def _sanitize_input_structure(input_structure: Structure) -> Structure:
"""Sanitize our input structure by removing magnetic information
and making primitive.
Args:
input_structure: Structure
Returns: Structure
"""
input_structure = input_structure.copy()
# remove any annotated spin
input_structure.remove_spin()
# sanitize input structure: first make primitive ...
input_structure = input_structure.get_primitive_structure(
use_site_props=False)
# ... and strip out existing magmoms, which can cause conflicts
# with later transformations otherwise since sites would end up
# with both magmom site properties and Species spins defined
if "magmom" in input_structure.site_properties:
input_structure.remove_site_property("magmom")
return input_structure
def insert_atoms(structure: Structure,
inserted_atoms: List[dict]) -> Tuple[Structure, List[dict]]:
"""Return the structure with inserted atoms and its inserted atom indices
Args:
structure (Structure):
Input structure.
inserted_atoms (list):
List of dict with "element" and "coords" keys.
Not that "index" is absent here as it is not determined, yet.
Return:
(inserted Structure, list of dict of inserted atom info)
"""
inserted_structure = structure.copy()
inserted_atoms_with_indices = []
for atom in inserted_atoms:
index = first_appearing_index(inserted_structure, atom["element"])
inserted_structure.insert(index, atom["element"], atom["coords"])
# The atom indices locating after k need to be incremented.
for i in inserted_atoms_with_indices:
if i["index"] >= index:
i["index"] += 1
inserted_atoms_with_indices.append({
"element": atom["element"],
"index": index,
"coords": atom["coords"]
})
return inserted_structure, inserted_atoms_with_indices
class SlabTest(unittest.TestCase):
def setUp(self):
self.cu = Structure(Lattice.cubic(3), ["Cu", "Cu", "Cu", "Cu"],
[[0, 0, 0], [0.5, 0.5, 0], [0.5, 0, 0.5],
[0, 0.5, 0.5]])
def test_init(self):
for hkl in itertools.product(xrange(4), xrange(4), xrange(4)):
if any(hkl):
ssize = 6
vsize = 10
s = Slab(self.cu, hkl, ssize, vsize)
if hkl == [0, 1, 1]:
self.assertEqual(len(s), 13)
self.assertAlmostEqual(s.surface_area, 12.727922061357855)
manual = self.cu.copy()
manual.make_supercell(s.scale_factor)
self.assertEqual(manual.lattice.lengths_and_angles,
s.lattice.lengths_and_angles)
# # For visual debugging
# from pymatgen import write_structure
# write_structure(s.parent, "cu.cif")
# write_structure(s, "cu_slab_%s_%.3f_%.3f.cif" %
# (str(hkl), ssize, vsize))
def test_adsorb_atom(self):
s001 = Slab(self.cu,[0, 0, 1], 5, 5)
# print s001
# O adsorb on 4Cu[0.5, 0.5, 0.25], abc = [3, 3, 12]
# 1. test site_a = abc input
s001_ad1 = Slab.adsorb_atom(structure_a=s001, site_a=[0.5, 0.5, 0.25], atom= ['O'],
distance=2)
self.assertEqual(len(s001_ad1), 9)
for i in xrange(len(s001_ad1)):
if str(s001_ad1[i].specie) == 'O':
print s001_ad1[i].frac_coords
self.assertAlmostEqual(s001_ad1[i].a, 0.5)
self.assertAlmostEqual(s001_ad1[i].b, 0.5)
self.assertAlmostEqual(s001_ad1[i].c, 0.4166667)
self.assertEqual(s001_ad1.lattice.lengths_and_angles,
s001.lattice.lengths_and_angles)
# 2. test site_a = xyz input
s001_ad2 = Slab.adsorb_atom(structure_a=s001, site_a=[1.5, 1.5, 3], atom= ['O'],
distance=2, xyz=1)
self.assertEqual(len(s001_ad2), 9)
for i in xrange(len(s001_ad2)):
if str(s001_ad2[i].specie) == 'O':
print s001_ad2[i].frac_coords
self.assertAlmostEqual(s001_ad2[i].a, 0.5)
self.assertAlmostEqual(s001_ad2[i].b, 0.5)
self.assertAlmostEqual(s001_ad2[i].c, 0.4166667)
def apply_transformation(self, structure: Structure) -> Structure:
"""
Apply the transformation.
Args:
structure: Input Structure
Returns:
Structure with sites perturbed.
"""
s = structure.copy()
s.perturb(self.distance, min_distance=self.min_distance)
return s
def __init__(self,
structure: Structure,
task: Task,
xc: Xc,
**input_options):
self._input_options = deepcopy(input_options)
self._input_options.update(
{"initial_structure": structure.copy(),
"task": task,
"xc": xc})
self._set_kpt_density()
self._raise_error_when_unknown_options_exist()
def test_primitive_positions(self):
coords = [[0, 0, 0], [0.3, 0.35, 0.45]]
s = Structure(Lattice.from_parameters(1,2,3,50,66,88), ["Ag"] * 2, coords)
a = [[-1,2,-3], [3,2,-4], [1,0,-1]]
b = [[4, 0, 0], [1, 1, 0], [3, 0, 1]]
c = [[2, 0, 0], [1, 3, 0], [1, 1, 1]]
for sc_matrix in [c]:
sc = s.copy()
sc.make_supercell(sc_matrix)
prim = sc.get_primitive_structure(0.01)
self.assertEqual(len(prim), 2)
self.assertAlmostEqual(prim.distance_matrix[0,1], 1.0203432356739286)
def test_primitive_positions(self):
coords = [[0, 0, 0], [0.3, 0.35, 0.45]]
s = Structure(Lattice.from_parameters(1, 2, 3, 50, 66, 88), ["Ag"] * 2,
coords)
a = [[-1, 2, -3], [3, 2, -4], [1, 0, -1]]
b = [[4, 0, 0], [1, 1, 0], [3, 0, 1]]
c = [[2, 0, 0], [1, 3, 0], [1, 1, 1]]
for sc_matrix in [c]:
sc = s.copy()
sc.make_supercell(sc_matrix)
prim = sc.get_primitive_structure(0.01)
self.assertEqual(len(prim), 2)
self.assertAlmostEqual(prim.distance_matrix[0, 1],
1.0203432356739286)
def perturb_neighboring_atoms(structure: Structure,
center: List[float],
cutoff: float,
distance: float,
inserted_atom_indices: List[int]
) -> Tuple[Structure, list]:
""" Return the structure with randomly perturbed atoms near the center
Args:
structure (Structure):
pmg Structure class object
center (list):
Fractional coordinates of a central position.
cutoff (float):
Radius of a sphere in which atoms are perturbed.
distance (float):
Max displacement distance for the perturbation.
inserted_atom_indices (list):
Inserted atom indices, which will not be perturbed.
Return:
Tuple of perturbed Structure and list of perturbed atom indices.
"""
perturbed_structure = structure.copy()
cartesian_coords = structure.lattice.get_cartesian_coords(center)
# neighbor is (PeriodicSite, distance, index)
neighbors = structure.get_sites_in_sphere(
pt=cartesian_coords, r=cutoff, include_index=True)
if not neighbors:
logger.warning(f"No neighbors withing the cutoff {cutoff}.")
sites = []
for i in neighbors:
# not perturb inserted atoms
if i[2] in inserted_atom_indices:
continue
# Since translate_sites accepts only one vector, iterate this.
vector = normalized_random_3d_vector() * distance * np.random.random()
site_index = i[2]
sites.append(site_index)
perturbed_structure.translate_sites(
indices=site_index, vector=vector, frac_coords=False)
return perturbed_structure, sites
class SlabTest(unittest.TestCase):
def setUp(self):
self.cu = Structure(Lattice.cubic(3), ["Cu", "Cu", "Cu", "Cu"],
[[0, 0, 0], [0.5, 0.5, 0], [0.5, 0, 0.5],
[0, 0.5, 0.5]])
def test_init(self):
for hkl in itertools.product(xrange(4), xrange(4), xrange(4)):
if any(hkl):
ssize = 6
vsize = 10
s = Slab(self.cu, hkl, ssize, vsize)
if hkl == [0, 1, 1]:
self.assertEqual(len(s), 13)
self.assertAlmostEqual(s.surface_area, 12.727922061357855)
manual = self.cu.copy()
manual.make_supercell(s.scale_factor)
self.assertEqual(manual.lattice.lengths_and_angles,
s.lattice.lengths_and_angles)
def test_copy(self):
new_struct = self.propertied_structure.copy(site_properties={'charge':
[2, 3]})
self.assertEqual(new_struct[0].magmom, 5)
self.assertEqual(new_struct[1].magmom, -5)
self.assertEqual(new_struct[0].charge, 2)
self.assertEqual(new_struct[1].charge, 3)
coords = list()
coords.append([0, 0, 0])
coords.append([0., 0, 0.0000001])
structure = Structure(self.lattice, ["O", "Si"], coords,
site_properties={'magmom': [5, -5]})
new_struct = structure.copy(site_properties={'charge': [2, 3]},
sanitize=True)
self.assertEqual(new_struct[0].magmom, -5)
self.assertEqual(new_struct[1].magmom, 5)
self.assertEqual(new_struct[0].charge, 3)
self.assertEqual(new_struct[1].charge, 2)
self.assertAlmostEqual(new_struct.volume, structure.volume)
def num_equivalent_clusters(structure: Structure,
inserted_atom_coords: Optional[list],
removed_atom_indices: Optional[list],
symprec: float = SYMMETRY_TOLERANCE,
angle_tolerance: float = ANGLE_TOL
) -> Tuple[int, str]:
"""Calculate number of equivalent clusters in the structure.
Args:
structure (Structure):
Supercell is assumed to big enough.
inserted_atom_coords (list):
removed_atom_indices (list):
Needs to begin from 0.
symprec (float):
angle_tolerance (float):
Angle tolerance in degree used for identifying the space group.
Returns:
Tuple of (num_equivalent_clusters (int), point_group (str))
"""
inserted_atom_coords = inserted_atom_coords or []
removed_atom_indices = removed_atom_indices or []
sga = SpacegroupAnalyzer(structure, symprec, angle_tolerance)
num_symmop = len(sga.get_symmetry_operations())
structure_with_cluster = structure.copy()
for i in inserted_atom_coords:
structure_with_cluster.append(DummySpecie(), i)
structure_with_cluster.remove_sites(removed_atom_indices)
sga_with_cluster = \
SpacegroupAnalyzer(structure_with_cluster, symprec, angle_tolerance)
sym_dataset = sga_with_cluster.get_symmetry_dataset()
point_group = sym_dataset["pointgroup"]
return int(num_symmop / num_symmetry_operation(point_group)), point_group
def __init__(
self,
grid_data: np.ndarray,
structure: Structure,
normalization: str = "vasp",
):
"""
Class that contains functions to featurize volumetic data with periodic
boundary conditions.
Make sure the data being stored is grid-independent
Args:
grid_data: Volumetric data to read in
structure: Atomic structure corresponding to the charge density
normalization: the normalization scheme:
- 'vasp' sum of the data / number of grid points == number of electrons
"""
self.structure = structure.copy()
self.normalization = normalization
if normalization[0].lower() == "n":
"""
No rescaling
"""
scaled_data = grid_data
elif normalization[0].lower() == "v":
"""
the standard charge density from VASP is given as (rho*V) such that:
sum(rho)/NGRID = NELECT/UC_vol
so the real rho is:
rho = (rho*UC_vol)*NGRID/UC_vol/UC_vol
where the second V account for the different number of electrons in
different cells
"""
scaled_data = grid_data / self.structure.volume
else:
raise NotImplementedError("Not a valid normalization scheme")
super().__init__(grid_data=scaled_data, lattice=None)
class TestMaterials(unittest.TestCase):
def setUp(self):
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice([[3.8401979337, 0.00, 0.00],
[1.9200989668, 3.3257101909, 0.00],
[0.00, -2.2171384943, 3.1355090603]])
self.structure = Structure(lattice, ["Si", "Si"], coords)
tasks = MongoStore("emmet_test", "tasks")
materials = MongoStore("emmet_test", "materials")
self.mbuilder = MaterialsBuilder(tasks,
materials,
mat_prefix="",
chunk_size=1)
def test_make_mat(self):
struc1 = self.structure.copy()
struc2 = self.structure.copy()
struc2.translate_sites(1, [0.5, 0, 0])
tasks = [{
"task_id": "mp-1",
"orig_inputs": {
"incar": {
"LDAU": True,
"ISIF": 3,
"IBRION": 1
}
},
"output": {
"structure": struc1.as_dict(),
"bandgap": 1.3
},
"formula_anonymous": "A",
"formula_pretty": "Cl",
"last_updated": "Never"
}, {
"task_id": "mp-2",
"orig_inputs": {
"incar": {
"LDAU": True,
"ICHARG": 11,
"IBRION": 1
}
},
"output": {
"structure": struc2.as_dict(),
"bandgap": 2
},
"formula_anonymous": "A",
"formula_pretty": "Cl",
"last_updated": "Never"
}]
mat = self.mbuilder.make_mat(tasks)
self.assertEqual(mat["task_ids"], ["mp-1", "mp-2"])
for k in [
"task_ids", "task_id", "origins", "task_types",
"formula_anonymous", "bandstructure", "inputs",
"formula_pretty", "structure"
]:
self.assertIn(k, mat)
self.assertIn(self.mbuilder.materials.lu_field, mat)
def test_filter_and_group_tasks(self):
si = self.structure
si2 = si.copy()
si2.translate_sites(1, [0.5, 0, 0])
si3 = si.copy()
si3.make_supercell(2)
si4 = si.copy()
si4.make_supercell(2)
si4.translate_sites(1, [0.1, 0, 0])
incar = {"incar": {"LDAU": True, "ISIF": 3, "IBRION": 1}}
task1 = {
"output": {
"structure": si.as_dict()
},
"task_id": "mp-1",
"orig_inputs": incar
}
task2 = {
"output": {
"structure": si2.as_dict()
},
"task_id": "mp-2",
"orig_inputs": incar
}
task3 = {
"output": {
"structure": si3.as_dict()
},
"task_id": "mp-3",
"orig_inputs": incar
}
task4 = {
"output": {
"structure": si4.as_dict()
},
"task_id": "mp-4",
"orig_inputs": incar
}
grouped_tasks = list(
self.mbuilder.filter_and_group_tasks([task1, task2, task3, task4]))
self.assertEqual(len(grouped_tasks), 3)
task_ids = [[t["task_id"] for t in tasks] for tasks in grouped_tasks]
self.assertIn(["mp-2"], task_ids)
def test_task_to_prop_list(self):
task = {
"task_id": "mp-3",
"orig_inputs": {
"incar": {
"LDAU": True,
"ISIF": 3,
"IBRION": 1
}
},
"output": {
"bandgap": 1.3,
"structure": "What structure"
},
"formula_anonymous": "A",
"formula_pretty": "Cl",
"last_updated": "Never"
}
prop_list = self.mbuilder.task_to_prop_list(task)
for p in prop_list:
self.assertIn("value", p)
self.assertIn("task_type", p)
self.assertIn("quality_score", p)
self.assertIn("track", p)
self.assertIn("last_updated", p)
self.assertIn("task_id", p)
self.assertIn("materials_key", p)
prop_names = [p["materials_key"] for p in prop_list]
props_in = [
'structure', 'inputs.structure_optimization',
'bandstructure.band_gap'
]
props_not_in = [
'formula_anonymous', 'formula_pretty', 'bandstructure.cbm',
'bandstructure.vbm', 'chemsys', 'analysis.delta_volume',
'thermo.energy'
]
for p in props_in:
self.assertIn(p, prop_names)
for p in props_not_in:
self.assertNotIn(p, prop_names)
class StructureTest(PymatgenTest):
def setUp(self):
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice([[3.8401979337, 0.00, 0.00],
[1.9200989668, 3.3257101909, 0.00],
[0.00, -2.2171384943, 3.1355090603]])
self.structure = Structure(lattice, ["Si", "Si"], coords)
def test_mutable_sequence_methods(self):
s = self.structure
s[0] = "Fe"
self.assertEqual(s.formula, "Fe1 Si1")
s[0] = "Fe", [0.5, 0.5, 0.5]
self.assertEqual(s.formula, "Fe1 Si1")
self.assertArrayAlmostEqual(s[0].frac_coords, [0.5, 0.5, 0.5])
s.reverse()
self.assertEqual(s[0].specie, Element("Si"))
self.assertArrayAlmostEqual(s[0].frac_coords, [0.75, 0.5, 0.75])
s[0] = {"Mn": 0.5}
self.assertEqual(s.formula, "Mn0.5 Fe1")
del s[1]
self.assertEqual(s.formula, "Mn0.5")
s[0] = "Fe", [0.9, 0.9, 0.9], {"magmom": 5}
self.assertEqual(s.formula, "Fe1")
self.assertEqual(s[0].magmom, 5)
def test_non_hash(self):
self.assertRaises(TypeError, dict, [(self.structure, 1)])
def test_sort(self):
s = self.structure
s[0] = "F"
s.sort()
self.assertEqual(s[0].species_string, "Si")
self.assertEqual(s[1].species_string, "F")
s.sort(key=lambda site: site.species_string)
self.assertEqual(s[0].species_string, "F")
self.assertEqual(s[1].species_string, "Si")
s.sort(key=lambda site: site.species_string, reverse=True)
self.assertEqual(s[0].species_string, "Si")
self.assertEqual(s[1].species_string, "F")
def test_append_insert_remove_replace(self):
s = self.structure
s.insert(1, "O", [0.5, 0.5, 0.5])
self.assertEqual(s.formula, "Si2 O1")
self.assertTrue(s.ntypesp == 2)
self.assertTrue(s.symbol_set == ("Si", "O"))
self.assertTrue(s.indices_from_symbol("Si") == (0, 2))
self.assertTrue(s.indices_from_symbol("O") == (1, ))
s.remove(2)
self.assertEqual(s.formula, "Si1 O1")
self.assertTrue(s.indices_from_symbol("Si") == (0, ))
self.assertTrue(s.indices_from_symbol("O") == (1, ))
s.append("N", [0.25, 0.25, 0.25])
self.assertEqual(s.formula, "Si1 N1 O1")
self.assertTrue(s.ntypesp == 3)
self.assertTrue(s.symbol_set == ("Si", "O", "N"))
self.assertTrue(s.indices_from_symbol("Si") == (0, ))
self.assertTrue(s.indices_from_symbol("O") == (1, ))
self.assertTrue(s.indices_from_symbol("N") == (2, ))
s.replace(0, "Ge")
self.assertEqual(s.formula, "Ge1 N1 O1")
self.assertTrue(s.symbol_set == ("Ge", "O", "N"))
s.replace_species({"Ge": "Si"})
self.assertEqual(s.formula, "Si1 N1 O1")
self.assertTrue(s.ntypesp == 3)
s.replace_species({"Si": {"Ge": 0.5, "Si": 0.5}})
self.assertEqual(s.formula, "Si0.5 Ge0.5 N1 O1")
#this should change the .5Si .5Ge sites to .75Si .25Ge
s.replace_species({"Ge": {"Ge": 0.5, "Si": 0.5}})
self.assertEqual(s.formula, "Si0.75 Ge0.25 N1 O1")
# In this case, s.ntypesp is ambiguous.
# for the time being, we raise AttributeError.
with self.assertRaises(AttributeError):
s.ntypesp
s.remove_species(["Si"])
self.assertEqual(s.formula, "Ge0.25 N1 O1")
s.remove_sites([1, 2])
self.assertEqual(s.formula, "Ge0.25")
def test_add_site_property(self):
s = self.structure
s.add_site_property("charge", [4.1, -5])
self.assertEqual(s[0].charge, 4.1)
self.assertEqual(s[1].charge, -5)
s.add_site_property("magmom", [3, 2])
self.assertEqual(s[0].charge, 4.1)
self.assertEqual(s[0].magmom, 3)
def test_perturb(self):
d = 0.1
pre_perturbation_sites = self.structure.sites[:]
self.structure.perturb(distance=d)
post_perturbation_sites = self.structure.sites
for i, x in enumerate(pre_perturbation_sites):
self.assertAlmostEqual(x.distance(post_perturbation_sites[i]), d,
3, "Bad perturbation distance")
def test_add_oxidation_states(self):
oxidation_states = {"Si": -4}
self.structure.add_oxidation_state_by_element(oxidation_states)
for site in self.structure:
for k in site.species_and_occu.keys():
self.assertEqual(k.oxi_state, oxidation_states[k.symbol],
"Wrong oxidation state assigned!")
oxidation_states = {"Fe": 2}
self.assertRaises(ValueError,
self.structure.add_oxidation_state_by_element,
oxidation_states)
self.structure.add_oxidation_state_by_site([2, -4])
self.assertEqual(self.structure[0].specie.oxi_state, 2)
self.assertRaises(ValueError,
self.structure.add_oxidation_state_by_site, [1])
def test_remove_oxidation_states(self):
co_elem = Element("Co")
o_elem = Element("O")
co_specie = Specie("Co", 2)
o_specie = Specie("O", -2)
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice.cubic(10)
s_elem = Structure(lattice, [co_elem, o_elem], coords)
s_specie = Structure(lattice, [co_specie, o_specie], coords)
s_specie.remove_oxidation_states()
self.assertEqual(s_elem, s_specie, "Oxidation state remover " "failed")
def test_apply_operation(self):
op = SymmOp.from_axis_angle_and_translation([0, 0, 1], 90)
self.structure.apply_operation(op)
self.assertArrayAlmostEqual(
self.structure.lattice.matrix,
[[0.000000, 3.840198, 0.000000], [-3.325710, 1.920099, 0.000000],
[2.217138, -0.000000, 3.135509]], 5)
def test_apply_strain(self):
s = self.structure
initial_coord = s[1].coords
s.apply_strain(0.01)
self.assertAlmostEqual(
s.lattice.abc,
(3.8785999130369997, 3.878600984287687, 3.8785999130549516))
self.assertArrayAlmostEqual(s[1].coords, initial_coord * 1.01)
a1, b1, c1 = s.lattice.abc
s.apply_strain([0.1, 0.2, 0.3])
a2, b2, c2 = s.lattice.abc
self.assertAlmostEqual(a2 / a1, 1.1)
self.assertAlmostEqual(b2 / b1, 1.2)
self.assertAlmostEqual(c2 / c1, 1.3)
def test_scale_lattice(self):
initial_coord = self.structure[1].coords
self.structure.scale_lattice(self.structure.volume * 1.01**3)
self.assertArrayAlmostEqual(
self.structure.lattice.abc,
(3.8785999130369997, 3.878600984287687, 3.8785999130549516))
self.assertArrayAlmostEqual(self.structure[1].coords,
initial_coord * 1.01)
def test_translate_sites(self):
self.structure.translate_sites([0, 1], [0.5, 0.5, 0.5],
frac_coords=True)
self.assertArrayEqual(self.structure.frac_coords[0], [0.5, 0.5, 0.5])
self.structure.translate_sites([0], [0.5, 0.5, 0.5], frac_coords=False)
self.assertArrayAlmostEqual(self.structure.cart_coords[0],
[3.38014845, 1.05428585, 2.06775453])
self.structure.translate_sites([0], [0.5, 0.5, 0.5],
frac_coords=True,
to_unit_cell=False)
self.assertArrayAlmostEqual(self.structure.frac_coords[0],
[1.00187517, 1.25665291, 1.15946374])
def test_make_supercell(self):
self.structure.make_supercell([2, 1, 1])
self.assertEqual(self.structure.formula, "Si4")
self.structure.make_supercell([[1, 0, 0], [2, 1, 0], [0, 0, 1]])
self.assertEqual(self.structure.formula, "Si4")
self.structure.make_supercell(2)
self.assertEqual(self.structure.formula, "Si32")
self.assertArrayAlmostEqual(self.structure.lattice.abc,
[15.360792, 35.195996, 7.680396], 5)
def test_disordered_supercell_primitive_cell(self):
l = Lattice.cubic(2)
f = [[0.5, 0.5, 0.5]]
sp = [{'Si': 0.54738}]
s = Structure(l, sp, f)
#this supercell often breaks things
s.make_supercell([[0, -1, 1], [-1, 1, 0], [1, 1, 1]])
self.assertEqual(len(s.get_primitive_structure()), 1)
def test_another_supercell(self):
#this is included b/c for some reason the old algo was failing on it
s = self.structure.copy()
s.make_supercell([[0, 2, 2], [2, 0, 2], [2, 2, 0]])
self.assertEqual(s.formula, "Si32")
s = self.structure.copy()
s.make_supercell([[0, 2, 0], [1, 0, 0], [0, 0, 1]])
self.assertEqual(s.formula, "Si4")
def test_to_from_dict(self):
d = self.structure.to_dict
s2 = Structure.from_dict(d)
self.assertEqual(type(s2), Structure)
def test_propertied_structure_mod(self):
prop_structure = Structure(self.structure.lattice, ["Si"] * 2,
self.structure.frac_coords,
site_properties={'magmom': [5, -5]})
prop_structure.append("C", [0.25, 0.25, 0.25])
d = prop_structure.to_dict
with warnings.catch_warnings(record=True) as w:
# Cause all warnings to always be triggered.
warnings.simplefilter("always")
s2 = Structure.from_dict(d)
self.assertEqual(len(w), 1)
self.assertEqual(
str(w[0].message),
'Not all sites have property magmom. Missing values are set '
'to None.')
def apply_transformation(self, structure, return_ranked_list=False):
"""
Return either a single ordered structure or a sequence of all ordered
structures.
Args:
structure: Structure to order.
return_ranked_list (bool): Whether or not multiple structures are
returned. If return_ranked_list is a number, that number of
structures is returned.
Returns:
Depending on returned_ranked list, either a transformed structure
or a list of dictionaries, where each dictionary is of the form
{"structure" = .... , "other_arguments"}
The list of ordered structures is ranked by ewald energy / atom, if
the input structure is an oxidation state decorated structure.
Otherwise, it is ranked by number of sites, with smallest number of
sites first.
"""
try:
num_to_return = int(return_ranked_list)
except ValueError:
num_to_return = 1
if self.occu_tol:
species = [dict(d) for d in structure.species_and_occu]
# Here, we rescale all occupancies such that they meet the frac
# limit.
for sp in species:
for k, v in sp.items():
sp[k] = float(Fraction(v).limit_denominator(self.occu_tol))
structure = Structure(structure.lattice, species,
structure.frac_coords)
if self.refine_structure:
finder = SpacegroupAnalyzer(structure, self.symm_prec)
structure = finder.get_refined_structure()
contains_oxidation_state = all(
[hasattr(sp, "oxi_state") and sp.oxi_state != 0 for sp in
structure.composition.elements]
)
if structure.is_ordered:
warn("Enumeration skipped for structure with composition {} "
"because it is ordered".format(structure.composition))
structures = [structure.copy()]
else:
adaptor = EnumlibAdaptor(
structure, min_cell_size=self.min_cell_size,
max_cell_size=self.max_cell_size,
symm_prec=self.symm_prec, refine_structure=False,
enum_precision_parameter=self.enum_precision_parameter,
check_ordered_symmetry=self.check_ordered_symmetry)
adaptor.run()
structures = adaptor.structures
original_latt = structure.lattice
inv_latt = np.linalg.inv(original_latt.matrix)
ewald_matrices = {}
all_structures = []
for s in structures:
new_latt = s.lattice
transformation = np.dot(new_latt.matrix, inv_latt)
transformation = tuple([tuple([int(round(cell)) for cell in row])
for row in transformation])
if contains_oxidation_state:
if transformation not in ewald_matrices:
s_supercell = structure * transformation
ewald = EwaldSummation(s_supercell)
ewald_matrices[transformation] = ewald
else:
ewald = ewald_matrices[transformation]
energy = ewald.compute_sub_structure(s)
all_structures.append({"num_sites": len(s), "energy": energy,
"structure": s})
else:
all_structures.append({"num_sites": len(s), "structure": s})
def sort_func(s):
return s["energy"] / s["num_sites"] if contains_oxidation_state \
else s["num_sites"]
self._all_structures = sorted(all_structures, key=sort_func)
if return_ranked_list:
return self._all_structures[0:num_to_return]
else:
return self._all_structures[0]["structure"]
def __init__(
self,
structure: Structure,
overwrite_magmom_mode: Union[OverwriteMagmomMode, str] = "none",
round_magmoms: bool = False,
detect_valences: bool = False,
make_primitive: bool = True,
default_magmoms: bool = None,
set_net_positive: bool = True,
threshold: float = 0.1,
):
"""
A class which provides a few helpful methods to analyze
collinear magnetic structures.
If magnetic moments are not defined, moments will be
taken either from default_magmoms.yaml (similar to the
default magmoms in MPRelaxSet, with a few extra definitions)
or from a specie:magmom dict provided by the default_magmoms
kwarg.
Input magmoms can be replaced using the 'overwrite_magmom_mode'
kwarg. This can be:
* "none" to do nothing,
* "respect_sign" which will overwrite existing magmoms with
those from default_magmoms but will keep sites with positive magmoms
positive, negative magmoms negative and zero magmoms zero,
* "respect_zeros", which will give a ferromagnetic structure
(all positive magmoms from default_magmoms) but still keep sites with
zero magmoms as zero,
* "replace_all" which will try to guess initial magmoms for
all sites in the structure irrespective of input structure
(this is most suitable for an initial DFT calculation),
* "replace_all_if_undefined" is the same as "replace_all" but only if
no magmoms are defined in input structure, otherwise it will respect
existing magmoms.
* "normalize" will normalize magmoms to unity, but will respect sign
(used for comparing orderings), magmoms < theshold will be set to zero
:param structure: Structure object
:param overwrite_magmom_mode (str): default "none"
:param round_magmoms (int or bool): will round input magmoms to
specified number of decimal places if integer is supplied, if set
to a float will try and group magmoms together using a kernel density
estimator of provided width, and extracting peaks of the estimator
:param detect_valences (bool): if True, will attempt to assign valences
to input structure
:param make_primitive (bool): if True, will transform to primitive
magnetic cell
:param default_magmoms (dict): (optional) dict specifying default magmoms
:param set_net_positive (bool): if True, will change sign of magnetic
moments such that the net magnetization is positive. Argument will be
ignored if mode "respect_sign" is used.
:param threshold (float): number (in Bohr magnetons) below which magmoms
will be rounded to zero, default of 0.1 can probably be increased for many
magnetic systems, depending on your application
"""
if default_magmoms:
self.default_magmoms = default_magmoms
else:
self.default_magmoms = DEFAULT_MAGMOMS
structure = structure.copy()
# check for disorder
if not structure.is_ordered:
raise NotImplementedError(
"Not implemented for disordered structures, "
"make ordered approximation first.")
if detect_valences:
trans = AutoOxiStateDecorationTransformation()
bva = BVAnalyzer()
try:
structure = trans.apply_transformation(structure)
except ValueError:
warnings.warn("Could not assign valences "
"for {}".format(
structure.composition.reduced_formula))
# check to see if structure has magnetic moments
# on site properties or species spin properties,
# prioritize site properties
has_magmoms = bool(structure.site_properties.get("magmom", False))
has_spin = False
for comp in structure.species_and_occu:
for sp, occu in comp.items():
if getattr(sp, "spin", False):
has_spin = True
# perform input sanitation ...
# rest of class will assume magnetic moments
# are stored on site properties:
# this is somewhat arbitrary, arguments can
# be made for both approaches
if has_magmoms and has_spin:
raise ValueError("Structure contains magnetic moments on both "
"magmom site properties and spin species "
"properties. This is ambiguous. Remove one or "
"the other.")
elif has_magmoms:
if None in structure.site_properties["magmom"]:
warnings.warn("Be careful with mixing types in your magmom "
"site properties. Any 'None' magmoms have been "
"replaced with zero.")
magmoms = [
m if m else 0 for m in structure.site_properties["magmom"]
]
elif has_spin:
magmoms = [getattr(sp, "spin", 0) for sp in structure.species]
structure.remove_spin()
else:
# no magmoms present, add zero magmoms for now
magmoms = [0] * len(structure)
# and overwrite magmoms with default magmoms later unless otherwise stated
if overwrite_magmom_mode == "replace_all_if_undefined":
overwrite_magmom_mode = "replace_all"
# test to see if input structure has collinear magmoms
self.is_collinear = Magmom.are_collinear(magmoms)
if not self.is_collinear:
warnings.warn(
"This class is not designed to be used with "
"non-collinear structures. If your structure is "
"only slightly non-collinear (e.g. canted) may still "
"give useful results, but use with caution.")
# this is for collinear structures only, make sure magmoms
# are all floats
magmoms = list(map(float, magmoms))
# set properties that should be done /before/ we process input magmoms
self.total_magmoms = sum(magmoms)
self.magnetization = sum(magmoms) / structure.volume
# round magmoms below threshold to zero
magmoms = [m if abs(m) > threshold else 0 for m in magmoms]
# overwrite existing magmoms with default_magmoms
if overwrite_magmom_mode not in (
"none",
"respect_sign",
"respect_zeros",
"replace_all",
"replace_all_if_undefined",
"normalize",
):
raise ValueError("Unsupported mode.")
for idx, site in enumerate(structure):
if site.species_string in self.default_magmoms:
# look for species first, e.g. Fe2+
default_magmom = self.default_magmoms[site.species_string]
elif (isinstance(site.specie, Specie)
and str(site.specie.element) in self.default_magmoms):
# look for element, e.g. Fe
default_magmom = self.default_magmoms[str(site.specie.element)]
else:
default_magmom = 0
# overwrite_magmom_mode = "respect_sign" will change magnitude of
# existing moments only, and keep zero magmoms as
# zero: it will keep the magnetic ordering intact
if overwrite_magmom_mode == "respect_sign":
set_net_positive = False
if magmoms[idx] > 0:
magmoms[idx] = default_magmom
elif magmoms[idx] < 0:
magmoms[idx] = -default_magmom
# overwrite_magmom_mode = "respect_zeros" will give a ferromagnetic
# structure but will keep zero magmoms as zero
elif overwrite_magmom_mode == "respect_zeros":
if magmoms[idx] != 0:
magmoms[idx] = default_magmom
# overwrite_magmom_mode = "replace_all" will ignore input magmoms
# and give a ferromagnetic structure with magnetic
# moments on *all* atoms it thinks could be magnetic
elif overwrite_magmom_mode == "replace_all":
magmoms[idx] = default_magmom
# overwrite_magmom_mode = "normalize" set magmoms magnitude to 1
elif overwrite_magmom_mode == "normalize":
if magmoms[idx] != 0:
magmoms[idx] = int(magmoms[idx] / abs(magmoms[idx]))
# round magmoms, used to smooth out computational data
magmoms = (self._round_magmoms(magmoms, round_magmoms)
if round_magmoms else magmoms)
if set_net_positive:
sign = np.sum(magmoms)
if sign < 0:
magmoms = -np.array(magmoms)
structure.add_site_property("magmom", magmoms)
if make_primitive:
structure = structure.get_primitive_structure(use_site_props=True)
self.structure = structure
class StructureTest(unittest.TestCase):
def setUp(self):
self.si = Element("Si")
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
self.lattice = Lattice([[3.8401979337, 0.00, 0.00],
[1.9200989668, 3.3257101909, 0.00],
[0.00, -2.2171384943, 3.1355090603]])
self.struct = Structure(self.lattice, [self.si, self.si], coords)
self.assertEqual(len(self.struct), 2,
"Wrong number of sites in structure!")
self.assertTrue(self.struct.is_ordered)
coords = list()
coords.append([0, 0, 0])
coords.append([0., 0, 0.0000001])
self.assertRaises(StructureError, Structure, self.lattice,
[self.si, self.si], coords, True)
self.propertied_structure = Structure(self.lattice, [self.si, self.si],
coords,
site_properties={'magmom':
[5, -5]})
def test_volume_and_density(self):
self.assertAlmostEqual(self.struct.volume, 40.04, 2, "Volume wrong!")
self.assertAlmostEqual(self.struct.density, 2.33, 2,
"Incorrect density")
def test_specie_init(self):
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
s = Structure(self.lattice, [{Specie('O', -2):1.0},
{Specie('Mg', 2):0.8}], coords)
self.assertEqual(str(s.composition), 'Mg2+0.8 O2-1')
def test_get_sorted_structure(self):
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
s = Structure(self.lattice, ["O", "Li"], coords,
site_properties={'charge': [-2, 1]})
sorted_s = s.get_sorted_structure()
self.assertEqual(sorted_s[0].species_and_occu, Composition("Li"))
self.assertEqual(sorted_s[1].species_and_occu, Composition("O"))
self.assertEqual(sorted_s[0].charge, 1)
self.assertEqual(sorted_s[1].charge, -2)
def test_fractional_occupations(self):
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
s = Structure(self.lattice, [{Element('O'):1.0}, {Element('Mg'):0.8}],
coords)
self.assertEqual(str(s.composition), 'Mg0.8 O1')
self.assertFalse(s.is_ordered)
def test_get_distance(self):
self.assertAlmostEqual(self.struct.get_distance(0, 1), 2.35, 2,
"Distance calculated wrongly!")
pt = [0.9, 0.9, 0.8]
self.assertAlmostEqual(self.struct[0].distance_from_point(pt),
1.50332963784, 2,
"Distance calculated wrongly!")
def test_to_dict(self):
si = Specie("Si", 4)
mn = Element("Mn")
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
struct = Structure(self.lattice, [{si:0.5, mn:0.5}, {si:0.5}], coords)
self.assertIn("lattice", struct.to_dict)
self.assertIn("sites", struct.to_dict)
d = self.propertied_structure.to_dict
self.assertEqual(d['sites'][0]['properties']['magmom'], 5)
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
s = Structure(self.lattice, [{Specie('O', -2,
properties={"spin":3}):1.0},
{Specie('Mg', 2,
properties={"spin":2}):0.8}],
coords, site_properties={'magmom': [5, -5]})
d = s.to_dict
self.assertEqual(d['sites'][0]['properties']['magmom'], 5)
self.assertEqual(d['sites'][0]['species'][0]['properties']['spin'], 3)
def test_from_dict(self):
d = self.propertied_structure.to_dict
s = Structure.from_dict(d)
self.assertEqual(s[0].magmom, 5)
d = {'lattice': {'a': 3.8401979337, 'volume': 40.044794644251596,
'c': 3.8401979337177736, 'b': 3.840198994344244,
'matrix': [[3.8401979337, 0.0, 0.0],
[1.9200989668, 3.3257101909, 0.0],
[0.0, -2.2171384943, 3.1355090603]],
'alpha': 119.9999908639842, 'beta': 90.0,
'gamma': 60.000009137322195},
'sites': [{'properties': {'magmom': 5}, 'abc': [0.0, 0.0, 0.0],
'occu': 1.0, 'species': [{'occu': 1.0,
'oxidation_state':-2,
'properties': {'spin': 3},
'element': 'O'}],
'label': 'O2-', 'xyz': [0.0, 0.0, 0.0]},
{'properties': {'magmom':-5}, 'abc': [0.75, 0.5, 0.75],
'occu': 0.8, 'species': [{'occu': 0.8,
'oxidation_state': 2,
'properties': {'spin': 2},
'element': 'Mg'}],
'label': 'Mg2+:0.800',
'xyz': [3.8401979336749994, 1.2247250003039056e-06,
2.351631795225]}]}
s = Structure.from_dict(d)
self.assertEqual(s[0].magmom, 5)
self.assertEqual(s[0].specie.spin, 3)
def test_site_properties(self):
site_props = self.propertied_structure.site_properties
self.assertEqual(site_props['magmom'], [5, -5])
self.assertEqual(self.propertied_structure[0].magmom, 5)
self.assertEqual(self.propertied_structure[1].magmom, -5)
def test_copy(self):
new_struct = self.propertied_structure.copy(site_properties={'charge':
[2, 3]})
self.assertEqual(new_struct[0].magmom, 5)
self.assertEqual(new_struct[1].magmom, -5)
self.assertEqual(new_struct[0].charge, 2)
self.assertEqual(new_struct[1].charge, 3)
coords = list()
coords.append([0, 0, 0])
coords.append([0., 0, 0.0000001])
structure = Structure(self.lattice, ["O", "Si"], coords,
site_properties={'magmom': [5, -5]})
new_struct = structure.copy(site_properties={'charge': [2, 3]},
sanitize=True)
self.assertEqual(new_struct[0].magmom, -5)
self.assertEqual(new_struct[1].magmom, 5)
self.assertEqual(new_struct[0].charge, 3)
self.assertEqual(new_struct[1].charge, 2)
self.assertAlmostEqual(new_struct.volume, structure.volume)
def test_interpolate(self):
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
struct = Structure(self.lattice, [self.si, self.si], coords)
coords2 = list()
coords2.append([0, 0, 0])
coords2.append([0.5, 0.5, 0.5])
struct2 = Structure(self.struct.lattice, [self.si, self.si], coords2)
int_s = struct.interpolate(struct2, 10)
for s in int_s:
self.assertIsNotNone(s, "Interpolation Failed!")
self.assertTrue((int_s[1][1].frac_coords == [0.725, 0.5, 0.725]).all())
badlattice = [[1, 0.00, 0.00], [0, 1, 0.00], [0.00, 0, 1]]
struct2 = Structure(badlattice, [self.si, self.si], coords2)
self.assertRaises(ValueError, struct.interpolate, struct2)
coords2 = list()
coords2.append([0, 0, 0])
coords2.append([0.5, 0.5, 0.5])
struct2 = Structure(self.struct.lattice, [self.si, Element("Fe")],
coords2)
self.assertRaises(ValueError, struct.interpolate, struct2)
def test_get_primitive_structure(self):
coords = [[0, 0, 0], [0.5, 0.5, 0], [0, 0.5, 0.5], [0.5, 0, 0.5]]
fcc_ag = Structure(Lattice.cubic(4.09), ["Ag"] * 4, coords)
self.assertEqual(len(fcc_ag.get_primitive_structure()), 1)
coords = [[0, 0, 0], [0.5, 0.5, 0.5]]
bcc_li = Structure(Lattice.cubic(4.09), ["Li"] * 2, coords)
self.assertEqual(len(bcc_li.get_primitive_structure()), 1)
def test_primitive_structure_volume_check(self):
l = Lattice.tetragonal(10, 30)
coords = [[0.5, 0.8, 0], [0.5, 0.2, 0],
[0.5, 0.8, 0.333], [0.5, 0.5, 0.333],
[0.5, 0.5, 0.666], [0.5, 0.2, 0.666]]
s = Structure(l, ["Ag"] * 6, coords)
sprim = s.get_primitive_structure(tolerance=0.1)
self.assertEqual(len(sprim), 6)
def test_get_all_neighbors_and_get_neighbors(self):
s = self.struct
r = random.uniform(3, 6)
all_nn = s.get_all_neighbors(r)
for i in range(len(s)):
self.assertEqual(len(all_nn[i]), len(s.get_neighbors(s[i], r)))
def test_get_dist_matrix(self):
ans = [[0., 2.3516318],
[2.3516318, 0.]]
self.assertTrue(np.allclose(self.struct.distance_matrix, ans))
class StructureTest(PymatgenTest):
def setUp(self):
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice([[3.8401979337, 0.00, 0.00],
[1.9200989668, 3.3257101909, 0.00],
[0.00, -2.2171384943, 3.1355090603]])
self.structure = Structure(lattice, ["Si", "Si"], coords)
def test_mutable_sequence_methods(self):
s = self.structure
s[0] = "Fe"
self.assertEqual(s.formula, "Fe1 Si1")
s[0] = "Fe", [0.5, 0.5, 0.5]
self.assertEqual(s.formula, "Fe1 Si1")
self.assertArrayAlmostEqual(s[0].frac_coords, [0.5, 0.5, 0.5])
s.reverse()
self.assertEqual(s[0].specie, Element("Si"))
self.assertArrayAlmostEqual(s[0].frac_coords, [0.75, 0.5, 0.75])
s[0] = {"Mn": 0.5}
self.assertEqual(s.formula, "Mn0.5 Fe1")
del s[1]
self.assertEqual(s.formula, "Mn0.5")
s[0] = "Fe", [0.9, 0.9, 0.9], {"magmom": 5}
self.assertEqual(s.formula, "Fe1")
self.assertEqual(s[0].magmom, 5)
# Test atomic replacement.
s["Fe"] = "Mn"
self.assertEqual(s.formula, "Mn1")
# Test slice replacement.
s = PymatgenTest.get_structure("Li2O")
s[1:3] = "S"
self.assertEqual(s.formula, "Li1 S2")
def test_non_hash(self):
self.assertRaises(TypeError, dict, [(self.structure, 1)])
def test_sort(self):
s = self.structure
s[0] = "F"
s.sort()
self.assertEqual(s[0].species_string, "Si")
self.assertEqual(s[1].species_string, "F")
s.sort(key=lambda site: site.species_string)
self.assertEqual(s[0].species_string, "F")
self.assertEqual(s[1].species_string, "Si")
s.sort(key=lambda site: site.species_string, reverse=True)
self.assertEqual(s[0].species_string, "Si")
self.assertEqual(s[1].species_string, "F")
def test_append_insert_remove_replace(self):
s = self.structure
s.insert(1, "O", [0.5, 0.5, 0.5])
self.assertEqual(s.formula, "Si2 O1")
self.assertTrue(s.ntypesp == 2)
self.assertTrue(s.symbol_set == ("Si", "O"))
self.assertTrue(s.indices_from_symbol("Si") == (0, 2))
self.assertTrue(s.indices_from_symbol("O") == (1, ))
del s[2]
self.assertEqual(s.formula, "Si1 O1")
self.assertTrue(s.indices_from_symbol("Si") == (0, ))
self.assertTrue(s.indices_from_symbol("O") == (1, ))
s.append("N", [0.25, 0.25, 0.25])
self.assertEqual(s.formula, "Si1 N1 O1")
self.assertTrue(s.ntypesp == 3)
self.assertTrue(s.symbol_set == ("Si", "O", "N"))
self.assertTrue(s.indices_from_symbol("Si") == (0, ))
self.assertTrue(s.indices_from_symbol("O") == (1, ))
self.assertTrue(s.indices_from_symbol("N") == (2, ))
s[0] = "Ge"
self.assertEqual(s.formula, "Ge1 N1 O1")
self.assertTrue(s.symbol_set == ("Ge", "O", "N"))
s.replace_species({"Ge": "Si"})
self.assertEqual(s.formula, "Si1 N1 O1")
self.assertTrue(s.ntypesp == 3)
s.replace_species({"Si": {"Ge": 0.5, "Si": 0.5}})
self.assertEqual(s.formula, "Si0.5 Ge0.5 N1 O1")
#this should change the .5Si .5Ge sites to .75Si .25Ge
s.replace_species({"Ge": {"Ge": 0.5, "Si": 0.5}})
self.assertEqual(s.formula, "Si0.75 Ge0.25 N1 O1")
# In this case, s.ntypesp is ambiguous.
# for the time being, we raise AttributeError.
with self.assertRaises(AttributeError):
s.ntypesp
s.remove_species(["Si"])
self.assertEqual(s.formula, "Ge0.25 N1 O1")
s.remove_sites([1, 2])
self.assertEqual(s.formula, "Ge0.25")
def test_add_site_property(self):
s = self.structure
s.add_site_property("charge", [4.1, -5])
self.assertEqual(s[0].charge, 4.1)
self.assertEqual(s[1].charge, -5)
s.add_site_property("magmom", [3, 2])
self.assertEqual(s[0].charge, 4.1)
self.assertEqual(s[0].magmom, 3)
def test_propertied_structure(self):
#Make sure that site properties are set to None for missing values.
s = self.structure
s.add_site_property("charge", [4.1, -5])
s.append("Li", [0.3, 0.3, 0.3])
self.assertEqual(len(s.site_properties["charge"]), 3)
def test_perturb(self):
d = 0.1
pre_perturbation_sites = self.structure.sites[:]
self.structure.perturb(distance=d)
post_perturbation_sites = self.structure.sites
for i, x in enumerate(pre_perturbation_sites):
self.assertAlmostEqual(x.distance(post_perturbation_sites[i]), d,
3, "Bad perturbation distance")
def test_add_oxidation_states(self):
oxidation_states = {"Si": -4}
self.structure.add_oxidation_state_by_element(oxidation_states)
for site in self.structure:
for k in site.species_and_occu.keys():
self.assertEqual(k.oxi_state, oxidation_states[k.symbol],
"Wrong oxidation state assigned!")
oxidation_states = {"Fe": 2}
self.assertRaises(ValueError,
self.structure.add_oxidation_state_by_element,
oxidation_states)
self.structure.add_oxidation_state_by_site([2, -4])
self.assertEqual(self.structure[0].specie.oxi_state, 2)
self.assertRaises(ValueError,
self.structure.add_oxidation_state_by_site, [1])
def test_remove_oxidation_states(self):
co_elem = Element("Co")
o_elem = Element("O")
co_specie = Specie("Co", 2)
o_specie = Specie("O", -2)
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice.cubic(10)
s_elem = Structure(lattice, [co_elem, o_elem], coords)
s_specie = Structure(lattice, [co_specie, o_specie], coords)
s_specie.remove_oxidation_states()
self.assertEqual(s_elem, s_specie, "Oxidation state remover " "failed")
def test_apply_operation(self):
op = SymmOp.from_axis_angle_and_translation([0, 0, 1], 90)
s = self.structure.copy()
s.apply_operation(op)
self.assertArrayAlmostEqual(
s.lattice.matrix,
[[0.000000, 3.840198, 0.000000], [-3.325710, 1.920099, 0.000000],
[2.217138, -0.000000, 3.135509]], 5)
op = SymmOp([[1, 1, 0, 0.5], [1, 0, 0, 0.5], [0, 0, 1, 0.5],
[0, 0, 0, 1]])
s = self.structure.copy()
s.apply_operation(op, fractional=True)
self.assertArrayAlmostEqual(
s.lattice.matrix,
[[5.760297, 3.325710, 0.000000], [3.840198, 0.000000, 0.000000],
[0.000000, -2.217138, 3.135509]], 5)
def test_apply_strain(self):
s = self.structure
initial_coord = s[1].coords
s.apply_strain(0.01)
self.assertAlmostEqual(
s.lattice.abc,
(3.8785999130369997, 3.878600984287687, 3.8785999130549516))
self.assertArrayAlmostEqual(s[1].coords, initial_coord * 1.01)
a1, b1, c1 = s.lattice.abc
s.apply_strain([0.1, 0.2, 0.3])
a2, b2, c2 = s.lattice.abc
self.assertAlmostEqual(a2 / a1, 1.1)
self.assertAlmostEqual(b2 / b1, 1.2)
self.assertAlmostEqual(c2 / c1, 1.3)
def test_scale_lattice(self):
initial_coord = self.structure[1].coords
self.structure.scale_lattice(self.structure.volume * 1.01**3)
self.assertArrayAlmostEqual(
self.structure.lattice.abc,
(3.8785999130369997, 3.878600984287687, 3.8785999130549516))
self.assertArrayAlmostEqual(self.structure[1].coords,
initial_coord * 1.01)
def test_translate_sites(self):
self.structure.translate_sites([0, 1], [0.5, 0.5, 0.5],
frac_coords=True)
self.assertArrayEqual(self.structure.frac_coords[0], [0.5, 0.5, 0.5])
self.structure.translate_sites([0], [0.5, 0.5, 0.5], frac_coords=False)
self.assertArrayAlmostEqual(self.structure.cart_coords[0],
[3.38014845, 1.05428585, 2.06775453])
self.structure.translate_sites([0], [0.5, 0.5, 0.5],
frac_coords=True,
to_unit_cell=False)
self.assertArrayAlmostEqual(self.structure.frac_coords[0],
[1.00187517, 1.25665291, 1.15946374])
def test_mul(self):
self.structure *= [2, 1, 1]
self.assertEqual(self.structure.formula, "Si4")
s = [2, 1, 1] * self.structure
self.assertEqual(s.formula, "Si8")
self.assertIsInstance(s, Structure)
s = self.structure * [[1, 0, 0], [2, 1, 0], [0, 0, 2]]
self.assertEqual(s.formula, "Si8")
self.assertArrayAlmostEqual(s.lattice.abc,
[7.6803959, 17.5979979, 7.6803959])
def test_make_supercell(self):
self.structure.make_supercell([2, 1, 1])
self.assertEqual(self.structure.formula, "Si4")
self.structure.make_supercell([[1, 0, 0], [2, 1, 0], [0, 0, 1]])
self.assertEqual(self.structure.formula, "Si4")
self.structure.make_supercell(2)
self.assertEqual(self.structure.formula, "Si32")
self.assertArrayAlmostEqual(self.structure.lattice.abc,
[15.360792, 35.195996, 7.680396], 5)
def test_disordered_supercell_primitive_cell(self):
l = Lattice.cubic(2)
f = [[0.5, 0.5, 0.5]]
sp = [{'Si': 0.54738}]
s = Structure(l, sp, f)
#this supercell often breaks things
s.make_supercell([[0, -1, 1], [-1, 1, 0], [1, 1, 1]])
self.assertEqual(len(s.get_primitive_structure()), 1)
def test_another_supercell(self):
#this is included b/c for some reason the old algo was failing on it
s = self.structure.copy()
s.make_supercell([[0, 2, 2], [2, 0, 2], [2, 2, 0]])
self.assertEqual(s.formula, "Si32")
s = self.structure.copy()
s.make_supercell([[0, 2, 0], [1, 0, 0], [0, 0, 1]])
self.assertEqual(s.formula, "Si4")
def test_to_from_dict(self):
d = self.structure.as_dict()
s2 = Structure.from_dict(d)
self.assertEqual(type(s2), Structure)
def test_to_from_abivars(self):
"""Test as_dict, from_dict with fmt == abivars."""
d = self.structure.as_dict(fmt="abivars")
s2 = Structure.from_dict(d, fmt="abivars")
self.assertEqual(s2, self.structure)
self.assertEqual(type(s2), Structure)
def test_to_from_file_string(self):
for fmt in ["cif", "json", "poscar", "cssr", "yaml", "xsf"]:
s = self.structure.to(fmt=fmt)
self.assertIsNotNone(s)
ss = Structure.from_str(s, fmt=fmt)
self.assertArrayAlmostEqual(
ss.lattice.lengths_and_angles,
self.structure.lattice.lengths_and_angles,
decimal=5)
self.assertArrayAlmostEqual(ss.frac_coords,
self.structure.frac_coords)
self.assertIsInstance(ss, Structure)
self.structure.to(filename="POSCAR.testing")
self.assertTrue(os.path.exists("POSCAR.testing"))
os.remove("POSCAR.testing")
self.structure.to(filename="structure_testing.json")
self.assertTrue(os.path.exists("structure_testing.json"))
s = Structure.from_file("structure_testing.json")
self.assertEqual(s, self.structure)
os.remove("structure_testing.json")
def test_from_spacegroup(self):
s1 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3), ["Li", "O"],
[[0.25, 0.25, 0.25], [0, 0, 0]])
self.assertEqual(s1.formula, "Li8 O4")
s2 = Structure.from_spacegroup(225, Lattice.cubic(3), ["Li", "O"],
[[0.25, 0.25, 0.25], [0, 0, 0]])
self.assertEqual(s1, s2)
s2 = Structure.from_spacegroup(225,
Lattice.cubic(3), ["Li", "O"],
[[0.25, 0.25, 0.25], [0, 0, 0]],
site_properties={"charge": [1, -2]})
self.assertEqual(sum(s2.site_properties["charge"]), 0)
s = Structure.from_spacegroup("Pm-3m", Lattice.cubic(3), ["Cs", "Cl"],
[[0, 0, 0], [0.5, 0.5, 0.5]])
self.assertEqual(s.formula, "Cs1 Cl1")
self.assertRaises(ValueError, Structure.from_spacegroup, "Pm-3m",
Lattice.tetragonal(1, 3), ["Cs", "Cl"],
[[0, 0, 0], [0.5, 0.5, 0.5]])
self.assertRaises(ValueError, Structure.from_spacegroup, "Pm-3m",
Lattice.cubic(3), ["Cs"],
[[0, 0, 0], [0.5, 0.5, 0.5]])
def test_from_magnetic_spacegroup(self):
# AFM MnF
s1 = Structure.from_magnetic_spacegroup(
"P4_2'/mnm'", Lattice.tetragonal(4.87, 3.30), ["Mn", "F"],
[[0, 0, 0], [0.30, 0.30, 0.00]], {'magmom': [4, 0]})
self.assertEqual(s1.formula, "Mn2 F4")
self.assertEqual(sum(map(float, s1.site_properties['magmom'])), 0)
self.assertEqual(max(map(float, s1.site_properties['magmom'])), 4)
self.assertEqual(min(map(float, s1.site_properties['magmom'])), -4)
# AFM LaMnO3, ordered on (001) planes
s2 = Structure.from_magnetic_spacegroup(
"Pn'ma'", Lattice.orthorhombic(5.75, 7.66,
5.53), ["La", "Mn", "O", "O"],
[[0.05, 0.25, 0.99], [0.00, 0.00, 0.50], [0.48, 0.25, 0.08],
[0.31, 0.04, 0.72]], {'magmom': [0, Magmom([4, 0, 0]), 0, 0]})
self.assertEqual(s2.formula, "La4 Mn4 O12")
self.assertEqual(sum(map(float, s2.site_properties['magmom'])), 0)
self.assertEqual(max(map(float, s2.site_properties['magmom'])), 4)
self.assertEqual(min(map(float, s2.site_properties['magmom'])), -4)
def test_merge_sites(self):
species = [{
'Ag': 0.5
}, {
'Cl': 0.25
}, {
'Cl': 0.1
}, {
'Ag': 0.5
}, {
'F': 0.15
}, {
'F': 0.1
}]
coords = [[0, 0, 0], [0.5, 0.5, 0.5], [0.5, 0.5, 0.5], [0, 0, 0],
[0.5, 0.5, 1.501], [0.5, 0.5, 1.501]]
s = Structure(Lattice.cubic(1), species, coords)
s.merge_sites(mode="s")
self.assertEqual(s[0].specie.symbol, 'Ag')
self.assertEqual(s[1].species_and_occu,
Composition({
'Cl': 0.35,
'F': 0.25
}))
self.assertArrayAlmostEqual(s[1].frac_coords, [.5, .5, .5005])
# Test for TaS2 with spacegroup 166 in 160 setting.
l = Lattice.from_lengths_and_angles([3.374351, 3.374351, 20.308941],
[90.000000, 90.000000, 120.000000])
species = ["Ta", "S", "S"]
coords = [[0.000000, 0.000000,
0.944333], [0.333333, 0.666667, 0.353424],
[0.666667, 0.333333, 0.535243]]
tas2 = Structure.from_spacegroup(160, l, species, coords)
assert len(tas2) == 13
tas2.merge_sites(mode="d")
assert len(tas2) == 9
l = Lattice.from_lengths_and_angles([3.587776, 3.587776, 19.622793],
[90.000000, 90.000000, 120.000000])
species = ["Na", "V", "S", "S"]
coords = [[0.333333, 0.666667,
0.165000], [0.000000, 0.000000, 0.998333],
[0.333333, 0.666667, 0.399394],
[0.666667, 0.333333, 0.597273]]
navs2 = Structure.from_spacegroup(160, l, species, coords)
assert len(navs2) == 18
navs2.merge_sites(mode="d")
assert len(navs2) == 12
def test_properties(self):
self.assertEqual(self.structure.num_sites, len(self.structure))
self.structure.make_supercell(2)
self.structure[1] = "C"
sites = list(self.structure.group_by_types())
self.assertEqual(sites[-1].specie.symbol, "C")
self.structure.add_oxidation_state_by_element({"Si": 4, "C": 2})
self.assertEqual(self.structure.charge, 62)
def test_set_item(self):
s = self.structure.copy()
s[0] = "C"
self.assertEqual(s.formula, "Si1 C1")
s[(0, 1)] = "Ge"
self.assertEqual(s.formula, "Ge2")
s[0:2] = "Sn"
self.assertEqual(s.formula, "Sn2")
s = self.structure.copy()
s["Si"] = "C"
self.assertEqual(s.formula, "C2")
s["C"] = "C0.25Si0.5"
self.assertEqual(s.formula, "Si1 C0.5")
s["C"] = "C0.25Si0.5"
self.assertEqual(s.formula, "Si1.25 C0.125")
def test_init_error(self):
self.assertRaises(StructureError, Structure, Lattice.cubic(3), ["Si"],
[[0, 0, 0], [0.5, 0.5, 0.5]])
def test_from_sites(self):
self.structure.add_site_property("hello", [1, 2])
s = Structure.from_sites(self.structure, to_unit_cell=True)
self.assertEqual(s.site_properties["hello"][1], 2)
def test_magic(self):
s = Structure.from_sites(self.structure)
self.assertEqual(s, self.structure)
self.assertNotEqual(s, None)
s.apply_strain(0.5)
self.assertNotEqual(s, self.structure)
self.assertNotEqual(self.structure * 2, self.structure)
class StructureTest(PymatgenTest):
def setUp(self):
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice([[3.8401979337, 0.00, 0.00],
[1.9200989668, 3.3257101909, 0.00],
[0.00, -2.2171384943, 3.1355090603]])
self.structure = Structure(lattice, ["Si", "Si"], coords)
def test_mutable_sequence_methods(self):
s = self.structure
s[0] = "Fe"
self.assertEqual(s.formula, "Fe1 Si1")
s[0] = "Fe", [0.5, 0.5, 0.5]
self.assertEqual(s.formula, "Fe1 Si1")
self.assertArrayAlmostEqual(s[0].frac_coords, [0.5, 0.5, 0.5])
s.reverse()
self.assertEqual(s[0].specie, Element("Si"))
self.assertArrayAlmostEqual(s[0].frac_coords, [0.75, 0.5, 0.75])
s[0] = {"Mn": 0.5}
self.assertEqual(s.formula, "Mn0.5 Fe1")
del s[1]
self.assertEqual(s.formula, "Mn0.5")
s[0] = "Fe", [0.9, 0.9, 0.9], {"magmom": 5}
self.assertEqual(s.formula, "Fe1")
self.assertEqual(s[0].magmom, 5)
def test_non_hash(self):
self.assertRaises(TypeError, dict, [(self.structure, 1)])
def test_sort(self):
s = self.structure
s[0] = "F"
s.sort()
self.assertEqual(s[0].species_string, "Si")
self.assertEqual(s[1].species_string, "F")
s.sort(key=lambda site: site.species_string)
self.assertEqual(s[0].species_string, "F")
self.assertEqual(s[1].species_string, "Si")
s.sort(key=lambda site: site.species_string, reverse=True)
self.assertEqual(s[0].species_string, "Si")
self.assertEqual(s[1].species_string, "F")
def test_append_insert_remove_replace(self):
s = self.structure
s.insert(1, "O", [0.5, 0.5, 0.5])
self.assertEqual(s.formula, "Si2 O1")
self.assertTrue(s.ntypesp == 2)
self.assertTrue(s.symbol_set == ("Si", "O"))
self.assertTrue(s.indices_from_symbol("Si") == (0, 2))
self.assertTrue(s.indices_from_symbol("O") == (1, ))
del s[2]
self.assertEqual(s.formula, "Si1 O1")
self.assertTrue(s.indices_from_symbol("Si") == (0, ))
self.assertTrue(s.indices_from_symbol("O") == (1, ))
s.append("N", [0.25, 0.25, 0.25])
self.assertEqual(s.formula, "Si1 N1 O1")
self.assertTrue(s.ntypesp == 3)
self.assertTrue(s.symbol_set == ("Si", "O", "N"))
self.assertTrue(s.indices_from_symbol("Si") == (0, ))
self.assertTrue(s.indices_from_symbol("O") == (1, ))
self.assertTrue(s.indices_from_symbol("N") == (2, ))
s[0] = "Ge"
self.assertEqual(s.formula, "Ge1 N1 O1")
self.assertTrue(s.symbol_set == ("Ge", "O", "N"))
s.replace_species({"Ge": "Si"})
self.assertEqual(s.formula, "Si1 N1 O1")
self.assertTrue(s.ntypesp == 3)
s.replace_species({"Si": {"Ge": 0.5, "Si": 0.5}})
self.assertEqual(s.formula, "Si0.5 Ge0.5 N1 O1")
#this should change the .5Si .5Ge sites to .75Si .25Ge
s.replace_species({"Ge": {"Ge": 0.5, "Si": 0.5}})
self.assertEqual(s.formula, "Si0.75 Ge0.25 N1 O1")
# In this case, s.ntypesp is ambiguous.
# for the time being, we raise AttributeError.
with self.assertRaises(AttributeError):
s.ntypesp
s.remove_species(["Si"])
self.assertEqual(s.formula, "Ge0.25 N1 O1")
s.remove_sites([1, 2])
self.assertEqual(s.formula, "Ge0.25")
def test_add_site_property(self):
s = self.structure
s.add_site_property("charge", [4.1, -5])
self.assertEqual(s[0].charge, 4.1)
self.assertEqual(s[1].charge, -5)
s.add_site_property("magmom", [3, 2])
self.assertEqual(s[0].charge, 4.1)
self.assertEqual(s[0].magmom, 3)
def test_propertied_structure(self):
#Make sure that site properties are set to None for missing values.
s = self.structure
s.add_site_property("charge", [4.1, -5])
s.append("Li", [0.3, 0.3, 0.3])
self.assertEqual(len(s.site_properties["charge"]), 3)
def test_perturb(self):
d = 0.1
pre_perturbation_sites = self.structure.sites[:]
self.structure.perturb(distance=d)
post_perturbation_sites = self.structure.sites
for i, x in enumerate(pre_perturbation_sites):
self.assertAlmostEqual(x.distance(post_perturbation_sites[i]), d,
3, "Bad perturbation distance")
def test_add_oxidation_states(self):
oxidation_states = {"Si": -4}
self.structure.add_oxidation_state_by_element(oxidation_states)
for site in self.structure:
for k in site.species_and_occu.keys():
self.assertEqual(k.oxi_state, oxidation_states[k.symbol],
"Wrong oxidation state assigned!")
oxidation_states = {"Fe": 2}
self.assertRaises(ValueError,
self.structure.add_oxidation_state_by_element,
oxidation_states)
self.structure.add_oxidation_state_by_site([2, -4])
self.assertEqual(self.structure[0].specie.oxi_state, 2)
self.assertRaises(ValueError,
self.structure.add_oxidation_state_by_site, [1])
def test_remove_oxidation_states(self):
co_elem = Element("Co")
o_elem = Element("O")
co_specie = Specie("Co", 2)
o_specie = Specie("O", -2)
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice.cubic(10)
s_elem = Structure(lattice, [co_elem, o_elem], coords)
s_specie = Structure(lattice, [co_specie, o_specie], coords)
s_specie.remove_oxidation_states()
self.assertEqual(s_elem, s_specie, "Oxidation state remover " "failed")
def test_apply_operation(self):
op = SymmOp.from_axis_angle_and_translation([0, 0, 1], 90)
s = self.structure.copy()
s.apply_operation(op)
self.assertArrayAlmostEqual(
s.lattice.matrix,
[[0.000000, 3.840198, 0.000000], [-3.325710, 1.920099, 0.000000],
[2.217138, -0.000000, 3.135509]], 5)
op = SymmOp([[1, 1, 0, 0.5], [1, 0, 0, 0.5], [0, 0, 1, 0.5],
[0, 0, 0, 1]])
s = self.structure.copy()
s.apply_operation(op, fractional=True)
self.assertArrayAlmostEqual(
s.lattice.matrix,
[[5.760297, 3.325710, 0.000000], [3.840198, 0.000000, 0.000000],
[0.000000, -2.217138, 3.135509]], 5)
def test_apply_strain(self):
s = self.structure
initial_coord = s[1].coords
s.apply_strain(0.01)
self.assertAlmostEqual(
s.lattice.abc,
(3.8785999130369997, 3.878600984287687, 3.8785999130549516))
self.assertArrayAlmostEqual(s[1].coords, initial_coord * 1.01)
a1, b1, c1 = s.lattice.abc
s.apply_strain([0.1, 0.2, 0.3])
a2, b2, c2 = s.lattice.abc
self.assertAlmostEqual(a2 / a1, 1.1)
self.assertAlmostEqual(b2 / b1, 1.2)
self.assertAlmostEqual(c2 / c1, 1.3)
def test_scale_lattice(self):
initial_coord = self.structure[1].coords
self.structure.scale_lattice(self.structure.volume * 1.01**3)
self.assertArrayAlmostEqual(
self.structure.lattice.abc,
(3.8785999130369997, 3.878600984287687, 3.8785999130549516))
self.assertArrayAlmostEqual(self.structure[1].coords,
initial_coord * 1.01)
def test_translate_sites(self):
self.structure.translate_sites([0, 1], [0.5, 0.5, 0.5],
frac_coords=True)
self.assertArrayEqual(self.structure.frac_coords[0], [0.5, 0.5, 0.5])
self.structure.translate_sites([0], [0.5, 0.5, 0.5], frac_coords=False)
self.assertArrayAlmostEqual(self.structure.cart_coords[0],
[3.38014845, 1.05428585, 2.06775453])
self.structure.translate_sites([0], [0.5, 0.5, 0.5],
frac_coords=True,
to_unit_cell=False)
self.assertArrayAlmostEqual(self.structure.frac_coords[0],
[1.00187517, 1.25665291, 1.15946374])
def test_mul(self):
self.structure *= [2, 1, 1]
self.assertEqual(self.structure.formula, "Si4")
s = [2, 1, 1] * self.structure
self.assertEqual(s.formula, "Si8")
self.assertIsInstance(s, Structure)
s = self.structure * [[1, 0, 0], [2, 1, 0], [0, 0, 2]]
self.assertEqual(s.formula, "Si8")
self.assertArrayAlmostEqual(s.lattice.abc,
[7.6803959, 17.5979979, 7.6803959])
def test_make_supercell(self):
self.structure.make_supercell([2, 1, 1])
self.assertEqual(self.structure.formula, "Si4")
self.structure.make_supercell([[1, 0, 0], [2, 1, 0], [0, 0, 1]])
self.assertEqual(self.structure.formula, "Si4")
self.structure.make_supercell(2)
self.assertEqual(self.structure.formula, "Si32")
self.assertArrayAlmostEqual(self.structure.lattice.abc,
[15.360792, 35.195996, 7.680396], 5)
def test_disordered_supercell_primitive_cell(self):
l = Lattice.cubic(2)
f = [[0.5, 0.5, 0.5]]
sp = [{'Si': 0.54738}]
s = Structure(l, sp, f)
#this supercell often breaks things
s.make_supercell([[0, -1, 1], [-1, 1, 0], [1, 1, 1]])
self.assertEqual(len(s.get_primitive_structure()), 1)
def test_another_supercell(self):
#this is included b/c for some reason the old algo was failing on it
s = self.structure.copy()
s.make_supercell([[0, 2, 2], [2, 0, 2], [2, 2, 0]])
self.assertEqual(s.formula, "Si32")
s = self.structure.copy()
s.make_supercell([[0, 2, 0], [1, 0, 0], [0, 0, 1]])
self.assertEqual(s.formula, "Si4")
def test_to_from_dict(self):
d = self.structure.as_dict()
s2 = Structure.from_dict(d)
self.assertEqual(type(s2), Structure)
def test_to_from_file_string(self):
for fmt in ["cif", "json", "poscar", "cssr", "yaml", "xsf"]:
s = self.structure.to(fmt=fmt)
self.assertIsNotNone(s)
ss = Structure.from_str(s, fmt=fmt)
self.assertArrayAlmostEqual(
ss.lattice.lengths_and_angles,
self.structure.lattice.lengths_and_angles,
decimal=5)
self.assertArrayAlmostEqual(ss.frac_coords,
self.structure.frac_coords)
self.assertIsInstance(ss, Structure)
self.structure.to(filename="POSCAR.testing")
self.assertTrue(os.path.exists("POSCAR.testing"))
os.remove("POSCAR.testing")
self.structure.to(filename="structure_testing.json")
self.assertTrue(os.path.exists("structure_testing.json"))
s = Structure.from_file("structure_testing.json")
self.assertEqual(s, self.structure)
os.remove("structure_testing.json")
def test_from_spacegroup(self):
s1 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3), ["Li", "O"],
[[0.25, 0.25, 0.25], [0, 0, 0]])
self.assertEqual(s1.formula, "Li8 O4")
s2 = Structure.from_spacegroup(225, Lattice.cubic(3), ["Li", "O"],
[[0.25, 0.25, 0.25], [0, 0, 0]])
self.assertEqual(s1, s2)
s2 = Structure.from_spacegroup(225,
Lattice.cubic(3), ["Li", "O"],
[[0.25, 0.25, 0.25], [0, 0, 0]],
site_properties={"charge": [1, -2]})
self.assertEqual(sum(s2.site_properties["charge"]), 0)
s = Structure.from_spacegroup("Pm-3m", Lattice.cubic(3), ["Cs", "Cl"],
[[0, 0, 0], [0.5, 0.5, 0.5]])
self.assertEqual(s.formula, "Cs1 Cl1")
self.assertRaises(ValueError, Structure.from_spacegroup, "Pm-3m",
Lattice.tetragonal(1, 3), ["Cs", "Cl"],
[[0, 0, 0], [0.5, 0.5, 0.5]])
def test_merge_sites(self):
species = [{
'Ag': 0.5
}, {
'Cl': 0.25
}, {
'Cl': 0.1
}, {
'Ag': 0.5
}, {
'F': 0.15
}, {
'F': 0.1
}]
coords = [[0, 0, 0], [0.5, 0.5, 0.5], [0.5, 0.5, 0.5], [0, 0, 0],
[0.5, 0.5, 1.501], [0.5, 0.5, 1.501]]
s = Structure(Lattice.cubic(1), species, coords)
s.merge_sites()
self.assertEqual(s[0].specie.symbol, 'Ag')
self.assertEqual(s[1].species_and_occu,
Composition({
'Cl': 0.35,
'F': 0.25
}))
self.assertArrayAlmostEqual(s[1].frac_coords, [.5, .5, .5005])
gg +=1
if i == len(term_slab) - 1:
term_index.append(i)
else:
if tracker_index[i] != tracker_index[i+1]:
term_index.append(i)
if gg == len(structure):
break
slab_list, term_coords = [], []
a, i = 0, 0
new_slab = Structure(term_slab.lattice, el, org_coords)
for iii in range(0, len(term_index)):
y = []
alt_slab = new_slab.copy()
for ii in range(0, len(alt_slab)):
index = []
term_scale = 0
index.append(ii)
if alt_slab.frac_coords[ii][2] > alt_slab.frac_coords[term_index[iii]][2]:
term_scale = min_vacuum_size
alt_slab.translate_sites(index, [0, 0, term_scale/(new_slab.lattice.c)])
if standardize:
index = []
for f in range(0, len(alt_slab)):
index.append(f)
def __init__(
self,
structure: Structure,
overwrite_magmom_mode: Union[OverwriteMagmomMode, str] = "none",
round_magmoms: bool = False,
detect_valences: bool = False,
make_primitive: bool = True,
default_magmoms: bool = None,
set_net_positive: bool = True,
threshold: float = 0.1,
):
"""
A class which provides a few helpful methods to analyze
collinear magnetic structures.
If magnetic moments are not defined, moments will be
taken either from default_magmoms.yaml (similar to the
default magmoms in MPRelaxSet, with a few extra definitions)
or from a specie:magmom dict provided by the default_magmoms
kwarg.
Input magmoms can be replaced using the 'overwrite_magmom_mode'
kwarg. This can be:
* "none" to do nothing,
* "respect_sign" which will overwrite existing magmoms with
those from default_magmoms but will keep sites with positive magmoms
positive, negative magmoms negative and zero magmoms zero,
* "respect_zeros", which will give a ferromagnetic structure
(all positive magmoms from default_magmoms) but still keep sites with
zero magmoms as zero,
* "replace_all" which will try to guess initial magmoms for
all sites in the structure irrespective of input structure
(this is most suitable for an initial DFT calculation),
* "replace_all_if_undefined" is the same as "replace_all" but only if
no magmoms are defined in input structure, otherwise it will respect
existing magmoms.
* "normalize" will normalize magmoms to unity, but will respect sign
(used for comparing orderings), magmoms < theshold will be set to zero
:param structure: Structure object
:param overwrite_magmom_mode (str): default "none"
:param round_magmoms (int or bool): will round input magmoms to
specified number of decimal places if integer is supplied, if set
to a float will try and group magmoms together using a kernel density
estimator of provided width, and extracting peaks of the estimator
:param detect_valences (bool): if True, will attempt to assign valences
to input structure
:param make_primitive (bool): if True, will transform to primitive
magnetic cell
:param default_magmoms (dict): (optional) dict specifying default magmoms
:param set_net_positive (bool): if True, will change sign of magnetic
moments such that the net magnetization is positive. Argument will be
ignored if mode "respect_sign" is used.
:param threshold (float): number (in Bohr magnetons) below which magmoms
will be rounded to zero, default of 0.1 can probably be increased for many
magnetic systems, depending on your application
"""
if default_magmoms:
self.default_magmoms = default_magmoms
else:
self.default_magmoms = DEFAULT_MAGMOMS
structure = structure.copy()
# check for disorder
if not structure.is_ordered:
raise NotImplementedError(
"Not implemented for disordered structures, "
"make ordered approximation first."
)
if detect_valences:
trans = AutoOxiStateDecorationTransformation()
bva = BVAnalyzer()
try:
structure = trans.apply_transformation(structure)
except ValueError:
warnings.warn(
"Could not assign valences "
"for {}".format(structure.composition.reduced_formula)
)
# check to see if structure has magnetic moments
# on site properties or species spin properties,
# prioritize site properties
has_magmoms = bool(structure.site_properties.get("magmom", False))
has_spin = False
for comp in structure.species_and_occu:
for sp, occu in comp.items():
if getattr(sp, "spin", False):
has_spin = True
# perform input sanitation ...
# rest of class will assume magnetic moments
# are stored on site properties:
# this is somewhat arbitrary, arguments can
# be made for both approaches
if has_magmoms and has_spin:
raise ValueError(
"Structure contains magnetic moments on both "
"magmom site properties and spin species "
"properties. This is ambiguous. Remove one or "
"the other."
)
elif has_magmoms:
if None in structure.site_properties["magmom"]:
warnings.warn(
"Be careful with mixing types in your magmom "
"site properties. Any 'None' magmoms have been "
"replaced with zero."
)
magmoms = [m if m else 0 for m in structure.site_properties["magmom"]]
elif has_spin:
magmoms = [getattr(sp, "spin", 0) for sp in structure.species]
structure.remove_spin()
else:
# no magmoms present, add zero magmoms for now
magmoms = [0] * len(structure)
# and overwrite magmoms with default magmoms later unless otherwise stated
if overwrite_magmom_mode == "replace_all_if_undefined":
overwrite_magmom_mode = "replace_all"
# test to see if input structure has collinear magmoms
self.is_collinear = Magmom.are_collinear(magmoms)
if not self.is_collinear:
warnings.warn(
"This class is not designed to be used with "
"non-collinear structures. If your structure is "
"only slightly non-collinear (e.g. canted) may still "
"give useful results, but use with caution."
)
# this is for collinear structures only, make sure magmoms
# are all floats
magmoms = list(map(float, magmoms))
# set properties that should be done /before/ we process input magmoms
self.total_magmoms = sum(magmoms)
self.magnetization = sum(magmoms) / structure.volume
# round magmoms below threshold to zero
magmoms = [m if abs(m) > threshold else 0 for m in magmoms]
# overwrite existing magmoms with default_magmoms
if overwrite_magmom_mode not in (
"none",
"respect_sign",
"respect_zeros",
"replace_all",
"replace_all_if_undefined",
"normalize",
):
raise ValueError("Unsupported mode.")
for idx, site in enumerate(structure):
if site.species_string in self.default_magmoms:
# look for species first, e.g. Fe2+
default_magmom = self.default_magmoms[site.species_string]
elif (
isinstance(site.specie, Specie)
and str(site.specie.element) in self.default_magmoms
):
# look for element, e.g. Fe
default_magmom = self.default_magmoms[str(site.specie.element)]
else:
default_magmom = 0
# overwrite_magmom_mode = "respect_sign" will change magnitude of
# existing moments only, and keep zero magmoms as
# zero: it will keep the magnetic ordering intact
if overwrite_magmom_mode == "respect_sign":
set_net_positive = False
if magmoms[idx] > 0:
magmoms[idx] = default_magmom
elif magmoms[idx] < 0:
magmoms[idx] = -default_magmom
# overwrite_magmom_mode = "respect_zeros" will give a ferromagnetic
# structure but will keep zero magmoms as zero
elif overwrite_magmom_mode == "respect_zeros":
if magmoms[idx] != 0:
magmoms[idx] = default_magmom
# overwrite_magmom_mode = "replace_all" will ignore input magmoms
# and give a ferromagnetic structure with magnetic
# moments on *all* atoms it thinks could be magnetic
elif overwrite_magmom_mode == "replace_all":
magmoms[idx] = default_magmom
# overwrite_magmom_mode = "normalize" set magmoms magnitude to 1
elif overwrite_magmom_mode == "normalize":
if magmoms[idx] != 0:
magmoms[idx] = int(magmoms[idx] / abs(magmoms[idx]))
# round magmoms, used to smooth out computational data
magmoms = (
self._round_magmoms(magmoms, round_magmoms) if round_magmoms else magmoms
)
if set_net_positive:
sign = np.sum(magmoms)
if sign < 0:
magmoms = -np.array(magmoms)
structure.add_site_property("magmom", magmoms)
if make_primitive:
structure = structure.get_primitive_structure(use_site_props=True)
self.structure = structure
class StructureTest(PymatgenTest):
def setUp(self):
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice([[3.8401979337, 0.00, 0.00],
[1.9200989668, 3.3257101909, 0.00],
[0.00, -2.2171384943, 3.1355090603]])
self.structure = Structure(lattice, ["Si", "Si"], coords)
def test_non_hash(self):
self.assertRaises(TypeError, dict, [(self.structure, 1)])
def test_append_insert_remove_replace(self):
s = self.structure
s.insert(1, "O", [0.5, 0.5, 0.5])
self.assertEqual(s.formula, "Si2 O1")
self.assertTrue(s.ntypesp == 2)
self.assertTrue(s.symbol_set == ("Si", "O"))
self.assertTrue(s.indices_from_symbol("Si") == (0,2))
self.assertTrue(s.indices_from_symbol("O") == (1,))
s.remove(2)
self.assertEqual(s.formula, "Si1 O1")
self.assertTrue(s.indices_from_symbol("Si") == (0,))
self.assertTrue(s.indices_from_symbol("O") == (1,))
s.append("N", [0.25, 0.25, 0.25])
self.assertEqual(s.formula, "Si1 N1 O1")
self.assertTrue(s.ntypesp == 3)
self.assertTrue(s.symbol_set == ("Si", "O", "N"))
self.assertTrue(s.indices_from_symbol("Si") == (0,))
self.assertTrue(s.indices_from_symbol("O") == (1,))
self.assertTrue(s.indices_from_symbol("N") == (2,))
s.replace(0, "Ge")
self.assertEqual(s.formula, "Ge1 N1 O1")
self.assertTrue(s.symbol_set == ("Ge", "O", "N"))
s.replace_species({"Ge": "Si"})
self.assertEqual(s.formula, "Si1 N1 O1")
self.assertTrue(s.ntypesp == 3)
s.replace_species({"Si": {"Ge": 0.5, "Si": 0.5}})
self.assertEqual(s.formula, "Si0.5 Ge0.5 N1 O1")
#this should change the .5Si .5Ge sites to .75Si .25Ge
s.replace_species({"Ge": {"Ge": 0.5, "Si": 0.5}})
self.assertEqual(s.formula, "Si0.75 Ge0.25 N1 O1")
# In this case, s.ntypesp is ambiguous.
# for the time being, we raise AttributeError.
with self.assertRaises(AttributeError):
s.ntypesp
s.remove_species(["Si"])
self.assertEqual(s.formula, "Ge0.25 N1 O1")
s.remove_sites([1, 2])
self.assertEqual(s.formula, "Ge0.25")
def test_add_site_property(self):
s = self.structure
s.add_site_property("charge", [4.1, -5])
self.assertEqual(s[0].charge, 4.1)
self.assertEqual(s[1].charge, -5)
s.add_site_property("magmom", [3, 2])
self.assertEqual(s[0].charge, 4.1)
self.assertEqual(s[0].magmom, 3)
def test_perturb(self):
d = 0.1
pre_perturbation_sites = self.structure.sites[:]
self.structure.perturb(distance=d)
post_perturbation_sites = self.structure.sites
for i, x in enumerate(pre_perturbation_sites):
self.assertAlmostEqual(x.distance(post_perturbation_sites[i]), d,
3, "Bad perturbation distance")
def test_add_oxidation_states(self):
oxidation_states = {"Si": -4}
self.structure.add_oxidation_state_by_element(oxidation_states)
for site in self.structure:
for k in site.species_and_occu.keys():
self.assertEqual(k.oxi_state, oxidation_states[k.symbol],
"Wrong oxidation state assigned!")
oxidation_states = {"Fe": 2}
self.assertRaises(ValueError,
self.structure.add_oxidation_state_by_element,
oxidation_states)
self.structure.add_oxidation_state_by_site([2, -4])
self.assertEqual(self.structure[0].specie.oxi_state, 2)
self.assertRaises(ValueError,
self.structure.add_oxidation_state_by_site,
[1])
def test_remove_oxidation_states(self):
co_elem = Element("Co")
o_elem = Element("O")
co_specie = Specie("Co", 2)
o_specie = Specie("O", -2)
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice.cubic(10)
s_elem = Structure(lattice, [co_elem, o_elem], coords)
s_specie = Structure(lattice, [co_specie, o_specie], coords)
s_specie.remove_oxidation_states()
self.assertEqual(s_elem, s_specie, "Oxidation state remover "
"failed")
def test_apply_operation(self):
op = SymmOp.from_axis_angle_and_translation([0, 0, 1], 90)
self.structure.apply_operation(op)
self.assertArrayAlmostEqual(
self.structure.lattice.matrix,
[[0.000000, 3.840198, 0.000000],
[-3.325710, 1.920099, 0.000000],
[2.217138, -0.000000, 3.135509]], 5)
def test_apply_strain(self):
initial_coord = self.structure[1].coords
self.structure.apply_strain(0.01)
self.assertAlmostEqual(
self.structure.lattice.abc,
(3.8785999130369997, 3.878600984287687, 3.8785999130549516))
self.assertArrayAlmostEqual(self.structure[1].coords,
initial_coord * 1.01)
def test_scale_lattice(self):
initial_coord = self.structure[1].coords
self.structure.scale_lattice(self.structure.volume * 1.01 ** 3)
self.assertArrayAlmostEqual(
self.structure.lattice.abc,
(3.8785999130369997, 3.878600984287687, 3.8785999130549516))
self.assertArrayAlmostEqual(self.structure[1].coords,
initial_coord * 1.01)
def test_translate_sites(self):
self.structure.translate_sites([0, 1], [0.5, 0.5, 0.5],
frac_coords=True)
self.assertArrayEqual(self.structure.frac_coords[0],
[0.5, 0.5, 0.5])
self.structure.translate_sites([0], [0.5, 0.5, 0.5],
frac_coords=False)
self.assertArrayAlmostEqual(self.structure.cart_coords[0],
[3.38014845, 1.05428585, 2.06775453])
self.structure.translate_sites([0], [0.5, 0.5, 0.5],
frac_coords=True, to_unit_cell=False)
self.assertArrayAlmostEqual(self.structure.frac_coords[0],
[1.00187517, 1.25665291, 1.15946374])
def test_make_supercell(self):
self.structure.make_supercell([2, 1, 1])
self.assertEqual(self.structure.formula, "Si4")
self.structure.make_supercell([[1, 0, 0], [2, 1, 0], [0, 0, 1]])
self.assertEqual(self.structure.formula, "Si4")
self.structure.make_supercell(2)
self.assertEqual(self.structure.formula, "Si32")
self.assertArrayAlmostEqual(self.structure.lattice.abc,
[15.360792, 35.195996, 7.680396], 5)
def test_disordered_supercell_primitive_cell(self):
l = Lattice.cubic(2)
f = [[0.5, 0.5, 0.5]]
sp = [{'Si': 0.54738}]
s = Structure(l, sp, f)
#this supercell often breaks things
s.make_supercell([[0,-1,1],[-1,1,0],[1,1,1]])
self.assertEqual(len(s.get_primitive_structure()), 1)
def test_another_supercell(self):
#this is included b/c for some reason the old algo was failing on it
s = self.structure.copy()
s.make_supercell([[0, 2, 2], [2, 0, 2], [2, 2, 0]])
self.assertEqual(s.formula, "Si32")
s = self.structure.copy()
s.make_supercell([[0, 2, 0], [1, 0, 0], [0, 0, 1]])
self.assertEqual(s.formula, "Si4")
def test_to_from_dict(self):
d = self.structure.to_dict
s2 = Structure.from_dict(d)
self.assertEqual(type(s2), Structure)
def apply_transformation(self, structure, return_ranked_list=False):
"""
Return either a single ordered structure or a sequence of all ordered
structures.
Args:
structure: Structure to order.
return_ranked_list (bool): Whether or not multiple structures are
returned. If return_ranked_list is a number, that number of
structures is returned.
Returns:
Depending on returned_ranked list, either a transformed structure
or a list of dictionaries, where each dictionary is of the form
{"structure" = .... , "other_arguments"}
The list of ordered structures is ranked by ewald energy / atom, if
the input structure is an oxidation state decorated structure.
Otherwise, it is ranked by number of sites, with smallest number of
sites first.
"""
try:
num_to_return = int(return_ranked_list)
except ValueError:
num_to_return = 1
if self.occu_tol:
species = [dict(d) for d in structure.species_and_occu]
# Here, we rescale all occupancies such that they meet the frac
# limit.
for sp in species:
for k, v in sp.items():
sp[k] = float(Fraction(v).limit_denominator(self.occu_tol))
structure = Structure(structure.lattice, species,
structure.frac_coords)
if self.refine_structure:
finder = SpacegroupAnalyzer(structure, self.symm_prec)
structure = finder.get_refined_structure()
contains_oxidation_state = all([
hasattr(sp, "oxi_state") and sp.oxi_state != 0
for sp in structure.composition.elements
])
if structure.is_ordered:
warn("Enumeration skipped for structure with composition {} "
"because it is ordered".format(structure.composition))
structures = [structure.copy()]
else:
adaptor = EnumlibAdaptor(
structure,
min_cell_size=self.min_cell_size,
max_cell_size=self.max_cell_size,
symm_prec=self.symm_prec,
refine_structure=False,
enum_precision_parameter=self.enum_precision_parameter,
check_ordered_symmetry=self.check_ordered_symmetry)
adaptor.run()
structures = adaptor.structures
original_latt = structure.lattice
inv_latt = np.linalg.inv(original_latt.matrix)
ewald_matrices = {}
all_structures = []
for s in structures:
new_latt = s.lattice
transformation = np.dot(new_latt.matrix, inv_latt)
transformation = tuple([
tuple([int(round(cell)) for cell in row])
for row in transformation
])
if contains_oxidation_state:
if transformation not in ewald_matrices:
s_supercell = structure * transformation
ewald = EwaldSummation(s_supercell)
ewald_matrices[transformation] = ewald
else:
ewald = ewald_matrices[transformation]
energy = ewald.compute_sub_structure(s)
all_structures.append({
"num_sites": len(s),
"energy": energy,
"structure": s
})
else:
all_structures.append({"num_sites": len(s), "structure": s})
def sort_func(s):
return s["energy"] / s["num_sites"] if contains_oxidation_state \
else s["num_sites"]
self._all_structures = sorted(all_structures, key=sort_func)
if return_ranked_list:
return self._all_structures[0:num_to_return]
else:
return self._all_structures[0]["structure"]
class StructureTest(PymatgenTest):
def setUp(self):
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice([[3.8401979337, 0.00, 0.00],
[1.9200989668, 3.3257101909, 0.00],
[0.00, -2.2171384943, 3.1355090603]])
self.structure = Structure(lattice, ["Si", "Si"], coords)
def test_mutable_sequence_methods(self):
s = self.structure
s[0] = "Fe"
self.assertEqual(s.formula, "Fe1 Si1")
s[0] = "Fe", [0.5, 0.5, 0.5]
self.assertEqual(s.formula, "Fe1 Si1")
self.assertArrayAlmostEqual(s[0].frac_coords, [0.5, 0.5, 0.5])
s.reverse()
self.assertEqual(s[0].specie, Element("Si"))
self.assertArrayAlmostEqual(s[0].frac_coords, [0.75, 0.5, 0.75])
s[0] = {"Mn": 0.5}
self.assertEqual(s.formula, "Mn0.5 Fe1")
del s[1]
self.assertEqual(s.formula, "Mn0.5")
s[0] = "Fe", [0.9, 0.9, 0.9], {"magmom": 5}
self.assertEqual(s.formula, "Fe1")
self.assertEqual(s[0].magmom, 5)
def test_non_hash(self):
self.assertRaises(TypeError, dict, [(self.structure, 1)])
def test_sort(self):
s = self.structure
s[0] = "F"
s.sort()
self.assertEqual(s[0].species_string, "Si")
self.assertEqual(s[1].species_string, "F")
s.sort(key=lambda site: site.species_string)
self.assertEqual(s[0].species_string, "F")
self.assertEqual(s[1].species_string, "Si")
s.sort(key=lambda site: site.species_string, reverse=True)
self.assertEqual(s[0].species_string, "Si")
self.assertEqual(s[1].species_string, "F")
def test_append_insert_remove_replace(self):
s = self.structure
s.insert(1, "O", [0.5, 0.5, 0.5])
self.assertEqual(s.formula, "Si2 O1")
self.assertTrue(s.ntypesp == 2)
self.assertTrue(s.symbol_set == ("Si", "O"))
self.assertTrue(s.indices_from_symbol("Si") == (0,2))
self.assertTrue(s.indices_from_symbol("O") == (1,))
del s[2]
self.assertEqual(s.formula, "Si1 O1")
self.assertTrue(s.indices_from_symbol("Si") == (0,))
self.assertTrue(s.indices_from_symbol("O") == (1,))
s.append("N", [0.25, 0.25, 0.25])
self.assertEqual(s.formula, "Si1 N1 O1")
self.assertTrue(s.ntypesp == 3)
self.assertTrue(s.symbol_set == ("Si", "O", "N"))
self.assertTrue(s.indices_from_symbol("Si") == (0,))
self.assertTrue(s.indices_from_symbol("O") == (1,))
self.assertTrue(s.indices_from_symbol("N") == (2,))
s[0] = "Ge"
self.assertEqual(s.formula, "Ge1 N1 O1")
self.assertTrue(s.symbol_set == ("Ge", "O", "N"))
s.replace_species({"Ge": "Si"})
self.assertEqual(s.formula, "Si1 N1 O1")
self.assertTrue(s.ntypesp == 3)
s.replace_species({"Si": {"Ge": 0.5, "Si": 0.5}})
self.assertEqual(s.formula, "Si0.5 Ge0.5 N1 O1")
#this should change the .5Si .5Ge sites to .75Si .25Ge
s.replace_species({"Ge": {"Ge": 0.5, "Si": 0.5}})
self.assertEqual(s.formula, "Si0.75 Ge0.25 N1 O1")
# In this case, s.ntypesp is ambiguous.
# for the time being, we raise AttributeError.
with self.assertRaises(AttributeError):
s.ntypesp
s.remove_species(["Si"])
self.assertEqual(s.formula, "Ge0.25 N1 O1")
s.remove_sites([1, 2])
self.assertEqual(s.formula, "Ge0.25")
def test_add_site_property(self):
s = self.structure
s.add_site_property("charge", [4.1, -5])
self.assertEqual(s[0].charge, 4.1)
self.assertEqual(s[1].charge, -5)
s.add_site_property("magmom", [3, 2])
self.assertEqual(s[0].charge, 4.1)
self.assertEqual(s[0].magmom, 3)
def test_propertied_structure(self):
#Make sure that site properties are set to None for missing values.
s = self.structure
s.add_site_property("charge", [4.1, -5])
s.append("Li", [0.3, 0.3 ,0.3])
self.assertEqual(len(s.site_properties["charge"]), 3)
def test_perturb(self):
d = 0.1
pre_perturbation_sites = self.structure.sites[:]
self.structure.perturb(distance=d)
post_perturbation_sites = self.structure.sites
for i, x in enumerate(pre_perturbation_sites):
self.assertAlmostEqual(x.distance(post_perturbation_sites[i]), d,
3, "Bad perturbation distance")
def test_add_oxidation_states(self):
oxidation_states = {"Si": -4}
self.structure.add_oxidation_state_by_element(oxidation_states)
for site in self.structure:
for k in site.species_and_occu.keys():
self.assertEqual(k.oxi_state, oxidation_states[k.symbol],
"Wrong oxidation state assigned!")
oxidation_states = {"Fe": 2}
self.assertRaises(ValueError,
self.structure.add_oxidation_state_by_element,
oxidation_states)
self.structure.add_oxidation_state_by_site([2, -4])
self.assertEqual(self.structure[0].specie.oxi_state, 2)
self.assertRaises(ValueError,
self.structure.add_oxidation_state_by_site,
[1])
def test_remove_oxidation_states(self):
co_elem = Element("Co")
o_elem = Element("O")
co_specie = Specie("Co", 2)
o_specie = Specie("O", -2)
coords = list()
coords.append([0, 0, 0])
coords.append([0.75, 0.5, 0.75])
lattice = Lattice.cubic(10)
s_elem = Structure(lattice, [co_elem, o_elem], coords)
s_specie = Structure(lattice, [co_specie, o_specie], coords)
s_specie.remove_oxidation_states()
self.assertEqual(s_elem, s_specie, "Oxidation state remover "
"failed")
def test_apply_operation(self):
op = SymmOp.from_axis_angle_and_translation([0, 0, 1], 90)
s = self.structure.copy()
s.apply_operation(op)
self.assertArrayAlmostEqual(
s.lattice.matrix,
[[0.000000, 3.840198, 0.000000],
[-3.325710, 1.920099, 0.000000],
[2.217138, -0.000000, 3.135509]], 5)
op = SymmOp([[1, 1, 0, 0.5], [1, 0, 0, 0.5], [0, 0, 1, 0.5],
[0, 0, 0, 1]])
s = self.structure.copy()
s.apply_operation(op, fractional=True)
self.assertArrayAlmostEqual(
s.lattice.matrix,
[[5.760297, 3.325710, 0.000000],
[3.840198, 0.000000, 0.000000],
[0.000000, -2.217138, 3.135509]], 5)
def test_apply_strain(self):
s = self.structure
initial_coord = s[1].coords
s.apply_strain(0.01)
self.assertAlmostEqual(
s.lattice.abc,
(3.8785999130369997, 3.878600984287687, 3.8785999130549516))
self.assertArrayAlmostEqual(s[1].coords, initial_coord * 1.01)
a1, b1, c1 = s.lattice.abc
s.apply_strain([0.1, 0.2, 0.3])
a2, b2, c2 = s.lattice.abc
self.assertAlmostEqual(a2 / a1, 1.1)
self.assertAlmostEqual(b2 / b1, 1.2)
self.assertAlmostEqual(c2 / c1, 1.3)
def test_scale_lattice(self):
initial_coord = self.structure[1].coords
self.structure.scale_lattice(self.structure.volume * 1.01 ** 3)
self.assertArrayAlmostEqual(
self.structure.lattice.abc,
(3.8785999130369997, 3.878600984287687, 3.8785999130549516))
self.assertArrayAlmostEqual(self.structure[1].coords,
initial_coord * 1.01)
def test_translate_sites(self):
self.structure.translate_sites([0, 1], [0.5, 0.5, 0.5],
frac_coords=True)
self.assertArrayEqual(self.structure.frac_coords[0],
[0.5, 0.5, 0.5])
self.structure.translate_sites([0], [0.5, 0.5, 0.5],
frac_coords=False)
self.assertArrayAlmostEqual(self.structure.cart_coords[0],
[3.38014845, 1.05428585, 2.06775453])
self.structure.translate_sites([0], [0.5, 0.5, 0.5],
frac_coords=True, to_unit_cell=False)
self.assertArrayAlmostEqual(self.structure.frac_coords[0],
[1.00187517, 1.25665291, 1.15946374])
def test_mul(self):
self.structure *= [2, 1, 1]
self.assertEqual(self.structure.formula, "Si4")
s = [2, 1, 1] * self.structure
self.assertEqual(s.formula, "Si8")
self.assertIsInstance(s, Structure)
s = self.structure * [[1, 0, 0], [2, 1, 0], [0, 0, 2]]
self.assertEqual(s.formula, "Si8")
self.assertArrayAlmostEqual(s.lattice.abc,
[7.6803959, 17.5979979, 7.6803959])
def test_make_supercell(self):
self.structure.make_supercell([2, 1, 1])
self.assertEqual(self.structure.formula, "Si4")
self.structure.make_supercell([[1, 0, 0], [2, 1, 0], [0, 0, 1]])
self.assertEqual(self.structure.formula, "Si4")
self.structure.make_supercell(2)
self.assertEqual(self.structure.formula, "Si32")
self.assertArrayAlmostEqual(self.structure.lattice.abc,
[15.360792, 35.195996, 7.680396], 5)
def test_disordered_supercell_primitive_cell(self):
l = Lattice.cubic(2)
f = [[0.5, 0.5, 0.5]]
sp = [{'Si': 0.54738}]
s = Structure(l, sp, f)
#this supercell often breaks things
s.make_supercell([[0,-1,1],[-1,1,0],[1,1,1]])
self.assertEqual(len(s.get_primitive_structure()), 1)
def test_another_supercell(self):
#this is included b/c for some reason the old algo was failing on it
s = self.structure.copy()
s.make_supercell([[0, 2, 2], [2, 0, 2], [2, 2, 0]])
self.assertEqual(s.formula, "Si32")
s = self.structure.copy()
s.make_supercell([[0, 2, 0], [1, 0, 0], [0, 0, 1]])
self.assertEqual(s.formula, "Si4")
def test_to_from_dict(self):
d = self.structure.as_dict()
s2 = Structure.from_dict(d)
self.assertEqual(type(s2), Structure)
def test_to_from_file_string(self):
for fmt in ["cif", "json", "poscar", "cssr", "yaml", "xsf"]:
s = self.structure.to(fmt=fmt)
self.assertIsNotNone(s)
ss = Structure.from_str(s, fmt=fmt)
self.assertArrayAlmostEqual(
ss.lattice.lengths_and_angles,
self.structure.lattice.lengths_and_angles, decimal=5)
self.assertArrayAlmostEqual(ss.frac_coords,
self.structure.frac_coords)
self.assertIsInstance(ss, Structure)
self.structure.to(filename="POSCAR.testing")
self.assertTrue(os.path.exists("POSCAR.testing"))
os.remove("POSCAR.testing")
self.structure.to(filename="structure_testing.json")
self.assertTrue(os.path.exists("structure_testing.json"))
s = Structure.from_file("structure_testing.json")
self.assertEqual(s, self.structure)
os.remove("structure_testing.json")
def test_from_spacegroup(self):
s1 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3), ["Li", "O"],
[[0.25, 0.25, 0.25], [0, 0, 0]])
self.assertEqual(s1.formula, "Li8 O4")
s2 = Structure.from_spacegroup(225, Lattice.cubic(3), ["Li", "O"],
[[0.25, 0.25, 0.25], [0, 0, 0]])
self.assertEqual(s1, s2)
s2 = Structure.from_spacegroup(225, Lattice.cubic(3), ["Li", "O"],
[[0.25, 0.25, 0.25], [0, 0, 0]],
site_properties={"charge": [1, -2]})
self.assertEqual(sum(s2.site_properties["charge"]), 0)
s = Structure.from_spacegroup("Pm-3m", Lattice.cubic(3), ["Cs", "Cl"],
[[0, 0, 0], [0.5, 0.5, 0.5]])
self.assertEqual(s.formula, "Cs1 Cl1")
self.assertRaises(ValueError, Structure.from_spacegroup,
"Pm-3m", Lattice.tetragonal(1, 3), ["Cs", "Cl"],
[[0, 0, 0], [0.5, 0.5, 0.5]])
def test_merge_sites(self):
species = [{'Ag': 0.5}, {'Cl': 0.25}, {'Cl': 0.1},
{'Ag': 0.5}, {'F': 0.15}, {'F': 0.1}]
coords = [[0, 0, 0], [0.5, 0.5, 0.5], [0.5, 0.5, 0.5],
[0, 0, 0], [0.5, 0.5, 1.501], [0.5, 0.5, 1.501]]
s = Structure(Lattice.cubic(1), species, coords)
s.merge_sites()
self.assertEqual(s[0].specie.symbol, 'Ag')
self.assertEqual(s[1].species_and_occu,
Composition({'Cl': 0.35, 'F': 0.25}))
self.assertArrayAlmostEqual(s[1].frac_coords, [.5, .5, .5005])
def test_properties(self):
self.assertEqual(self.structure.num_sites, len(self.structure))
self.structure.make_supercell(2)
self.structure[1] = "C"
sites = list(self.structure.group_by_types())
self.assertEqual(sites[-1].specie.symbol, "C")
self.structure.add_oxidation_state_by_element({"Si": 4, "C": 2})
self.assertEqual(self.structure.charge, 62)
def test_init_error(self):
self.assertRaises(StructureError, Structure, Lattice.cubic(3), ["Si"], [[0, 0, 0], [0.5, 0.5, 0.5]])
def test_from_sites(self):
self.structure.add_site_property("hello", [1, 2])
s = Structure.from_sites(self.structure, to_unit_cell=True)
self.assertEqual(s.site_properties["hello"][1], 2)
def test_magic(self):
s = Structure.from_sites(self.structure)
self.assertEqual(s, self.structure)
self.assertNotEqual(s, None)
s.apply_strain(0.5)
self.assertNotEqual(s, self.structure)
self.assertNotEqual(self.structure * 2, self.structure)
def get_slab(self, shift=0, tol=0.1, energy=None):
"""
This method takes in shift value for the c lattice direction and
generates a slab based on the given shift. You should rarely use this
method. Instead, it is used by other generation algorithms to obtain
all slabs.
Arg:
shift (float): A shift value in Angstrom that determines how much a
slab should be shifted.
tol (float): Tolerance to determine primitive cell.
energy (float): An energy to assign to the slab.
Returns:
(Slab) A Slab object with a particular shifted oriented unit cell.
"""
h = self._proj_height
nlayers_slab = int(math.ceil(self.min_slab_size / h))
nlayers_vac = int(math.ceil(self.min_vac_size / h))
nlayers = nlayers_slab + nlayers_vac
species = self.oriented_unit_cell.species_and_occu
props = self.oriented_unit_cell.site_properties
props = {k: v * nlayers_slab for k, v in props.items()}
frac_coords = self.oriented_unit_cell.frac_coords
frac_coords = np.array(frac_coords) +\
np.array([0, 0, -shift])[None, :]
frac_coords = frac_coords - np.floor(frac_coords)
a, b, c = self.oriented_unit_cell.lattice.matrix
new_lattice = [a, b, nlayers * c]
frac_coords[:, 2] = frac_coords[:, 2] / nlayers
all_coords = []
for i in range(nlayers_slab):
fcoords = frac_coords.copy()
fcoords[:, 2] += i / nlayers
all_coords.extend(fcoords)
slab = Structure(new_lattice, species * nlayers_slab, all_coords,
site_properties=props)
scale_factor = self.slab_scale_factor
# Whether or not to orthogonalize the structure
if self.lll_reduce:
lll_slab = slab.copy(sanitize=True)
mapping = lll_slab.lattice.find_mapping(slab.lattice)
scale_factor = np.dot(mapping[2], scale_factor)
slab = lll_slab
# Whether or not to center the slab layer around the vacuum
if self.center_slab:
avg_c = np.average([c[2] for c in slab.frac_coords])
slab.translate_sites(list(range(len(slab))), [0, 0, 0.5 - avg_c])
if self.primitive:
prim = slab.get_primitive_structure(tolerance=tol)
if energy is not None:
energy = prim.volume / slab.volume * energy
slab = prim
return Slab(slab.lattice, slab.species_and_occu,
slab.frac_coords, self.miller_index,
self.oriented_unit_cell, shift,
scale_factor, site_properties=slab.site_properties,
energy=energy)
def get_slab(self, shift=0, tol=0.1, energy=None):
"""
This method takes in shift value for the c lattice direction and
generates a slab based on the given shift. You should rarely use this
method. Instead, it is used by other generation algorithms to obtain
all slabs.
Arg:
shift (float): A shift value in Angstrom that determines how much a
slab should be shifted.
tol (float): Tolerance to determine primitive cell.
energy (float): An energy to assign to the slab.
Returns:
(Slab) A Slab object with a particular shifted oriented unit cell.
"""
h = self._proj_height
nlayers_slab = int(math.ceil(self.min_slab_size / h))
nlayers_vac = int(math.ceil(self.min_vac_size / h))
nlayers = nlayers_slab + nlayers_vac
species = self.oriented_unit_cell.species_and_occu
props = self.oriented_unit_cell.site_properties
props = {k: v * nlayers_slab for k, v in props.items()}
frac_coords = self.oriented_unit_cell.frac_coords
frac_coords = np.array(frac_coords) +\
np.array([0, 0, -shift])[None, :]
frac_coords = frac_coords - np.floor(frac_coords)
a, b, c = self.oriented_unit_cell.lattice.matrix
new_lattice = [a, b, nlayers * c]
frac_coords[:, 2] = frac_coords[:, 2] / nlayers
all_coords = []
for i in range(nlayers_slab):
fcoords = frac_coords.copy()
fcoords[:, 2] += i / nlayers
all_coords.extend(fcoords)
slab = Structure(new_lattice,
species * nlayers_slab,
all_coords,
site_properties=props)
scale_factor = self.slab_scale_factor
# Whether or not to orthogonalize the structure
if self.lll_reduce:
lll_slab = slab.copy(sanitize=True)
mapping = lll_slab.lattice.find_mapping(slab.lattice)
scale_factor = np.dot(mapping[2], scale_factor)
slab = lll_slab
# Whether or not to center the slab layer around the vacuum
if self.center_slab:
avg_c = np.average([c[2] for c in slab.frac_coords])
slab.translate_sites(list(range(len(slab))), [0, 0, 0.5 - avg_c])
if self.primitive:
prim = slab.get_primitive_structure(tolerance=tol)
if energy is not None:
energy = prim.volume / slab.volume * energy
slab = prim
return Slab(slab.lattice,
slab.species_and_occu,
slab.frac_coords,
self.miller_index,
self.oriented_unit_cell,
shift,
scale_factor,
site_properties=slab.site_properties,
energy=energy)
def from_options(cls, task: Task, original_structure: Structure,
standardize_structure: bool, sort_structure: bool,
is_magnetization: bool, kpt_mode: str, kpt_density: float,
kpt_shift: list, only_even: bool, band_ref_dist: float,
factor: Optional[int], symprec: float,
angle_tolerance: float):
""" Construct Structure and Kpoints from task and some options.
Note: When task and kpt_mode are not consistent e.g., task=Task.band,
kpt_mode="manual", task is prioritized.
Args: See ViseInputSet docstrings
Return: TaskStructureKpoints class object
"""
if sort_structure:
structure = original_structure.get_sorted_structure()
symbol_list = get_symbol_list(structure)
orig_symbol_list = get_symbol_list(original_structure)
if symbol_list != orig_symbol_list:
logger.warning(
"CAUTION: The sequence of the species is changed."
f"Symbol set in the original structure "
f"{symbol_list} "
f"Symbol set in the generated structure "
f"{orig_symbol_list}")
else:
structure = original_structure.copy()
is_structure_changed = False
if task == Task.defect:
kpt_mode = "manual_set"
elif task == Task.cluster_opt:
kpt_mode = "manual_set"
kpt_density = 1e-5
only_even = False
kpt_shift = [0, 0, 0]
elif task == Task.band:
kpt_mode = "band"
elif task == Task.phonon_force:
kpt_mode = "manual_set"
if kpt_shift != [0, 0, 0]:
logger.warning(
"For phonon force calculations, Gamma centering "
"is forced for k-point sampling.")
kpt_shift = [0, 0, 0]
else:
primitive_structure, is_structure_changed = \
find_spglib_primitive(structure, symprec, angle_tolerance)
if standardize_structure:
org = original_structure.lattice.matrix
primitive = primitive_structure.lattice.matrix
if is_structure_changed:
with np.printoptions(precision=3, suppress=True):
logger.warning("CAUTION: The structure is changed.\n"
f"Original lattice\n {org} \n"
f"Generated lattice\n {primitive} \n")
structure = primitive_structure
else:
if is_structure_changed and kpt_mode != "manual_set":
logger.warning(
"Standardizaion is set to False and the given "
"structure is not a primitive cell. Thus, the "
"kpoint set is switched to manual_set.")
kpt_mode = "manual_set"
else:
logger.info("The structure is a standardized primitive.")
# Gamma-center mesh is a must for GW calculations due to vasp
# implementation and tetrahedron method, while is a strong recommend for
# dos and dielectric function to sample the band edges.
if task in PLOT_TASK and kpt_shift != [0, 0, 0]:
logger.warning("Gamma centering is forced for k-point sampling.")
kpt_shift = [0, 0, 0]
if factor is None:
if task == Task.dielectric_function:
factor = 3
elif task in (Task.dos, Task.dielectric_dfpt,
Task.dielectric_finite_field):
factor = 2
else:
factor = 1
kpoints = MakeKpoints(mode=kpt_mode,
structure=structure,
kpt_density=kpt_density,
only_even=only_even,
ref_distance=band_ref_dist,
kpt_shift=kpt_shift,
factor=factor,
symprec=symprec,
angle_tolerance=angle_tolerance,
is_magnetization=is_magnetization)
kpoints.make_kpoints()
return cls(structure=structure,
kpoints=kpoints.kpoints,
is_structure_changed=kpoints.is_structure_changed,
sg=kpoints.sg,
num_kpts=kpoints.num_kpts,
factor=factor)
