class random_crystal: """ Class for storing and generating atomic crystals based on symmetry constraints. Given a spacegroup, list of atomic symbols, the stoichiometry, and a volume factor, generates a random crystal consistent with the spacegroup's symmetry. Args: group: the spacegroup number (1-230), or a `pyxtal.symmetry.Group <pyxtal.symmetry.Group.html>`_ object species: a list of atomic symbols for each ion type, e.g., `["Ti", "O"]` numIons: a list of the number of each type of atom within the primitive cell (NOT the conventional cell), e.g., `[4, 2]` factor (optional): volume factor used to generate the crystal sites (optional): pre-assigned wyckoff sites (e.g., `[["4a"], ["2b"]]`) lattice (optional): `pyxtal.lattice.Lattice <pyxtal.lattice.Lattice.html>`_ object to define the unit cell tm (optional): `pyxtal.tolerance.Tol_matrix <pyxtal.tolerance.Tol_matrix.html>`_ object to define the distances """ def __init__( self, group=None, species=None, numIons=None, factor=1.1, lattice=None, sites=None, conventional=True, tm=Tol_matrix(prototype="atomic"), ): self.dim = 3 #periodic dimensions of the crystal self.PBC = [1, 1, 1] #The periodic boundary axes of the crystal self.lattice_attempts = 0 self.coord_attempts = 0 if type(group) != Group: group = Group(group, self.dim) self.init_common(species, numIons, factor, group, lattice, sites, conventional, tm) def __str__(self): if self.valid: s = "------Crystal from {:s}------".format(self.source) s += "\nComposition: {}".format(self.formula) s += "\nDimension: {}".format(self.dim) s += "\nGroup: {} ({})".format(self.group.symbol, self.group.number) s += "\n{}".format(self.lattice) s += "\nWyckoff sites:" for wyc in self.atom_sites: s += "\n\t{}".format(wyc) else: s = "\nStructure not available." return s def __repr__(self): return str(self) def init_common(self, species, numIons, factor, group, lattice, sites, conventional, tm): """ Common init functionality for 0D-3D cases of random_crystal. """ self.source = 'Random' self.valid = False # Check that numIons are integers greater than 0 for num in numIons: if int(num) != num or num < 1: printx("Error: composition must be positive integers.", priority=1) return False if type(group) == Group: self.group = group else: self.group = Group(group, dim=self.dim) self.number = self.group.number """ The international group number of the crystal: 1-230 for 3D space groups 1-80 for 2D layer groups 1-75 for 1D Rod groups 1-32 for crystallographic point groups None otherwise """ # The number of attempts to generate the crystal # number of atoms # volume factor for the unit cell. # The number of atom in the PRIMITIVE cell # The number of each type of atom in the CONVENTIONAL cell. # A list of atomic symbols for the types of atoms # A list of warning messages self.numattempts = 0 numIons = np.array(numIons) self.factor = factor if not conventional: mul = cellsize(self.group) else: mul = 1 self.numIons = numIons * mul formula = "" for i, s in zip(self.numIons, species): formula += "{:s}{:d}".format(s, int(i)) self.formula = formula self.species = species # Use the provided lattice if lattice is not None: self.lattice = lattice self.volume = lattice.volume # Make sure the custom lattice PBC axes are correct. if lattice.PBC != self.PBC: self.lattice.PBC = self.PBC printx("\n Warning: converting custom lattice PBC to " + str(self.PBC)) # Generate a Lattice instance based on a given volume estimation elif lattice is None: # Determine the unique axis if self.dim == 2: if self.number in range(3, 8): unique_axis = "c" else: unique_axis = "a" elif self.dim == 1: if self.number in range(3, 8): unique_axis = "a" else: unique_axis = "c" else: unique_axis = "c" self.volume = self.estimate_volume() if self.dim == 3 or self.dim == 0: self.lattice = Lattice( self.group.lattice_type, self.volume, PBC=self.PBC, unique_axis=unique_axis, ) elif self.dim == 2: self.lattice = Lattice( self.group.lattice_type, self.volume, PBC=self.PBC, unique_axis=unique_axis, # NOTE self.thickness is part of 2D class thickness=self.thickness, ) elif self.dim == 1: self.lattice = Lattice( self.group.lattice_type, self.volume, PBC=self.PBC, unique_axis=unique_axis, # NOTE self.area is part of 1D class area=self.area, ) # Set the tolerance matrix for checking inter-atomic distances if type(tm) == Tol_matrix: self.tol_matrix = tm else: try: self.tol_matrix = Tol_matrix(prototype=tm) # TODO Remove bare except except: printx( ("Error: tm must either be a Tol_matrix object or " "a prototype string for initializing one."), priority=1, ) self.valid = False return self.sites = {} for i, specie in enumerate(self.species): if sites is not None and sites[i] is not None: self.check_consistency(sites[i], self.numIons[i]) self.sites[specie] = sites[i] else: self.sites[specie] = None # QZ: needs to check if it is compatible self.generate_crystal() def check_compatible(self, group, numIons): """ Checks if the number of atoms is compatible with the Wyckoff positions. Considers the number of degrees of freedom for each Wyckoff position, and makes sure at least one valid combination of WP's exists. NOTE Comprhys: Is degrees of freedom used symnomously with multiplicity? perhaps standardising to multiplicity would be clearer? """ # Store whether or not at least one degree of freedom exists has_freedom = False # Store the wp's already used that don't have any freedom used_indices = [] # Loop over species for numIon in numIons: # Get lists of multiplicity, maxn and freedom l_mult0 = [] l_maxn0 = [] l_free0 = [] indices0 = [] for i_wp, wp in enumerate(group): indices0.append(i_wp) l_mult0.append(len(wp)) l_maxn0.append(numIon // len(wp)) if np.allclose(wp[0].rotation_matrix, np.zeros([3, 3])): l_free0.append(False) else: l_free0.append(True) # Remove redundant multiplicities: l_mult = [] l_maxn = [] l_free = [] indices = [] for mult, maxn, free, i_wp in zip(l_mult0, l_maxn0, l_free0, indices0): if free is True: if mult not in l_mult: l_mult.append(mult) l_maxn.append(maxn) l_free.append(True) indices.append(i_wp) elif free is False and i_wp not in used_indices: l_mult.append(mult) indices.append(i_wp) if mult <= numIon: l_maxn.append(1) elif mult > numIon: l_maxn.append(0) l_free.append(False) # Loop over possible combinations p = 0 # Create pointer variable to move through lists # Store the number of each WP, used across possible WP combinations n0 = [0] * len(l_mult) n = deepcopy(n0) for i, mult in enumerate(l_mult): if l_maxn[i] != 0: p = i n[i] = l_maxn[i] break p2 = p if n == n0: return False while True: num = np.dot(n, l_mult) dobackwards = False # The combination works: move to next species if num == numIon: # Check if at least one degree of freedom exists for val, free, i_wp in zip(n, l_free, indices): if val > 0: if free is True: has_freedom = True elif free is False: used_indices.append(i_wp) break # All combinations failed: return False if n == n0 and p >= len(l_mult) - 1: return False # Too few atoms if num < numIon: # Forwards routine # Move p to the right and max out if p < len(l_mult) - 1: p += 1 n[p] = min((numIon - num) // l_mult[p], l_maxn[p]) elif p == len(l_mult) - 1: # p is already at last position: trigger backwards routine dobackwards = True # Too many atoms if num > numIon or dobackwards is True: # Backwards routine # Set n[p] to 0, move p backwards to non-zero, and decrease by 1 n[p] = 0 while p > 0 and p > p2: p -= 1 if n[p] != 0: n[p] -= 1 if n[p] == 0 and p == p2: p2 = p + 1 break if has_freedom: # All species passed: return True return True else: # All species passed, but no degrees of freedom: return 0 return 0 def check_consistency(self, site, numIon): num = 0 for s in site: num += int(s[:-1]) if numIon == num: return True else: msg = "\nThe requested number of atoms is inconsistent: " + str( site) msg += "\nfrom numIons: {:d}".format(numIon) msg += "\nfrom Wyckoff list: {:d}".format(num) raise ValueError(msg) def estimate_volume(self): """ Estimates the volume of a unit cell based on the number and types of ions. Assumes each atom takes up a sphere with radius equal to its covalent bond radius. Returns: a float value for the estimated volume """ volume = 0 for numIon, specie in zip(self.numIons, self.species): r = random.uniform( Element(specie).covalent_radius, Element(specie).vdw_radius) volume += numIon * 4 / 3 * np.pi * r**3 return self.factor * volume def generate_crystal(self): """ The main code to generate a random atomic crystal. If successful, stores a pymatgen.core.structure object in self.struct and sets self.valid to True. If unsuccessful, sets self.valid to False and outputs an error message. """ # Check the minimum number of degrees of freedom within the Wyckoff positions self.numattempts = 1 degrees = self.check_compatible(self.group, self.numIons) if degrees is False: msg = "Warning: the stoichiometry is incompatible with wyckoff choice" printx(msg, priority=1) self.valid = False return if degrees == 0: printx("Wyckoff positions have no degrees of freedom.", priority=2) # NOTE why do these need to be changed from defaults? self.lattice_attempts = 5 self.coord_attempts = 5 #self.wyckoff_attempts = 5 else: self.lattice_attempts = 40 self.coord_attempts = 10 #self.wyckoff_attempts=10 # Calculate a minimum vector length for generating a lattice # NOTE Comprhys: minvector never used? # minvector = max(self.tol_matrix.get_tol(s, s) for s in self.species) for cycle1 in range(self.lattice_attempts): self.cycle1 = cycle1 # 1, Generate a lattice if self.lattice.allow_volume_reset: self.volume = self.estimate_volume() self.lattice.volume = self.volume self.lattice.reset_matrix() try: cell_matrix = self.lattice.get_matrix() if cell_matrix is None: continue # TODO remove bare except except: continue # Check that the correct volume was generated if self.lattice.random: if self.dim != 0 and abs(self.volume - self.lattice.volume) > 1.0: printx( ("Error, volume is not equal to the estimated value: " "{} -> {} cell_para: {}").format( self.volume, self.lattice.volume, self.lattice.get_para), priority=0, ) self.valid = False return # to try to generate atomic coordinates for cycle2 in range(self.coord_attempts): self.cycle2 = cycle2 output = self._generate_coords(cell_matrix) if output: self.atom_sites = output break if self.valid: return return def _generate_coords(self, cell_matrix): """ generate coordinates for random crystal """ wyckoff_sites_list = [] # generate coordinates for each ion type in turn for numIon, specie in zip(self.numIons, self.species): output = self._generate_ion_wyckoffs(numIon, specie, cell_matrix, wyckoff_sites_list) if output is not None: wyckoff_sites_list.extend(output) else: # correct multiplicity not achieved exit and start over return None # If numIon_added correct for all specie return structure self.valid = True return wyckoff_sites_list def _generate_ion_wyckoffs(self, numIon, specie, cell_matrix, wyks): """ generates a set of wyckoff positions to accomodate a given number of ions Args: numIon: Number of ions to accomodate specie: Type of species being placed on wyckoff site cell_matrix: Matrix of lattice vectors wyks: current wyckoff sites Returns: Sucess: wyckoff_sites_tmp: list of wyckoff sites for valid sites Failue: None """ numIon_added = 0 tol = self.tol_matrix.get_tol(specie, specie) tol_matrix = self.tol_matrix wyckoff_sites_tmp = [] # Now we start to add the specie to the wyckoff position sites_list = deepcopy(self.sites[specie]) # the list of Wyckoff site if sites_list is not None: wyckoff_attempts = max(len(sites_list) * 2, 10) else: # the minimum numattempts is to put all atoms to the general WPs min_wyckoffs = int(numIon / len(self.group.wyckoffs_organized[0][0])) wyckoff_attempts = max(2 * min_wyckoffs, 10) cycle = 0 while cycle < wyckoff_attempts: # Choose a random WP for given multiplicity: 2a, 2b if sites_list is not None: site = sites_list[0] else: # Selecting the merging site = None wp = choose_wyckoff(self.group, numIon - numIon_added, site, self.dim) if wp is not False: # Generate a list of coords from ops mult = wp.multiplicity # remember the original multiplicity pt = self.lattice.generate_point() # Merge coordinates if the atoms are close pt, wp, _ = WP_merge(pt, cell_matrix, wp, tol) # For pure planar structure if self.dim == 2 and self.thickness is not None and self.thickness < 0.1: pt[-1] = 0.5 # If site the pre-assigned, do not accept merge if wp is not False: if site is not None and mult != wp.multiplicity: cycle += 1 continue # Use a Wyckoff_site object for the current site new_site = atom_site(wp, pt, specie) # Check current WP against existing WP's passed_wp_check = True for ws in wyckoff_sites_tmp + wyks: if not new_site.check_with_ws2(ws, cell_matrix, tol_matrix): passed_wp_check = False if passed_wp_check: if sites_list is not None: sites_list.pop(0) wyckoff_sites_tmp.append(new_site) numIon_added += new_site.multiplicity # Check if enough atoms have been added if numIon_added == numIon: return wyckoff_sites_tmp cycle += 1 self.numattempts += 1 return None
class molecular_crystal: """ Class for storing and generating molecular crystals based on symmetry constraints. Based on the crystal.random_crystal class for atomic crystals. Given a spacegroup, list of molecule objects, molecular stoichiometry, and a volume factor, generates a molecular crystal consistent with the given constraints. Args: group: the spacegroup number (1-230), or a `pyxtal.symmetry.Group <pyxtal.symmetry.Group.html>`_ object molecules: a list of pymatgen.core.structure.Molecule objects for each type of molecule. Alternatively, you may supply a file path, or the name of molecules from the built_in `database <pyxtal.database.collection.html>`_ numMols: A list of the number of each type of molecule within the primitive cell (NOT the conventioal cell) volume_factor: A volume factor used to generate a larger or smaller unit cell. Increasing this gives extra space between molecules allow_inversion: Whether or not to allow chiral molecules to be inverted. If True, the final crystal may contain mirror images of the original molecule. Unless the chemical properties of the mirror image are known, it is highly recommended to keep this value False orientations: Once a crystal with the same spacegroup and molecular stoichiometry has been generated, you may pass its valid_orientations attribute here to avoid repeating the calculation, but this is not required lattice (optional): the `pyxtal.lattice.Lattice <pyxtal.lattice.Lattice.html>`_ object to define the unit cell tm (optional): the `pyxtal.tolerance.Tol_matrix <pyxtal.tolerance.tolerance.html>`_ object to define the distances sites (optional): pre-assigned wyckoff sites (e.g., `[["4a"], ["2b"]]`) seed (optional): the cif file from user diag (optional): if use the nonstandart setting (P21/n, Pn, C2/n)? """ def __init__( self, group, molecules, numMols, volume_factor=1.1, select_high=True, allow_inversion=True, orientations=None, lattice=None, tm=Tol_matrix(prototype="molecular"), sites=None, seed=None, diag=False, relax_h=False, ): self.dim = 3 # The number of periodic dimensions (1,2,3) self.PBC = [1, 1, 1] self.diag = diag if type(group) != Group: group = Group(group, self.dim) self.sg = group.number self.selec_high = select_high self.seed = seed self.relax_h = relax_h self.init_common( molecules, numMols, volume_factor, select_high, allow_inversion, orientations, group, lattice, tm, sites, ) def init_common( self, molecules, numMols, volume_factor, select_high, allow_inversion, orientations, group, lattice, tm, sites, ): # init functionality which is shared by 3D, 2D, and 1D crystals self.valid = False self.numattempts = 0 # number of attempts to generate the crystal. if type(group) == Group: self.group = group """A pyxtal.symmetry.Group object storing information about the space/layer /Rod/point group, and its Wyckoff positions.""" else: self.group = Group(group, dim=self.dim) self.number = self.group.number """ The international group number of the crystal: 1-230 for 3D space groups 1-80 for 2D layer groups 1-75 for 1D Rod groups 1-32 for crystallographic point groups None otherwise """ self.Msgs() self.factor = volume_factor # volume factor for the unit cell. numMols = np.array(numMols) # must convert it to np.array self.numMols0 = numMols # in the PRIMITIVE cell self.numMols = self.numMols0 * cellsize( self.group) # in the CONVENTIONAL cell # boolean numbers self.allow_inversion = allow_inversion self.select_high = select_high # Set the tolerance matrix # The Tol_matrix object for checking inter-atomic distances within the structure. if type(tm) == Tol_matrix: self.tol_matrix = tm else: try: self.tol_matrix = Tol_matrix(prototype=tm) # TODO remove bare except except: msg = "Error: tm must either be a Tol_matrix object +\n" msg += "or a prototype string for initializing one." printx(msg, priority=1) return self.molecules = [] # A pyxtal_molecule objects, for mol in molecules: self.molecules.append(pyxtal_molecule(mol, self.tol_matrix)) self.sites = {} for i, mol in enumerate(self.molecules): if sites is not None and sites[i] is not None: self.check_consistency(sites[i], self.numMols[i]) self.sites[i] = sites[i] else: self.sites[i] = None # if seeds, directly parse the structure from cif # At the moment, we only support one specie if self.seed is not None: seed = structure_from_ext(self.seed, self.molecules[0].mol, relax_h=self.relax_h) if seed.match(): self.mol_sites = [seed.make_mol_site()] self.group = Group(seed.wyc.number) self.lattice = seed.lattice self.molecules = [pyxtal_molecule(seed.molecule)] self.diag = seed.diag self.valid = True # Need to add a check function else: raise ValueError("Cannot extract the structure from cif") # The valid orientations for each molecule and Wyckoff position. # May be copied when generating a new molecular_crystal to save a # small amount of time if orientations is None: self.get_orientations() else: self.valid_orientations = orientations if self.seed is None: if lattice is not None: # Use the provided lattice self.lattice = lattice self.volume = lattice.volume # Make sure the custom lattice PBC axes are correct. if lattice.PBC != self.PBC: self.lattice.PBC = self.PBC printx("\n Warning: converting custom lattice PBC to " + str(self.PBC)) else: # Determine the unique axis if self.dim == 2: if self.number in range(3, 8): unique_axis = "c" else: unique_axis = "a" elif self.dim == 1: if self.number in range(3, 8): unique_axis = "a" else: unique_axis = "c" else: unique_axis = "c" # Generate a Lattice instance self.volume = self.estimate_volume() # The Lattice object used to generate lattice matrices if self.dim == 3 or self.dim == 0: self.lattice = Lattice( self.group.lattice_type, self.volume, PBC=self.PBC, unique_axis=unique_axis, ) elif self.dim == 2: self.lattice = Lattice( self.group.lattice_type, self.volume, PBC=self.PBC, unique_axis=unique_axis, thickness=self.thickness, ) elif self.dim == 1: self.lattice = Lattice( self.group.lattice_type, self.volume, PBC=self.PBC, unique_axis=unique_axis, area=self.area, ) self.generate_crystal() def check_consistency(self, site, numMol): num = 0 for s in site: num += int(s[:-1]) if numMol == num: return True else: msg = "\nThe requested number of molecules is inconsistent: " + str( site) msg += "\nfrom numMols: {:d}".format(numMol) msg += "\nfrom Wyckoff list: {:d}".format(num) raise ValueError(msg) def estimate_volume(self): """ Given the molecular stoichiometry, estimate the volume needed for a unit cell. Returns: the estimated volume (in cubic Angstroms) needed for the unit cell """ volume = 0 for numMol, mol in zip(self.numMols, self.molecules): volume += numMol * mol.volume return abs(self.factor * volume) def check_short_distances(self, r=1.0, exclude_H=True): """ A function to check short distance pairs Mainly used for debug, powered by pymatgen Args: r: the given cutoff distances exclude_H: whether or not ignore the H atoms Returns: a list of pairs within the cutoff """ pairs = [] pmg_struc = self.to_pymatgen() if exclude_H: pmg_struc.remove_species('H') res = pmg_struc.get_all_neighbors(r) for i, neighs in enumerate(res): for n in neighs: pairs.append( [pmg_struc.sites[i].specie, n.specie, n.nn_distance]) return pairs def Msgs(self): self.Msg1 = ( "Error: the stoichiometry is incompatible with the wyckoff sites choice" ) self.Msg2 = "Error: failed in the cycle of generating structures" self.Msg3 = "Warning: failed in the cycle of adding species" self.Msg4 = "Warning: failed in the cycle of choosing wyckoff sites" self.Msg5 = "Finishing: added the specie" self.Msg6 = "Finishing: added the whole structure" self.Msg7 = "Error: invalid paramaters for initialization" def get_orientations(self): """ Calculates the valid orientations for each Molecule and Wyckoff position. Returns a list with 4 indices: - index 1: the molecular prototype's index within self.molecules - index 2: the Wyckoff position's 1st index (based on multiplicity) - index 3: the WP's 2nd index (within the group of equal multiplicity) - index 4: the index of the valid orientation for the molecule/WP pair For example, self.valid_orientations[i][j][k] would be a list of valid orientations for self.molecules[i], in the Wyckoff position self.group.wyckoffs_organized[j][k] """ self.valid_orientations = [] for pyxtal_mol in self.molecules: self.valid_orientations.append([]) wp_index = -1 for i, x in enumerate(self.group.wyckoffs_organized): self.valid_orientations[-1].append([]) for j, wp in enumerate(x): wp_index += 1 allowed = orientation_in_wyckoff_position( pyxtal_mol.mol, wp, already_oriented=True, allow_inversion=self.allow_inversion, ) if allowed is not False: self.valid_orientations[-1][-1].append(allowed) else: self.valid_orientations[-1][-1].append([]) def check_compatible(self, group, numMols, valid_orientations): """ Checks if the number of molecules is compatible with the Wyckoff positions. Considers the number of degrees of freedom for each Wyckoff position, and makes sure at least one valid combination of WP's exists. """ # Store whether or not at least one degree of freedom exists has_freedom = False # Store the wp's already used that don't have any freedom used_indices = [] # Loop over species for i_mol, numIon in enumerate(numMols): # Get lists of multiplicity, maxn and freedom l_mult0 = [] l_maxn0 = [] l_free0 = [] indices0 = [] for i_wp, wp in enumerate(group): # Check that at least one valid orientation exists j, k = jk_from_i(i_wp, group.wyckoffs_organized) if len(valid_orientations[i_mol][j][k]) > 0: indices0.append(i_wp) l_mult0.append(len(wp)) l_maxn0.append(numIon // len(wp)) if np.allclose(wp[0].rotation_matrix, np.zeros([3, 3])): l_free0.append(False) else: l_free0.append(True) # Remove redundant multiplicities: l_mult = [] l_maxn = [] l_free = [] indices = [] for mult, maxn, free, i_wp in zip(l_mult0, l_maxn0, l_free0, indices0): if free is True: if mult not in l_mult: l_mult.append(mult) l_maxn.append(maxn) l_free.append(True) indices.append(i_wp) elif free is False and i_wp not in used_indices: l_mult.append(mult) l_maxn.append(1) l_free.append(False) indices.append(i_wp) # Loop over possible combinations # Create pointer variable to move through lists p = 0 # Store the number of each WP, used across possible WP combinations n0 = [0] * len(l_mult) n = deepcopy(n0) for i, mult in enumerate(l_mult): if l_maxn[i] != 0: p = i n[i] = l_maxn[i] break p2 = p if n == n0: print("n == n0", n, n0) return False while True: num = np.dot(n, l_mult) dobackwards = False # The combination works: move to next species if num == numIon: # Check if at least one degree of freedom exists for val, free, i_wp in zip(n, l_free, indices): if val > 0: if free is True: has_freedom = True elif free is False: indices.append(i_wp) break # All combinations failed: return False if n == n0 and p >= len(l_mult) - 1: #print("All combinations failed: return False") return False # Too few atoms if num < numIon: # Forwards routine # Move p to the right and max out if p < len(l_mult) - 1: p += 1 n[p] = min((numIon - num) // l_mult[p], l_maxn[p]) else: # p is already at last position: trigger backwards routine dobackwards = True # Too many atoms if num > numIon or dobackwards is True: # Backwards routine # Set n[p] to 0, move p backwards to non-zero, and decrease by 1 n[p] = 0 while p > 0 and p > p2: p -= 1 if n[p] != 0: n[p] -= 1 if n[p] == 0 and p == p2: p2 = p + 1 break # All species passed: return True if has_freedom is True: return True # All species passed, but no degrees of freedom: return 0 elif has_freedom is False: return 0 def to_file(self, filename=None, fmt="cif", permission='w', **kwargs): """ Creates a file with the given filename and file type to store the structure. By default, creates cif files for crystals and xyz files for clusters. By default, the filename is based on the stoichiometry. Args: filename: the file path fmt: the file type (`cif`, `xyz`, etc.) permission: `w` or `a+` sym_num: `w` or `a+` Returns: Nothing. Creates a file at the specified path """ if self.valid: if fmt == "cif": if self.dim == 3: return write_cif(self, filename, "from_pyxtal", permission, **kwargs) else: pmg_struc = self.to_pymatgen() pmg_struc.sort() return pmg_struc.to(fmt=fmt, filename=filename) else: pmg_struc = self.to_pymatgen() pmg_struc.sort() return pmg_struc.to(fmt=fmt, filename=filename) else: printx("Cannot create file: structure did not generate.", priority=1) def copy(self): """ simply copy the structure """ return deepcopy(self) def optimize_lattice(self): """ optimize the lattice if the cell has a bad inclination angles """ for i in range(5): lattice, trans, opt = self.lattice.optimize() if opt: for site in self.mol_sites: pos_absolute = np.dot(site.position, self.lattice.matrix) pos_frac = pos_absolute.dot(lattice.inv_matrix) site.position = pos_frac - np.floor(pos_frac) site.lattice = lattice # for P21/c, Pc, C2/c, check if opt the inclination angle if self.group.number in [7, 14, 15]: for j, op in enumerate(site.wp.ops): vec = op.translation_vector.dot(trans) vec -= np.floor(vec) op1 = op.from_rotation_and_translation( op.rotation_matrix, vec) site.wp.ops[j] = op1 #to do needs to update diag if necessary _, perm = Wyckoff_position.from_symops(site.wp.ops, self.group.number) if not isinstance(perm, list): self.diag = True else: self.diag = False self.lattice = lattice else: break def _get_coords_and_species(self, absolute=False, unitcell=True): """ extract the coordinates and species information Args: abosulte: if True, return the cartesian coords otherwise fractional Returns: total_coords: N*3 numpy array species: N-length list, e.g. ["C", "C", ...] """ species = [] total_coords = None for site in self.mol_sites: coords, site_species = site.get_coords_and_species( absolute, unitcell=unitcell) species.extend(site_species) if total_coords is None: total_coords = coords else: total_coords = np.append(total_coords, coords, axis=0) return total_coords, species def to_ase(self, resort=True): """ export to ase Atoms object """ from ase import Atoms if self.valid: lattice = self.lattice.copy() coords, species = self._get_coords_and_species(True) latt, coords = lattice.add_vacuum(coords, frac=False, PBC=self.PBC) atoms = Atoms(species, positions=coords, cell=latt, pbc=self.PBC) if resort: permutation = np.argsort(atoms.numbers) atoms = atoms[permutation] return atoms else: printx("No valid structure can be converted to ase.", priority=1) def to_pymatgen(self): """ export to Pymatgen structure object """ from pymatgen.core.structure import Structure if self.valid: lattice = self.lattice.copy() coords, species = self._get_coords_and_species() # Add space above and below a 2D or 1D crystals latt, coords = lattice.add_vacuum(coords, PBC=self.PBC) return Structure(latt, species, coords) else: printx("No valid structure can be converted to pymatgen.", priority=1) def __str__(self): s = "------Random Molecular Crystal------" s += "\nDimension: " + str(self.dim) if self.group.number in [7, 14, 15] and self.diag: symbol = self.group.alias else: symbol = self.group.symbol s += "\nGroup: " + symbol s += "\nVolume factor: " + str(self.factor) s += "\n" + str(self.lattice) if self.valid: s += "\nWyckoff sites:" for wyc in self.mol_sites: s += "\n\t{}".format(wyc) else: s += "\nStructure not generated." return s def __repr__(self): return str(self) def show(self, **kwargs): """ display the crystal structure """ from pyxtal.viz import display_molecular return display_molecular(self, **kwargs) def _check_lattice_vs_shape(self, factor=0.95): """ Make sure that the shape is compatible with the lattice vectors. Experimental---- """ #min_lat = min(self.lattice.get_para()[:3]) #for mol in self.molecules: # # if mol.has_stick_shape(): # if min_lat < factor*min([mol.box.width, mol.box.height, mol.box.length]): # msg = "Warning: lattice-shape mismatch: " # msg += "{:6.2f}".format(min_lat) # msg += " {:6.2f}".format(min([mol.box.width, mol.box.height, mol.box.length])) # print(msg) # return False return True def generate_crystal(self): """ The main code to generate a random molecular crystal. If successful, `self.valid` is True (False otherwise) """ # Check the minimum number of degrees of freedom within the Wyckoff positions degrees = self.check_compatible(self.group, self.numMols, self.valid_orientations) if degrees is False: self.valid = False msg = "the space group is incompatible with the number of molecules" #raise ValueError(msg) return else: if degrees == 0: self.lattice_attempts = 20 self.coord_attempts = 3 self.ori_attempts = 1 else: self.lattice_attempts = 40 self.coord_attempts = 30 self.ori_attempts = 5 if not self.lattice.allow_volume_reset: self.lattice_attempts = 1 for cycle1 in range(self.lattice_attempts): self.cycle1 = cycle1 # 1, Generate a lattice if self.lattice.allow_volume_reset: self.volume = self.estimate_volume() self.lattice.volume = self.volume self.lattice.reset_matrix() if self._check_lattice_vs_shape(): for cycle2 in range(self.coord_attempts): self.cycle2 = cycle2 output = self._generate_coords() if output: self.mol_sites = output break if self.valid: return printx("Couldn't generate crystal after max attempts.", priority=1) return def _generate_coords(self): """ generate coordinates for random crystal """ mol_sites_total = [] # Add molecules for i, numMol in enumerate(self.numMols): pyxtal_mol = self.molecules[i] valid_ori = self.valid_orientations[i] output = self._generate_mol_wyckoffs(i, numMol, pyxtal_mol, valid_ori, mol_sites_total) if output is not None: mol_sites_total.extend(output) else: # correct multiplicity not achieved exit and start over return None self.valid = True return mol_sites_total def _generate_mol_wyckoffs(self, id, numMol, pyxtal_mol, valid_ori, mol_wyks): """ generates a set of wyckoff positions to accomodate a given number of molecules Args: numMol: Number of ions to accomodate pyxtal_mol: Type of species being placed on wyckoff site mol_wyks: current wyckoff sites Returns: if sucess, wyckoff_sites_tmp: list of wyckoff sites for valid sites otherwise, None """ numMol_added = 0 mol_sites_tmp = [] # Now we start to add the specie to the wyckoff position sites_list = deepcopy(self.sites[id]) # the list of Wyckoff site if sites_list is not None: self.wyckoff_attempts = max(len(sites_list) * 2, 10) else: # the minimum numattempts is to put all atoms to the general WPs min_wyckoffs = int(numMol / len(self.group.wyckoffs_organized[0][0])) self.wyckoff_attempts = max(2 * min_wyckoffs, 10) for cycle in range(self.wyckoff_attempts): # Choose a random WP for given multiplicity: 2a, 2b, 2c if sites_list is not None: site = sites_list[0] else: # Selecting the merging site = None # NOTE: The molecular version return wyckoff indices, not ops diff = numMol - numMol_added wp = choose_wyckoff_molecular(self.group, diff, site, valid_ori, self.select_high, self.dim) if wp is not False: # Generate a list of coords from the wyckoff position mult = wp.multiplicity # remember the original multiplicity pt = self.lattice.generate_point() # merge coordinates if the atoms are close mtol = pyxtal_mol.radius * 0.5 pt, wp, oris = WP_merge(pt, self.lattice.matrix, wp, mtol, valid_ori) if wp is not False: if site is not None and mult != wp.multiplicity: continue if self.dim == 2 and self.thickness is not None and self.thickness < 0.1: pt[-1] = 0.5 ms0 = self._generate_orientation(pyxtal_mol, pt, oris, wp) if ms0 is not None: # Check current WP against existing WP's passed_wp_check = True for ms1 in mol_sites_tmp + mol_wyks: if not check_mol_sites( ms0, ms1, tm=self.tol_matrix): passed_wp_check = False if passed_wp_check: if sites_list is not None: sites_list.pop(0) mol_sites_tmp.append(ms0) numMol_added += len(ms0.wp) # We have enough molecules of the current type if numMol_added == numMol: return mol_sites_tmp return None def _check_ori_dist(self, ori): #mat, lengths = self.lattice.get_lengths() #for mol in self.molecules: # if mol.has_stick_shape(): # axis = mol.axes.T[0].dot(ori.r.as_matrix().T) #get coords # mol_length = max([mol.box.length, mol.box.width, mol.box.height]) # for vec, dist in zip(mat, lengths): # #print(vec, mol_length, dist, mol_length/dist, angle(axis, vec, False)) # if mol_length/dist < 1.6 and abs(angle(axis, vec, False)-90)>80: # #print("=============> bad ori", axis) # return True #return False return True def _generate_orientation(self, pyxtal_mol, pt, oris, wp): # Use a Wyckoff_site object for the current site self.numattempts += 1 #ensure that the orientation is good count = 0 while count < 100: ori = random.choice(oris).copy() ori.change_orientation(flip=True) if self._check_ori_dist(ori): #print("===good orientation", count, self._check_ori_dist(ori)) break count += 1 #print(count, self.molecules[0].axes.T[0].dot(ori.r.as_matrix().T)) #print(ori.r.as_matrix()) ms0 = mol_site(pyxtal_mol, pt, ori, wp, self.lattice, self.diag) # Check distances within the WP if ms0.check_distances(): return ms0 else: # Maximize the smallest distance for the general # positions if needed if len(pyxtal_mol.mol) > 1 and ori.degrees > 0: # bisection method def fun_dist(angle, ori, mo, pt): ori0 = ori.copy() ori.change_orientation(angle) ms0 = mol_site( mo, pt, ori, wp, self.lattice, self.diag, ) d = ms0.compute_distances() return d angle_lo = ori.angle angle_hi = angle_lo + np.pi fun_lo = fun_dist(angle_lo, ori, pyxtal_mol, pt) fun_hi = fun_dist(angle_hi, ori, pyxtal_mol, pt) fun = fun_hi for it in range(self.ori_attempts): self.numattempts += 1 if (fun > 0.8) & (ms0.check_distances()): return ms0 angle = (angle_lo + angle_hi) / 2 fun = fun_dist(angle, ori, pyxtal_mol, pt) #print('Bisection: ', it, fun) if fun_lo > fun_hi: angle_hi, fun_hi = angle, fun else: angle_lo, fun_lo = angle, fun return None
class random_crystal: """ Class for storing and generating atomic crystals based on symmetry constraints. Given a spacegroup, list of atomic symbols, the stoichiometry, and a volume factor, generates a random crystal consistent with the spacegroup's symmetry. Args: group: the spacegroup number (1-230), or a `pyxtal.symmetry.Group <pyxtal.symmetry.Group.html>`_ object species: a list of atomic symbols for each ion type, e.g., `["Ti", "O"]` numIons: a list of the number of each type of atom within the primitive cell (NOT the conventional cell), e.g., `[4, 2]` factor (optional): volume factor used to generate the crystal sites (optional): pre-assigned wyckoff sites (e.g., `[["4a"], ["2b"]]`) lattice (optional): the `pyxtal.lattice.Lattice <pyxtal.lattice.Lattice.html>`_ object to define the unit cell tm (optional): the `pyxtal.tolerance.Tol_matrix <pyxtal.tolerance.Tol_matrix.html>`_ object to define the distances seed (optional): the cif/POSCAR file from user """ def __init__( self, group=None, species=None, numIons=None, factor=1.1, lattice=None, sites=None, tm=Tol_matrix(prototype="atomic"), seed=None, ): self.dim = 3 #periodic dimensions of the crystal self.PBC = [1, 1, 1] #The periodic boundary axes of the crystal if seed is None: if type(group) != Group: group = Group(group, self.dim) self.sg = group.number #The international spacegroup number self.seed = None self.init_common(species, numIons, factor, group, lattice, sites, tm) else: self.seed = seed self.from_seed() def from_seed(self): """ Load the seed structure from Pymatgen/ASE/POSCAR/CIFs Internally they will be handled by Pymatgen """ self.valid = True from ase import Atoms from pymatgen import Structure if isinstance(self.seed, Atoms): #ASE atoms from pymatgen.io.ase import AseAtomsAdaptor pmg_struc = AseAtomsAdaptor.get_structure(self.seed) self.from_pymatgen(pmg_struc) elif isinstance(self.seed, Structure): #Pymatgen self.from_pymatgen(self.seed) elif isinstance(self.seed, str): pmg_struc = Structure.from_file(self.seed) self.from_pymatgen(pmg_struc) formula = "" for i, s in zip(self.numIons, self.species): formula += "{:s}{:d}".format(s, int(i)) self.formula = formula self.factor = 1.0 self.number = self.group.number self.source = 'Seed' def from_pymatgen(self, structure): """ Load the seed structure from Pymatgen/ASE/POSCAR/CIFs """ from pymatgen.symmetry.analyzer import SpacegroupAnalyzer as sga try: # needs to do it twice in order to get the conventional cell s = sga(structure) structure = s.get_refined_structure() s = sga(structure) sym_struc = s.get_symmetrized_structure() number = s.get_space_group_number() except: print("Failed to load the Pymatgen structure") self.valid = False if self.valid: d = sym_struc.composition.as_dict() species = [key for key in d.keys()] numIons = [] for ele in species: numIons.append(int(d[ele])) self.numIons = numIons self.species = species self.group = Group(number) atom_sites = [] for i, site in enumerate(sym_struc.equivalent_sites): pos = site[0].frac_coords wp = Wyckoff_position.from_group_and_index( number, sym_struc.wyckoff_symbols[i]) specie = site[0].specie.number atom_sites.append(atom_site(wp, pos, specie)) self.atom_sites = atom_sites self.lattice = Lattice.from_matrix(sym_struc.lattice.matrix, ltype=self.group.lattice_type) def init_common(self, species, numIons, factor, group, lattice, sites, tm): """ Common init functionality for 0D-3D cases of random_crystal. """ self.source = 'Random' self.valid = False # Check that numIons are integers greater than 0 for num in numIons: if int(num) != num or num < 1: printx("Error: composition must be positive integers.", priority=1) return False if type(group) == Group: self.group = group else: self.group = Group(group, dim=self.dim) self.number = self.group.number """ The international group number of the crystal: 1-230 for 3D space groups 1-80 for 2D layer groups 1-75 for 1D Rod groups 1-32 for crystallographic point groups None otherwise """ # The number of attempts to generate the crystal # number of atoms # volume factor for the unit cell. # The number of atom in the PRIMITIVE cell # The number of each type of atom in the CONVENTIONAL cell. # A list of atomic symbols for the types of atoms # A list of warning messages self.numattempts = 0 numIons = np.array(numIons) self.factor = factor self.numIons0 = numIons self.numIons = self.numIons0 * cellsize(self.group) formula = "" for i, s in zip(self.numIons, species): formula += "{:s}{:d}".format(s, int(i)) self.formula = formula self.species = species self.Msgs() # Use the provided lattice if lattice is not None: self.lattice = lattice self.volume = lattice.volume # Make sure the custom lattice PBC axes are correct. if lattice.PBC != self.PBC: self.lattice.PBC = self.PBC printx("\n Warning: converting custom lattice PBC to " + str(self.PBC)) # Generate a Lattice instance based on a given volume estimation elif lattice is None: # Determine the unique axis if self.dim == 2: if self.number in range(3, 8): unique_axis = "c" else: unique_axis = "a" elif self.dim == 1: if self.number in range(3, 8): unique_axis = "a" else: unique_axis = "c" else: unique_axis = "c" self.volume = self.estimate_volume() if self.dim == 3 or self.dim == 0: self.lattice = Lattice( self.group.lattice_type, self.volume, PBC=self.PBC, unique_axis=unique_axis, ) elif self.dim == 2: self.lattice = Lattice( self.group.lattice_type, self.volume, PBC=self.PBC, unique_axis=unique_axis, # NOTE self.thickness is part of 2D class thickness=self.thickness, ) elif self.dim == 1: self.lattice = Lattice( self.group.lattice_type, self.volume, PBC=self.PBC, unique_axis=unique_axis, # NOTE self.area is part of 1D class area=self.area, ) # Set the tolerance matrix for checking inter-atomic distances if type(tm) == Tol_matrix: self.tol_matrix = tm else: try: self.tol_matrix = Tol_matrix(prototype=tm) # TODO Remove bare except except: printx( ("Error: tm must either be a Tol_matrix object or " "a prototype string for initializing one."), priority=1, ) self.valid = False return self.sites = {} for i, specie in enumerate(self.species): if sites is not None and sites[i] is not None: self.check_consistency(sites[i], self.numIons[i]) self.sites[specie] = sites[i] else: self.sites[specie] = None # QZ: needs to check if it is compatible self.generate_crystal() def check_compatible(self, group, numIons): """ Checks if the number of atoms is compatible with the Wyckoff positions. Considers the number of degrees of freedom for each Wyckoff position, and makes sure at least one valid combination of WP's exists. NOTE Comprhys: Is degrees of freedom used symnomously with multiplicity? perhaps standardising to multiplicity would be clearer? """ # Store whether or not at least one degree of freedom exists has_freedom = False # Store the wp's already used that don't have any freedom used_indices = [] # Loop over species for numIon in numIons: # Get lists of multiplicity, maxn and freedom l_mult0 = [] l_maxn0 = [] l_free0 = [] indices0 = [] for i_wp, wp in enumerate(group): indices0.append(i_wp) l_mult0.append(len(wp)) l_maxn0.append(numIon // len(wp)) if np.allclose(wp[0].rotation_matrix, np.zeros([3, 3])): l_free0.append(False) else: l_free0.append(True) # Remove redundant multiplicities: l_mult = [] l_maxn = [] l_free = [] indices = [] for mult, maxn, free, i_wp in zip(l_mult0, l_maxn0, l_free0, indices0): if free is True: if mult not in l_mult: l_mult.append(mult) l_maxn.append(maxn) l_free.append(True) indices.append(i_wp) elif free is False and i_wp not in used_indices: l_mult.append(mult) indices.append(i_wp) if mult <= numIon: l_maxn.append(1) elif mult > numIon: l_maxn.append(0) l_free.append(False) # Loop over possible combinations p = 0 # Create pointer variable to move through lists # Store the number of each WP, used across possible WP combinations n0 = [0] * len(l_mult) n = deepcopy(n0) for i, mult in enumerate(l_mult): if l_maxn[i] != 0: p = i n[i] = l_maxn[i] break p2 = p if n == n0: return False while True: num = np.dot(n, l_mult) dobackwards = False # The combination works: move to next species if num == numIon: # Check if at least one degree of freedom exists for val, free, i_wp in zip(n, l_free, indices): if val > 0: if free is True: has_freedom = True elif free is False: used_indices.append(i_wp) break # All combinations failed: return False if n == n0 and p >= len(l_mult) - 1: return False # Too few atoms if num < numIon: # Forwards routine # Move p to the right and max out if p < len(l_mult) - 1: p += 1 n[p] = min((numIon - num) // l_mult[p], l_maxn[p]) elif p == len(l_mult) - 1: # p is already at last position: trigger backwards routine dobackwards = True # Too many atoms if num > numIon or dobackwards is True: # Backwards routine # Set n[p] to 0, move p backwards to non-zero, and decrease by 1 n[p] = 0 while p > 0 and p > p2: p -= 1 if n[p] != 0: n[p] -= 1 if n[p] == 0 and p == p2: p2 = p + 1 break # All species passed: return True if has_freedom is True: return True # All species passed, but no degrees of freedom: return 0 elif has_freedom is False: return 0 def check_consistency(self, site, numIon): num = 0 for s in site: num += int(s[:-1]) if numIon == num: return True else: msg = "\nThe requested number of atoms is inconsistent: " + str( site) msg += "\nfrom numIons: {:d}".format(numIon) msg += "\nfrom Wyckoff list: {:d}".format(num) raise ValueError(msg) def check_short_distances(self, r=0.7, exclude_H=True): """ A function to check short distance pairs Mainly used for debug, powered by pymatgen Args: r: the given cutoff distances exclude_H: whether or not exclude the H atoms Returns: list of pairs within the cutoff """ if dim > 0: pairs = [] pmg_struc = self.to_pymatgen() if exclude_H: pmg_struc.remove_species('H') res = pmg_struc.get_all_neighbors(r) for i, neighs in enumerate(res): for n in neighs: pairs.append( [pmg_struc.sites[i].specie, n.specie, n.nn_distance]) else: raise NotImplementedError("Does not support cluster for now") return pairs def Msgs(self): """ Define a set of error and warning message if generation fails. Returns: nothing """ self.Msg1 = ( "Error: the stoichiometry is incompatible with the wyckoff sites choice" ) self.Msg2 = "Error: failed in the cycle of generating structures" self.Msg3 = "Warning: failed in the cycle of adding species" self.Msg4 = "Warning: failed in the cycle of choosing wyckoff sites" self.Msg5 = "Finishing: added the specie" self.Msg6 = "Finishing: added the whole structure" self.Msg7 = "Error: invalid paramaters for initialization" def estimate_volume(self): """ Estimates the volume of a unit cell based on the number and types of ions. Assumes each atom takes up a sphere with radius equal to its covalent bond radius. Returns: a float value for the estimated volume """ volume = 0 for numIon, specie in zip(self.numIons, self.species): r = random.uniform( Element(specie).covalent_radius, Element(specie).vdw_radius) volume += numIon * 4 / 3 * np.pi * r**3 return self.factor * volume def to_file(self, filename=None, fmt=None, permission='w'): """ Creates a file with the given filename and file type to store the structure. By default, creates cif files for crystals and xyz files for clusters. For other formats, Pymatgen is used Args: filename: the file path fmt: the file type (`cif`, `xyz`, etc.) permission: `w` or `a+` Returns: Nothing. Creates a file at the specified path """ if self.valid: if fmt is None: if self.dim == 0: fmt = 'xyz' else: fmt = 'cif' if fmt == "cif": if self.dim == 3: from pyxtal.io import write_cif return write_cif(self, filename, "from_pyxtal", permission) else: pmg_struc = self.to_pymatgen() return pmg_struc.to(fmt=fmt, filename=filename) else: pmg_struc = self.to_pymatgen() return pmg_struc.to(fmt=fmt, filename=filename) else: printx("Cannot create file: structure did not generate.", priority=1) def __str__(self): s = "------Crystal from {:s}------".format(self.source) s += "\nComposition: {}".format(self.formula) s += "\nDimension: {}".format(self.dim) s += "\nGroup: {} ({})".format(self.group.symbol, self.group.number) s += "\nVolume factor: {}".format(self.factor) s += "\n{}".format(self.lattice) if self.valid: s += "\nWyckoff sites:" for wyc in self.atom_sites: s += "\n\t{}".format(wyc) else: s += "\nStructure not generated." return s def __repr__(self): return str(self) def show(self, **kwargs): """ display the crystal structure """ from pyxtal.viz import display_atomic return display_atomic(self, **kwargs) def subgroup(self, H=None, eps=0.05, idx=None, once=False): """ generate a structure with lower symmetry Args: H: space group number (int) eps: pertubation term (float) idx: list once: generate only one structure, otherwise output all Returns: a list of pyxtal structures with lower symmetries """ #randomly choose a subgroup from the available list Hs = self.group.get_max_t_subgroup()['subgroup'] if idx is None: idx = range(len(Hs)) else: for id in idx: if id >= len(Hs): raise ValueError( "The idx exceeds the number of possible splits") if H is not None: idx = [id for id in idx if Hs[idx] == H] if len(idx) == 0: raise ValueError("The space group H is incompatible with idx") sites = [ str(site.wp.multiplicity) + site.wp.letter for site in self.atom_sites ] valid_splitters = [] bad_splitters = [] for id in idx: splitter = wyckoff_split(G=self.group.number, wp1=sites, idx=id) if splitter.valid_split: valid_splitters.append(splitter) else: bad_splitters.append(splitter) if len(valid_splitters) == 0: # do one more step new_strucs = [] for splitter in bad_splitters: trail_struc = self.subgroup_by_splitter(splitter) new_strucs.append(trail_struc.subgroup(once=True)) return new_strucs else: if once: return self.subgroup_by_splitter(choice(valid_splitters), eps=eps) else: new_strucs = [] for splitter in valid_splitters: new_strucs.append( self.subgroup_by_splitter(splitter, eps=eps)) return new_strucs def subgroup_by_splitter(self, splitter, eps=0.05): lat1 = np.dot(splitter.R[:3, :3].T, self.lattice.matrix) multiples = np.linalg.det(splitter.R[:3, :3]) split_sites = [] for i, site in enumerate(self.atom_sites): pos = site.position for ops1, ops2 in zip(splitter.G2_orbits[i], splitter.H_orbits[i]): pos0 = apply_ops(pos, ops1)[0] pos0 -= np.floor(pos0) pos0 += eps * (np.random.sample(3) - 0.5) wp, _ = Wyckoff_position.from_symops(ops2, group=splitter.H.number, permutation=False) split_sites.append(atom_site(wp, pos0, site.specie)) new_struc = deepcopy(self) new_struc.group = splitter.H lattice = Lattice.from_matrix(lat1, ltype=new_struc.group.lattice_type) new_struc.lattice = lattice.mutate(degree=0.01, frozen=True) new_struc.atom_sites = split_sites new_struc.numIons = [ int(multiples * numIon) for numIon in self.numIons ] new_struc.source = 'Wyckoff Split' return new_struc def generate_crystal(self): """ The main code to generate a random atomic crystal. If successful, stores a pymatgen.core.structure object in self.struct and sets self.valid to True. If unsuccessful, sets self.valid to False and outputs an error message. """ # Check the minimum number of degrees of freedom within the Wyckoff positions self.numattempts = 1 degrees = self.check_compatible(self.group, self.numIons) if degrees is False: printx(self.Msg1, priority=1) self.valid = False return if degrees == 0: printx("Wyckoff positions have no degrees of freedom.", priority=2) # NOTE why do these need to be changed from defaults? self.lattice_attempts = 5 self.coord_attempts = 5 #self.wyckoff_attempts = 5 else: self.lattice_attempts = 40 self.coord_attempts = 10 #self.wyckoff_attempts=10 # Calculate a minimum vector length for generating a lattice # NOTE Comprhys: minvector never used? # minvector = max(self.tol_matrix.get_tol(s, s) for s in self.species) for cycle1 in range(self.lattice_attempts): self.cycle1 = cycle1 # 1, Generate a lattice if self.lattice.allow_volume_reset: self.volume = self.estimate_volume() self.lattice.volume = self.volume self.lattice.reset_matrix() try: cell_matrix = self.lattice.get_matrix() if cell_matrix is None: continue # TODO remove bare except except: continue # Check that the correct volume was generated if self.lattice.random: if self.dim != 0 and abs(self.volume - self.lattice.volume) > 1.0: printx( ("Error, volume is not equal to the estimated value: " "{} -> {} cell_para: {}").format( self.volume, self.lattice.volume, self.lattice.get_para), priority=0, ) self.valid = False return # to try to generate atomic coordinates for cycle2 in range(self.coord_attempts): self.cycle2 = cycle2 output = self._generate_coords(cell_matrix) if output: self.atom_sites = output break if self.valid: return return def copy(self): """ simply copy the structure """ return deepcopy(self) def _get_coords_and_species(self, absolute=False): """ extract the coordinates and species information Args: abosulte: if True, return the cartesian coords otherwise fractional Returns: total_coords (N*3 numpy array) and the list of species """ species = [] total_coords = None for site in self.atom_sites: species.extend([site.specie] * site.multiplicity) if total_coords is None: total_coords = site.coords else: total_coords = np.append(total_coords, site.coords, axis=0) if absolute: return total_coords.dot(self.lattice.matrix), species else: return total_coords, species def to_ase(self): """ export to ase Atoms object """ from ase import Atoms if self.valid: if self.dim > 0: lattice = self.lattice.copy() coords, species = self._get_coords_and_species() # Add space above and below a 2D or 1D crystals latt, coords = lattice.add_vacuum(coords, PBC=self.PBC) return Atoms(species, scaled_positions=coords, cell=latt, pbc=self.PBC) else: coords, species = self._get_coords_and_species(True) return Atoms(species, positions=coords) else: printx("No valid structure can be converted to ase.", priority=1) def to_pymatgen(self): """ export to Pymatgen structure object """ from pymatgen.core.structure import Structure, Molecule if self.valid: if self.dim > 0: lattice = self.lattice.copy() coords, species = self._get_coords_and_species() # Add space above and below a 2D or 1D crystals latt, coords = lattice.add_vacuum(coords, PBC=self.PBC) return Structure(latt, species, coords) else: # Clusters are handled as large molecules coords, species = self._get_coords_and_species(True) return Molecule(species, coords) else: printx("No valid structure can be converted to pymatgen.", priority=1) def _generate_coords(self, cell_matrix): """ generate coordinates for random crystal """ wyckoff_sites_list = [] # generate coordinates for each ion type in turn for numIon, specie in zip(self.numIons, self.species): output = self._generate_ion_wyckoffs(numIon, specie, cell_matrix, wyckoff_sites_list) if output is not None: wyckoff_sites_list.extend(output) else: # correct multiplicity not achieved exit and start over return None # If numIon_added correct for all specie return structure self.valid = True return wyckoff_sites_list def _generate_ion_wyckoffs(self, numIon, specie, cell_matrix, wyks): """ generates a set of wyckoff positions to accomodate a given number of ions Args: numIon: Number of ions to accomodate specie: Type of species being placed on wyckoff site cell_matrix: Matrix of lattice vectors wyks: current wyckoff sites Returns: Sucess: wyckoff_sites_tmp: list of wyckoff sites for valid sites Failue: None """ numIon_added = 0 tol = self.tol_matrix.get_tol(specie, specie) tol_matrix = self.tol_matrix wyckoff_sites_tmp = [] # Now we start to add the specie to the wyckoff position sites_list = deepcopy(self.sites[specie]) # the list of Wyckoff site if sites_list is not None: wyckoff_attempts = max(len(sites_list) * 2, 10) else: # the minimum numattempts is to put all atoms to the general WPs min_wyckoffs = int(numIon / len(self.group.wyckoffs_organized[0][0])) wyckoff_attempts = max(2 * min_wyckoffs, 10) cycle = 0 while cycle < wyckoff_attempts: # Choose a random WP for given multiplicity: 2a, 2b if sites_list is not None: site = sites_list[0] else: # Selecting the merging site = None wp = choose_wyckoff(self.group, numIon - numIon_added, site, self.dim) if wp is not False: # Generate a list of coords from ops mult = wp.multiplicity # remember the original multiplicity pt = self.lattice.generate_point() # Merge coordinates if the atoms are close pt, wp, _ = WP_merge(pt, cell_matrix, wp, tol) # For pure planar structure if self.dim == 2 and self.thickness is not None and self.thickness < 0.1: pt[-1] = 0.5 # If site the pre-assigned, do not accept merge if wp is not False: if site is not None and mult != wp.multiplicity: cycle += 1 continue # Use a Wyckoff_site object for the current site new_site = atom_site(wp, pt, specie) # Check current WP against existing WP's passed_wp_check = True for ws in wyckoff_sites_tmp + wyks: if not check_atom_sites(new_site, ws, cell_matrix, tol_matrix): passed_wp_check = False if passed_wp_check: if sites_list is not None: sites_list.pop(0) wyckoff_sites_tmp.append(new_site) numIon_added += new_site.multiplicity # Check if enough atoms have been added if numIon_added == numIon: return wyckoff_sites_tmp cycle += 1 self.numattempts += 1 return None