtom() last_atom.xyz_cartn = rc last_atom.Uisoequiv = uiso elif record == "SIGATM": sigrc = [float(x) for x in line[30:54].split()] sigxyz = numpy.dot(scale, sigrc) try: sigo = float(line[54:60]) except ValueError: sigo = 0.0 try: sigB = float(line[60:66]) sigU = numpy.identity(3) * sigB / (8 * pi**2) except ValueError: sigU = numpy.zeros((3, 3), dtype=float) last_atom.sigxyz = sigxyz last_atom.sigo = sigo last_atom.sigU = sigU elif record == "ANISOU": last_atom.anisotropy = True Uij = [float(x) * 1.0e-4 for x in line[28:70].split()] Ua = last_atom.U for i in range(3): Ua[i, i] = Uij[i] Ua[0, 1] = Ua[1, 0] = Uij[3] Ua[0, 2] = Ua[2, 0] = Uij[4] Ua[1, 2] = Ua[2, 1] = Uij[5] elif record == "SIGUIJ": sigUij = [float(x) * 1.0e-4 for x in line[28:70].split()] for i in range(3): last_atom.sigU[i, i] = sigUij[i] last_atom.sigU[0, 1] = last_atom.sigU[1, 0] = sigUij[3] last_atom.sigU[0, 2] = last_atom.sigU[2, 0] = sigUij[4] last_atom.sigU[1, 2] = last_atom.sigU[2, 1] = sigUij[5] elif record in P_pdb.validRecords: pass else: emsg = "%d: invalid record name '%r'" % (p_nl, record) raise StructureFormatError(emsg) except (ValueError, IndexError): emsg = "%d: invalid PDB record" % p_nl exc_type, exc_value, exc_traceback = sys.exc_info() raise StructureFormatError, emsg, exc_traceback return stru