Esempio n. 1
0
 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 = IStructure(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 = IStructure(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)
Esempio n. 2
0
 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 = IStructure(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 = IStructure(Lattice.cubic(4.09), ["Li"] * 2, coords)
     self.assertEqual(len(bcc_li.get_primitive_structure()), 1)
Esempio n. 3
0
    def test_interpolate_lattice(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        struct = IStructure(self.lattice, ["Si"] * 2, coords)
        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        l2 = Lattice.from_lengths_and_angles([3,4,4], [100,100,70])
        struct2 = IStructure(l2, ["Si"] * 2, coords2)
        int_s = struct.interpolate(struct2, 2, interpolate_lattices=True)
        self.assertArrayAlmostEqual(struct.lattice.abc,
                                    int_s[0].lattice.abc)
        self.assertArrayAlmostEqual(struct.lattice.angles,
                                    int_s[0].lattice.angles)
        self.assertArrayAlmostEqual(struct2.lattice.abc,
                                    int_s[2].lattice.abc)
        self.assertArrayAlmostEqual(struct2.lattice.angles,
                                    int_s[2].lattice.angles)
        int_angles = [110.3976469, 94.5359731, 64.5165856]
        self.assertArrayAlmostEqual(int_angles,
                                    int_s[1].lattice.angles)

        # Assert that volume is monotonic
        self.assertTrue(struct2.lattice.volume >= int_s[1].lattice.volume)
        self.assertTrue(int_s[1].lattice.volume >= struct.lattice.volume)
Esempio n. 4
0
 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 = IStructure(l, ["Ag"] * 6, coords)
     sprim = s.get_primitive_structure(tolerance=0.1)
     self.assertEqual(len(sprim), 6)
Esempio n. 5
0
    def test_from_dict(self):

        d = self.propertied_structure.as_dict()
        s = IStructure.from_dict(d)
        self.assertEqual(s[0].magmom, 5)
        d = self.propertied_structure.as_dict(0)
        s2 = IStructure.from_dict(d)
        self.assertEqual(s, s2)

        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 = IStructure.from_dict(d)
        self.assertEqual(s[0].magmom, 5)
        self.assertEqual(s[0].specie.spin, 3)
        self.assertEqual(type(s), IStructure)
Esempio n. 6
0
 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 = IStructure(l, ["Ag"] * 6, coords)
     sprim = s.get_primitive_structure(tolerance=0.1)
     self.assertEqual(len(sprim), 6)
Esempio n. 7
0
    def test_interpolate_lattice_rotation(self):
        l1 = Lattice([[1, 0, 0], [0, 1, 0], [0, 0, 1]])
        l2 = Lattice([[-1.01, 0, 0], [0, -1.01, 0], [0, 0, 1]])
        coords = [[0, 0, 0], [0.75, 0.5, 0.75]]
        struct1 = IStructure(l1, ["Si"] * 2, coords)
        struct2 = IStructure(l2, ["Si"] * 2, coords)
        int_s = struct1.interpolate(struct2, 2, interpolate_lattices=True)

        # Assert that volume is monotonic
        self.assertTrue(struct2.lattice.volume >= int_s[1].lattice.volume)
        self.assertTrue(int_s[1].lattice.volume >= struct1.lattice.volume)
Esempio n. 8
0
    def test_interpolate_lattice_rotation(self):
        l1 = Lattice([[1, 0, 0], [0, 1, 0], [0, 0, 1]])
        l2 = Lattice([[-1.01, 0, 0], [0, -1.01, 0], [0, 0, 1]])
        coords = [[0, 0, 0], [0.75, 0.5, 0.75]]
        struct1 = IStructure(l1, ["Si"] * 2, coords)
        struct2 = IStructure(l2, ["Si"] * 2, coords)
        int_s = struct1.interpolate(struct2, 2, interpolate_lattices=True)

        # Assert that volume is monotonic
        self.assertTrue(struct2.lattice.volume >= int_s[1].lattice.volume)
        self.assertTrue(int_s[1].lattice.volume >= struct1.lattice.volume)
Esempio n. 9
0
 def test_get_sorted_structure(self):
     coords = list()
     coords.append([0, 0, 0])
     coords.append([0.75, 0.5, 0.75])
     s = IStructure(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)
     s = IStructure(self.lattice, ["Se", "C", "Se", "C"], [[0] * 3, [0.5] * 3, [0.25] * 3, [0.75] * 3])
     self.assertEqual([site.specie.symbol for site in s.get_sorted_structure()], ["C", "C", "Se", "Se"])
Esempio n. 10
0
 def test_bad_structure(self):
     coords = list()
     coords.append([0, 0, 0])
     coords.append([0.75, 0.5, 0.75])
     coords.append([0.75, 0.5, 0.75])
     self.assertRaises(StructureError,
                       IStructure,
                       self.lattice, ["Si"] * 3,
                       coords,
                       validate_proximity=True)
     #these shouldn't raise an error
     IStructure(self.lattice, ["Si"] * 2, coords[:2], True)
     IStructure(self.lattice, ["Si"], coords[:1], True)
Esempio n. 11
0
    def test_interpolate(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        struct = IStructure(self.lattice, ["Si"] * 2, coords)
        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si"] * 2, coords2)
        int_s = struct.interpolate(struct2, 10)
        for s in int_s:
            self.assertIsNotNone(s, "Interpolation Failed!")
            self.assertEqual(int_s[0].lattice, s.lattice)
        self.assertArrayEqual(int_s[1][1].frac_coords, [0.725, 0.5, 0.725])

        badlattice = [[1, 0.00, 0.00], [0, 1, 0.00], [0.00, 0, 1]]
        struct2 = IStructure(badlattice, ["Si"] * 2, coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)

        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si", "Fe"], coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)

        # Test autosort feature.
        s1 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3),
                                       ["Fe"], [[0, 0, 0]])
        s1.pop(0)
        s2 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3),
                                       ["Fe"], [[0, 0, 0]])
        s2.pop(2)
        random.shuffle(s2)

        for s in s1.interpolate(s2, autosort_tol=0.5):
            self.assertArrayAlmostEqual(s1[0].frac_coords, s[0].frac_coords)
            self.assertArrayAlmostEqual(s1[2].frac_coords, s[2].frac_coords)

        # Make sure autosort has no effect on simpler interpolations,
        # and with shuffled sites.
        s1 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3),
                                       ["Fe"], [[0, 0, 0]])
        s2 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3),
                                       ["Fe"], [[0, 0, 0]])
        s2[0] = "Fe", [0.01, 0.01, 0.01]
        random.shuffle(s2)

        for s in s1.interpolate(s2, autosort_tol=0.5):
            self.assertArrayAlmostEqual(s1[1].frac_coords, s[1].frac_coords)
            self.assertArrayAlmostEqual(s1[2].frac_coords, s[2].frac_coords)
            self.assertArrayAlmostEqual(s1[3].frac_coords, s[3].frac_coords)
Esempio n. 12
0
 def test_fractional_occupations(self):
     coords = list()
     coords.append([0, 0, 0])
     coords.append([0.75, 0.5, 0.75])
     s = IStructure(self.lattice, [{'O': 1.0}, {'Mg': 0.8}], coords)
     self.assertEqual(str(s.composition), 'Mg0.8 O1')
     self.assertFalse(s.is_ordered)
Esempio n. 13
0
    def test_to_from_file_string(self):
        for fmt in ["cif", "json", "poscar", "cssr"]:
            s = self.struct.to(fmt=fmt)
            self.assertIsNotNone(s)
            ss = IStructure.from_str(s, fmt=fmt)
            self.assertArrayAlmostEqual(
                ss.lattice.lengths_and_angles,
                self.struct.lattice.lengths_and_angles, decimal=5)
            self.assertArrayAlmostEqual(ss.frac_coords, self.struct.frac_coords)
            self.assertIsInstance(ss, IStructure)

        self.struct.to(filename="POSCAR.testing")
        self.assertTrue(os.path.exists("POSCAR.testing"))
        os.remove("POSCAR.testing")

        self.struct.to(filename="Si_testing.yaml")
        self.assertTrue(os.path.exists("Si_testing.yaml"))
        s = Structure.from_file("Si_testing.yaml")
        self.assertEqual(s, self.struct)
        os.remove("Si_testing.yaml")

        self.struct.to(filename="POSCAR.testing.gz")
        s = Structure.from_file("POSCAR.testing.gz")
        self.assertEqual(s, self.struct)
        os.remove("POSCAR.testing.gz")
Esempio n. 14
0
 def setUp(self):
     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 = IStructure(self.lattice, ["Si"] * 2, coords)
     self.assertEqual(len(self.struct), 2, "Wrong number of sites in structure!")
     self.assertTrue(self.struct.is_ordered)
     self.assertTrue(self.struct.ntypesp == 1)
     coords = list()
     coords.append([0, 0, 0])
     coords.append([0.0, 0, 0.0000001])
     self.assertRaises(StructureError, IStructure, self.lattice, ["Si"] * 2, coords, True)
     self.propertied_structure = IStructure(self.lattice, ["Si"] * 2, coords, site_properties={"magmom": [5, -5]})
Esempio n. 15
0
def get_pymatgen_formula(compound):
    """
	given a string of 'A2B1Bp1X6' return its pymatgen standard formula

	Args:
		compound: a string of form 'A2B1Bp1X6'

	Returns:
		formula : a formula style defined in pymatgen
	"""
    m = re.match(
        "([A-Za-z]+)([0-9])([A-Za-z]+)([0-9])([A-Za-z]+)([0-9])([A-Za-z]+)([0-9])",
        compound)
    A, B, Bp, X = m.group(1), m.group(3), m.group(5), m.group(7)
    struc = IStructure(lattice=[[1, 0.000000, 0.000000],
                                [0.5, sqrt(3) / 2, 0.000000],
                                [0.5, 1 / 2.0 / sqrt(3.0),
                                 sqrt(2.0 / 3.0)]],
                       species=[A, A, B, Bp, X, X, X, X, X, X],
                       coords=[[0.2500, 0.2500, 0.2500],
                               [0.7500, 0.7500, 0.7500],
                               [0.5000, 0.5000, 0.5000],
                               [0.0000, 0.0000, 0.0000],
                               [0.2550, 0.7450, 0.2550],
                               [0.7450, 0.7450, 0.2550],
                               [0.7450, 0.2550, 0.7450],
                               [0.7450, 0.2550, 0.2550],
                               [0.2550, 0.7450, 0.7450],
                               [0.2550, 0.2550, 0.7450]])
    return struc.formula
Esempio n. 16
0
    def test_to_from_file_string(self):
        for fmt in ["cif", "json", "poscar", "cssr"]:
            s = self.struct.to(fmt=fmt)
            self.assertIsNotNone(s)
            ss = IStructure.from_str(s, fmt=fmt)
            self.assertArrayAlmostEqual(ss.lattice.lengths_and_angles,
                                        self.struct.lattice.lengths_and_angles,
                                        decimal=5)
            self.assertArrayAlmostEqual(ss.frac_coords,
                                        self.struct.frac_coords)
            self.assertIsInstance(ss, IStructure)

        self.struct.to(filename="POSCAR.testing")
        self.assertTrue(os.path.exists("POSCAR.testing"))
        os.remove("POSCAR.testing")

        self.struct.to(filename="Si_testing.yaml")
        self.assertTrue(os.path.exists("Si_testing.yaml"))
        s = Structure.from_file("Si_testing.yaml")
        self.assertEqual(s, self.struct)
        os.remove("Si_testing.yaml")

        self.struct.to(filename="POSCAR.testing.gz")
        s = Structure.from_file("POSCAR.testing.gz")
        self.assertEqual(s, self.struct)
        os.remove("POSCAR.testing.gz")
Esempio n. 17
0
    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 = IStructure(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 = IStructure(Lattice.cubic(4.09), ["Li"] * 2, coords)
        bcc_prim = bcc_li.get_primitive_structure()
        self.assertEqual(len(bcc_prim), 1)
        self.assertAlmostEqual(bcc_prim.lattice.alpha, 109.47122, 3)

        coords = [[0] * 3, [0.5] * 3, [0.25] * 3, [0.26] * 3]
        s = IStructure(Lattice.cubic(4.09), ["Ag"] * 4, coords)
        self.assertEqual(len(s.get_primitive_structure()), 4)
Esempio n. 18
0
 def test_interpolate_lattice(self):
     coords = list()
     coords.append([0, 0, 0])
     coords.append([0.75, 0.5, 0.75])
     struct = IStructure(self.lattice, ["Si"] * 2, coords)
     coords2 = list()
     coords2.append([0, 0, 0])
     coords2.append([0.5, 0.5, 0.5])
     l2 = Lattice.from_lengths_and_angles([3, 4, 4], [100, 100, 70])
     struct2 = IStructure(l2, ["Si"] * 2, coords2)
     int_s = struct.interpolate(struct2, 2, interpolate_lattices=True)
     self.assertArrayAlmostEqual(struct.lattice.abc, int_s[0].lattice.abc)
     self.assertArrayAlmostEqual(struct.lattice.angles, int_s[0].lattice.angles)
     self.assertArrayAlmostEqual(struct2.lattice.abc, int_s[2].lattice.abc)
     self.assertArrayAlmostEqual(struct2.lattice.angles, int_s[2].lattice.angles)
     int_angles = [(a + struct2.lattice.angles[i]) / 2 for i, a in enumerate(struct.lattice.angles)]
     self.assertArrayAlmostEqual(int_angles, int_s[1].lattice.angles)
Esempio n. 19
0
    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, 0.0000001])

        structure = IStructure(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)
Esempio n. 20
0
 def setUp(self):
     coords = [[0, 0, 0], [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 = IStructure(self.lattice, ["Si"] * 2, coords)
     self.assertEqual(len(self.struct), 2,
                      "Wrong number of sites in structure!")
     self.assertTrue(self.struct.is_ordered)
     self.assertTrue(self.struct.ntypesp == 1)
     coords = list()
     coords.append([0, 0, 0])
     coords.append([0., 0, 0.0000001])
     self.assertRaises(StructureError, IStructure, self.lattice, ["Si"] * 2,
                       coords, True)
     self.propertied_structure = IStructure(
         self.lattice, ["Si"] * 2,
         coords,
         site_properties={'magmom': [5, -5]})
Esempio n. 21
0
 def test_specie_init(self):
     coords = list()
     coords.append([0, 0, 0])
     coords.append([0.75, 0.5, 0.75])
     s = IStructure(self.lattice, [{
         Specie('O', -2): 1.0
     }, {
         Specie('Mg', 2): 0.8
     }], coords)
     self.assertEqual(str(s.composition), 'Mg2+0.8 O2-1')
Esempio n. 22
0
 def test_from_dict(self):
     d = self.propertied_structure.to_dict
     s = IStructure.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 = IStructure.from_dict(d)
     self.assertEqual(s[0].magmom, 5)
     self.assertEqual(s[0].specie.spin, 3)
     self.assertEqual(type(s), IStructure)
Esempio n. 23
0
def running(temp, pre, crt):
    # -- Run AIMD at (run00, run01, ...)
    # -- First step is heat-up.
    total_try = 1
    #pre_dir = ("run%2d" % pre).replace(" ", "0")
    #crt_dir = ("run%2d" % crt).replace(" ", "0")
    pre_dir = ("run%03d" % pre)
    crt_dir = ("run%03d" % crt)
    # -- initiating
    if crt == 0:
        structure = IStructure.from_file("../" + structure_filename)
        crt_nsw = heating_nsw
        user_incar["SMASS"] = -1
        inputset = MITMDSet(structure,
                            100.0,
                            float(temp),
                            heating_nsw,
                            user_incar_settings=user_incar)
        inputset.write_input(crt_dir)
    # -- run
    else:
        run = Vasprun("%s/vasprun.xml.gz" % pre_dir,
                      parse_dos=False,
                      parse_eigen=False)
        structure = run.final_structure
        crt_nsw = nsw
        #structure = IStructure.from_file("%s/CONTCAR" % pre_dir)
        user_incar["SMASS"] = 0
        inputset = MITMDSet(structure,
                            float(temp),
                            float(temp),
                            nsw,
                            user_incar_settings=user_incar)
        inputset.write_input(crt_dir)
        os.system("cp %s/WAVECAR %s" % (pre_dir, crt_dir))
    os.chdir(crt_dir)
    os.system("mpirun -np $NSLOTS %s < /dev/null > vasp.out" % vasp)
    time.sleep(5)
    os.system("gzip OUTCAR vasprun.xml")
    os.system("rm -rf DOSCAR XDATCAR")
    write_log("try: %d" % total_try)
    properly_terminated = terminated_check(crt_nsw)
    while not properly_terminated:
        total_try += 1
        os.system("mpirun -np $NSLOTS %s < /dev/null > vasp.out" % vasp)
        time.sleep(5)
        os.system("gzip OUTCAR vasprun.xml")
        os.system("rm -rf DOSCAR XDATCAR")
        write_log("try: %d" % total_try)
        properly_terminated = terminated_check(crt_nsw)
    os.system("touch vasp.done")
    os.chdir("../")
    os.system("rm -rf %s/WAVECAR" %
              pre_dir)  # remove WAVECAR in previous dir to reduce storage
Esempio n. 24
0
    def featurize(self, structure):
        """Convert a pymatgen Structure to an immutable IStructure,

        Args:
            structure (`pymatgen.core.structure.Structure`): A structure.

        Returns:
            (`pymatgen.core.structure.IStructure`): An immutable IStructure
                object.
        """
        return [IStructure.from_sites(structure)]
Esempio n. 25
0
 def test_interpolate_lattice(self):
     coords = list()
     coords.append([0, 0, 0])
     coords.append([0.75, 0.5, 0.75])
     struct = IStructure(self.lattice, ["Si"] * 2, coords)
     coords2 = list()
     coords2.append([0, 0, 0])
     coords2.append([0.5, 0.5, 0.5])
     l2 = Lattice.from_lengths_and_angles([3, 4, 4], [100, 100, 70])
     struct2 = IStructure(l2, ["Si"] * 2, coords2)
     int_s = struct.interpolate(struct2, 2, interpolate_lattices=True)
     self.assertArrayAlmostEqual(struct.lattice.abc, int_s[0].lattice.abc)
     self.assertArrayAlmostEqual(struct.lattice.angles,
                                 int_s[0].lattice.angles)
     self.assertArrayAlmostEqual(struct2.lattice.abc, int_s[2].lattice.abc)
     self.assertArrayAlmostEqual(struct2.lattice.angles,
                                 int_s[2].lattice.angles)
     int_angles = [(a + struct2.lattice.angles[i]) / 2
                   for i, a in enumerate(struct.lattice.angles)]
     self.assertArrayAlmostEqual(int_angles, int_s[1].lattice.angles)
Esempio n. 26
0
    def featurize(self, structure):
        """Convert a pymatgen Structure to an immutable IStructure,

        Args:
            structure (`pymatgen.core.structure.Structure`): A structure.

        Returns:
            (`pymatgen.core.structure.IStructure`): An immutable IStructure
                object.
        """
        return [IStructure.from_sites(structure)]
Esempio n. 27
0
def load_jit_model(model_file, crystal_file_handle):
    model = torch.jit.load(model_file)
    model.eval()
    cif_str = crystal_file_handle.read().decode("utf-8")
    struct = IStructure.from_str(cif_str, fmt="cif")
    dataset = StructureOnlyDataset([struct])
    dataloader = DataLoader(dataset, batch_size=1)
    input = next(iter(dataloader))
    x, y = model(input)
    x = x.detach().numpy()
    y = y.detach().numpy()
    return x, y
Esempio n. 28
0
    def test_as_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 = IStructure(self.lattice, [{si: 0.5, mn: 0.5}, {si: 0.5}],
                            coords)
        self.assertIn("lattice", struct.as_dict())
        self.assertIn("sites", struct.as_dict())
        d = self.propertied_structure.as_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 = IStructure(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.as_dict()
        self.assertEqual(d['sites'][0]['properties']['magmom'], 5)
        self.assertEqual(d['sites'][0]['species'][0]['properties']['spin'], 3)

        d = s.as_dict(0)
        self.assertNotIn("volume", d['lattice'])
        self.assertNotIn("xyz", d['sites'][0])
Esempio n. 29
0
 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 = IStructure(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 = IStructure(Lattice.cubic(4.09), ["Li"] * 2, coords)
     self.assertEqual(len(bcc_li.get_primitive_structure()), 1)
Esempio n. 30
0
    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 = IStructure(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)
Esempio n. 31
0
    def test_interpolate(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        struct = IStructure(self.lattice, ["Si"] * 2, coords)
        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si"] * 2, coords2)
        int_s = struct.interpolate(struct2, 10)
        for s in int_s:
            self.assertIsNotNone(s, "Interpolation Failed!")
        self.assertArrayEqual(int_s[1][1].frac_coords, [0.725, 0.5, 0.725])

        badlattice = [[1, 0.00, 0.00], [0, 1, 0.00], [0.00, 0, 1]]
        struct2 = IStructure(badlattice, ["Si"] * 2, coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)

        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si", "Fe"], coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)
Esempio n. 32
0
    def test_interpolate_lattice(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        struct = IStructure(self.lattice, ["Si"] * 2, coords)
        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        l2 = Lattice.from_lengths_and_angles([3, 4, 4], [100, 100, 70])
        struct2 = IStructure(l2, ["Si"] * 2, coords2)
        int_s = struct.interpolate(struct2, 2, interpolate_lattices=True)
        self.assertArrayAlmostEqual(struct.lattice.abc, int_s[0].lattice.abc)
        self.assertArrayAlmostEqual(struct.lattice.angles,
                                    int_s[0].lattice.angles)
        self.assertArrayAlmostEqual(struct2.lattice.abc, int_s[2].lattice.abc)
        self.assertArrayAlmostEqual(struct2.lattice.angles,
                                    int_s[2].lattice.angles)
        int_angles = [110.3976469, 94.5359731, 64.5165856]
        self.assertArrayAlmostEqual(int_angles, int_s[1].lattice.angles)

        # Assert that volume is monotonic
        self.assertTrue(struct2.lattice.volume >= int_s[1].lattice.volume)
        self.assertTrue(int_s[1].lattice.volume >= struct.lattice.volume)
Esempio n. 33
0
def get_all_nearest_neighbors(method, structure):
    """Get the nearest neighbor list of a structure

    Args:
        method (NearNeighbor) - Method used to compute nearest neighbors
        structure (IStructure) - Structure to study
    Returns:
        Output of `method.get_all_nn_info(structure)`
    """

    # pymatgen does not hash Structure objects, so we need
    #  to convert from Structure to the immutatble IStructure method
    if isinstance(structure, Structure):
        structure = IStructure.from_sites(structure)
    return _get_all_nearest_neighbors(method, structure)
Esempio n. 34
0
 def get_input(data):
     couples = []
     for item in data:
         structure = IStructure.from_dict(item)
         try:
             raman = torch.FloatTensor(item["raman"])
             graph = CrystalEmbedding(structure, max_atoms=30)
         except ValueError:
             continue
         except RuntimeError:
             continue
         except TypeError:
             continue
         encoded_graph = graph.convert_to_model_input()
         couples.append((encoded_graph, raman))
     return couples
Esempio n. 35
0
def structure_stats(X):
    """
    Transform the input X to immutable IStructure to use caching and call
    _structure_stats .
    Args:
        X: iterable structures, can be pymatgen Structure or IStructure objects

    Returns:
        _structure_stats
    """
    X_struct = list()
    for structure in X:
        if isinstance(structure, Structure):
            X_struct.append(IStructure.from_sites(structure))
        elif isinstance(structure, IStructure):
            X_struct.append(structure)
    return _structure_stats(tuple(X_struct))
    def apply_transformation(self, structure):
        # get the new sites
        new_sites = self._voronoi_points(structure)
        if self._midpoints:
            dms = self._delaunay_midpoints(structure)
            for i in range(len(new_sites)):
                new_sites[i].extend(dms[i])

        # insert the new sites with dummy species
        se = structure
        dummy = DummySpecie()
        for i, sites_list in enumerate(new_sites):
            for ns in sites_list:
                if self._bl == {}:
                    se.append(self._sp, ns, coords_are_cartesian=True, validate_proximity=False)
                elif structure[i].specie in self._bl.keys():
                    bv = ns - structure[i].coords
                    bv *= self._bl[structure[i].specie] / np.linalg.norm(bv)
                    coords = structure[i].coords + bv
                    se.append_site(self._sp, coords, coords_are_cartesian=True, validate_proximity=False)
        logging.debug("Starting moving to unit cell")
        se = IStructure.get_reduced_structure(se)
        logging.debug("Finished moving to unit cell")

        structure = se  # .modified_structure

        # delete sites that are closer than the bond distance
        to_delete = []
        for sp, d in self._bl.items():
            neighbors = structure.get_all_neighbors(d * 0.999)
            for i in range(len(structure)):
                if structure[i].specie == dummy:
                    for n in neighbors[i]:
                        if n[0].specie == sp:
                            to_delete.append(i)
                            break
        se.remove_sites(to_delete)

        # replace the dummy species to get the correct composition
        if self._n:
            # amt = self._n / se.modified_structure.composition[dummy]
            amt = self._n / se.composition[dummy]
            se.replace_species({dummy: {self._sp: amt}})

        return se  # .modified_structure
Esempio n. 37
0
    def _get_all_nearest_neighbors(method, crystal):
        '''
        Get the nearest neighbor list of a structure

        Args:
            method: method used to compute nearest_neighbors
            crystal:  pymatgen structure

        Returns:
            nearest neighbors
        '''
        # check that the passed crystal is a pymatgen structure object
        if isinstance(crystal, Structure):
            # make the structure an immutable object
            crystal = IStructure.from_sites(crystal)

        # get the voronoi info of the crystal
        return method.get_all_nn_info(crystal)
Esempio n. 38
0
    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 = IStructure(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 = IStructure(Lattice.cubic(4.09), ["Li"] * 2, coords)
        bcc_prim = bcc_li.get_primitive_structure()
        self.assertEqual(len(bcc_prim), 1)
        self.assertAlmostEqual(bcc_prim.lattice.alpha, 109.47122, 3)

        coords = [[0] * 3, [0.5] * 3, [0.25] * 3, [0.26] * 3]
        s = IStructure(Lattice.cubic(4.09), ["Ag"] * 4, coords)
        self.assertEqual(len(s.get_primitive_structure()), 4)
Esempio n. 39
0
    def test_interpolate(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        struct = IStructure(self.lattice, ["Si"] * 2, coords)
        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si"] * 2, coords2)
        int_s = struct.interpolate(struct2, 10)
        for s in int_s:
            self.assertIsNotNone(s, "Interpolation Failed!")
            self.assertEqual(int_s[0].lattice, s.lattice)
        self.assertArrayEqual(int_s[1][1].frac_coords, [0.725, 0.5, 0.725])

        badlattice = [[1, 0.00, 0.00], [0, 1, 0.00], [0.00, 0, 1]]
        struct2 = IStructure(badlattice, ["Si"] * 2, coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)

        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si", "Fe"], coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)

        # Test autosort feature.
        s1 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3), ["Fe"],
                                       [[0, 0, 0]])
        s1.pop(0)
        s2 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3), ["Fe"],
                                       [[0, 0, 0]])
        s2.pop(2)
        random.shuffle(s2)

        for s in s1.interpolate(s2, autosort_tol=0.5):
            self.assertArrayAlmostEqual(s1[0].frac_coords, s[0].frac_coords)
            self.assertArrayAlmostEqual(s1[2].frac_coords, s[2].frac_coords)

        # Make sure autosort has no effect on simpler interpolations,
        # and with shuffled sites.
        s1 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3), ["Fe"],
                                       [[0, 0, 0]])
        s2 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3), ["Fe"],
                                       [[0, 0, 0]])
        s2[0] = "Fe", [0.01, 0.01, 0.01]
        random.shuffle(s2)

        for s in s1.interpolate(s2, autosort_tol=0.5):
            self.assertArrayAlmostEqual(s1[1].frac_coords, s[1].frac_coords)
            self.assertArrayAlmostEqual(s1[2].frac_coords, s[2].frac_coords)
            self.assertArrayAlmostEqual(s1[3].frac_coords, s[3].frac_coords)
Esempio n. 40
0
def struct_from_sgnum(sgnum: int,
                      scale: float,
                      lattice_vectors: Union[List[List[float]],
                                             numpy.ndarray] = None,
                      init_coords: Union[List[List[float]],
                                         numpy.ndarray] = None,
                      species: List[str] = None) -> IStructure:
    if init_coords is None:
        init_coords = [[0, 0, 0]]
    if lattice_vectors is None:
        lattice_vectors = [[0, 0, 1], [0, 1, 0], [1, 0, 0]]
    if species is None:
        species = ["Si"] * len(init_coords)

    lattice = Lattice(
        [x * scale for vector in lattice_vectors for x in vector])
    structure = IStructure.from_spacegroup(sgnum, lattice, species,
                                           init_coords)
    return structure.get_primitive_structure()
Esempio n. 41
0
    def __init__(self, filename, grid_size=1):
        structure = IStructure.from_file(filename)
        self.grid_size = grid_size

        self.sites = structure.sites
        self.all_species = [site.specie.number for site in self.sites]
        self.all_coords = [site.coords for site in self.sites]

        lattice = structure.lattice
        a, b, c = lattice.a, lattice.b, lattice.c
        self.grid_a = self.get_grid_length(a, self.grid_size)
        self.grid_b = self.get_grid_length(b, self.grid_size)
        self.grid_c = self.get_grid_length(c, self.grid_size)

        # total_atom_info = get_cgcnn_atom_info()
        total_atom_info = atomic_info()
        empty_info = np.full(total_atom_info[0].shape, -1)
        empty_info = np.array([empty_info])
        self.total_atom_info = np.concatenate((empty_info, total_atom_info),
                                              axis=0)
Esempio n. 42
0
def get_data(normalize_y, sample_size):
    radius = 3
    max_neighbor_num = 10
    training = 0.9
    test = 0.1

    df = pd.read_csv("./Data/metal-alloy-db.v2/00Total_DB.csv")
    # df = df.sample(n=len(df))
    df = df.sample(n=sample_size)

    cifs = "./Data/metal-alloy-db.v2/" + df['DBname'] + ".cif"
    structures = [IStructure.from_file(cif) for cif in cifs]
    encoded_structures = [
        structure_encoder(structure, radius, max_neighbor_num)
        for structure in structures
    ]
    x_data = np.array(encoded_structures)

    formation_energy = df['FormationEnergy']
    if normalize_y:
        mean = formation_energy.mean()
        std = formation_energy.std()
        norm_form_energy = (df['FormationEnergy'] - mean) / std

        def norm_back(val, mean, std):
            return val * std + mean

        y_data = [[val] for val in norm_form_energy]
    else:
        y_data = [[val] for val in formation_energy]
    y_data = np.array(y_data)

    total = len(df)
    train = int(float(total) * training)
    test = int(float(total) * test)
    x_train = x_data[:train]
    y_train = y_data[:train]
    x_test = x_data[train:train + test]
    y_test = y_data[train:train + test]

    return x_train, y_train, x_test, y_test
Esempio n. 43
0
 def test_get_sorted_structure(self):
     coords = list()
     coords.append([0, 0, 0])
     coords.append([0.75, 0.5, 0.75])
     s = IStructure(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)
     s = IStructure(self.lattice, ["Se", "C", "Se", "C"],
                    [[0] * 3, [0.5] * 3, [0.25] * 3, [0.75] * 3])
     self.assertEqual(
         [site.specie.symbol for site in s.get_sorted_structure()],
         ["C", "C", "Se", "Se"])
Esempio n. 44
0
    def test_interpolate(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        struct = IStructure(self.lattice, ["Si"] * 2, coords)
        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si"] * 2, coords2)
        int_s = struct.interpolate(struct2, 10)
        for s in int_s:
            self.assertIsNotNone(s, "Interpolation Failed!")
        self.assertArrayEqual(int_s[1][1].frac_coords, [0.725, 0.5, 0.725])

        badlattice = [[1, 0.00, 0.00], [0, 1, 0.00], [0.00, 0, 1]]
        struct2 = IStructure(badlattice, ["Si"] * 2, coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)

        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si", "Fe"], coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)
Esempio n. 45
0
 def test_from_dict(self):
     d = self.propertied_structure.to_dict
     s = IStructure.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 = IStructure.from_dict(d)
     self.assertEqual(s[0].magmom, 5)
     self.assertEqual(s[0].specie.spin, 3)
     self.assertEqual(type(s), IStructure)
Esempio n. 46
0
class IStructureTest(PymatgenTest):

    def setUp(self):
        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 = IStructure(self.lattice, ["Si"] * 2, coords)
        self.assertEqual(len(self.struct), 2,
                         "Wrong number of sites in structure!")
        self.assertTrue(self.struct.is_ordered)
        self.assertTrue(self.struct.ntypesp == 1)
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0., 0, 0.0000001])
        self.assertRaises(StructureError, IStructure, self.lattice,
                          ["Si"] * 2, coords, True)
        self.propertied_structure = IStructure(
            self.lattice, ["Si"] * 2, coords,
            site_properties={'magmom': [5, -5]})

    def test_bad_structure(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        coords.append([0.75, 0.5, 0.75])
        self.assertRaises(StructureError, IStructure, self.lattice,
                          ["Si"] * 3, coords, validate_proximity=True)

    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 = IStructure(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 = IStructure(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)
        s = IStructure(self.lattice, ["Se", "C", "Se", "C"],
                       [[0] * 3, [0.5] * 3, [0.25] * 3, [0.75] * 3])
        self.assertEqual([site.specie.symbol
                          for site in s.get_sorted_structure()],
                         ["C", "C", "Se", "Se"])


    def test_fractional_occupations(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        s = IStructure(self.lattice, [{'O': 1.0}, {'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 = IStructure(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 = IStructure(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 = IStructure.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 = IStructure.from_dict(d)
        self.assertEqual(s[0].magmom, 5)
        self.assertEqual(s[0].specie.spin, 3)
        self.assertEqual(type(s), IStructure)

    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 = IStructure(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 = IStructure(self.lattice, ["Si"] * 2, coords)
        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si"] * 2, coords2)
        int_s = struct.interpolate(struct2, 10)
        for s in int_s:
            self.assertIsNotNone(s, "Interpolation Failed!")
            self.assertEqual(int_s[0].lattice, s.lattice)
        self.assertArrayEqual(int_s[1][1].frac_coords, [0.725, 0.5, 0.725])

        badlattice = [[1, 0.00, 0.00], [0, 1, 0.00], [0.00, 0, 1]]
        struct2 = IStructure(badlattice, ["Si"] * 2, coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)

        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si", "Fe"], coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)
    
    def test_interpolate_lattice(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        struct = IStructure(self.lattice, ["Si"] * 2, coords)
        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        l2 = Lattice.from_lengths_and_angles([3,4,4], [100,100,70])
        struct2 = IStructure(l2, ["Si"] * 2, coords2)
        int_s = struct.interpolate(struct2, 2, interpolate_lattices=True)
        self.assertArrayAlmostEqual(struct.lattice.abc, 
                                    int_s[0].lattice.abc)
        self.assertArrayAlmostEqual(struct.lattice.angles, 
                                    int_s[0].lattice.angles)
        self.assertArrayAlmostEqual(struct2.lattice.abc, 
                                    int_s[2].lattice.abc)
        self.assertArrayAlmostEqual(struct2.lattice.angles, 
                                    int_s[2].lattice.angles)
        int_angles = [(a + struct2.lattice.angles[i]) / 2
                      for i, a in enumerate(struct.lattice.angles)]
        self.assertArrayAlmostEqual(int_angles,
                                    int_s[1].lattice.angles)
    
    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 = IStructure(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 = IStructure(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 = IStructure(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.assertArrayAlmostEqual(self.struct.distance_matrix, ans)
Esempio n. 47
0

def check_converged(crt_step, RSD, ASD):
    converged = False
    if crt_step >= min_step:
        if RSD <= min_RSD:
            if ASD <= min_ASD:
                converged = True
    if crt_step >= 300:
        converged = True

    return converged


if __name__ == "__main__":
    structure = IStructure.from_file(structure_filename)
    # -- Find neighboring specie distance
    sites = structure.sites
    specie_sites = [s for s in sites if str(s.specie) == specie]
    distance = []
    for specie_site in specie_sites:
        nbrs = structure.get_neighbors(specie_site, 5)
        nbrs = [nbr for nbr in nbrs if str(nbr[0].specie) == specie]
        for nbr in nbrs:
            distance.append(nbr[1])
    distance = np.array(distance)
    avg_specie_distance = distance.mean()

    working_dir = "%dK" % temp
    mkdir(working_dir)
    os.chdir(working_dir)
Esempio n. 48
0
class IStructureTest(PymatgenTest):

    def setUp(self):
        coords = [[0, 0, 0], [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 = IStructure(self.lattice, ["Si"] * 2, coords)
        self.assertEqual(len(self.struct), 2,
                         "Wrong number of sites in structure!")
        self.assertTrue(self.struct.is_ordered)
        self.assertTrue(self.struct.ntypesp == 1)
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0., 0, 0.0000001])
        self.assertRaises(StructureError, IStructure, self.lattice,
                          ["Si"] * 2, coords, True)
        self.propertied_structure = IStructure(
            self.lattice, ["Si"] * 2, coords,
            site_properties={'magmom': [5, -5]})

    def test_matches(self):
        ss = self.struct * 2
        self.assertTrue(ss.matches(self.struct))

    def test_bad_structure(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        coords.append([0.75, 0.5, 0.75])
        self.assertRaises(StructureError, IStructure, self.lattice,
                          ["Si"] * 3, coords, validate_proximity=True)
        #these shouldn't raise an error
        IStructure(self.lattice, ["Si"] * 2, coords[:2], True)
        IStructure(self.lattice, ["Si"], coords[:1], True)


    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 = IStructure(self.lattice, [{Specie('O', -2): 1.0},
                                      {Specie('Mg', 2): 0.8}], coords)
        self.assertEqual(s.composition.formula, 'Mg0.8 O1')

    def test_get_sorted_structure(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        s = IStructure(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)
        s = IStructure(self.lattice, ["Se", "C", "Se", "C"],
                       [[0] * 3, [0.5] * 3, [0.25] * 3, [0.75] * 3])
        self.assertEqual([site.specie.symbol
                          for site in s.get_sorted_structure()],
                         ["C", "C", "Se", "Se"])

    def test_get_spacegroup_data(self):
        self.assertEqual(self.struct.get_spacegroup_info(), ('Fd-3m', 227))

    def test_fractional_occupations(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        s = IStructure(self.lattice, [{'O': 1.0}, {'Mg': 0.8}],
                       coords)
        self.assertEqual(s.composition.formula, '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_as_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 = IStructure(self.lattice, [{si: 0.5, mn: 0.5}, {si: 0.5}],
                            coords)
        self.assertIn("lattice", struct.as_dict())
        self.assertIn("sites", struct.as_dict())
        d = self.propertied_structure.as_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 = IStructure(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.as_dict()
        self.assertEqual(d['sites'][0]['properties']['magmom'], 5)
        self.assertEqual(d['sites'][0]['species'][0]['properties']['spin'], 3)

        d = s.as_dict(0)
        self.assertNotIn("volume", d['lattice'])
        self.assertNotIn("xyz", d['sites'][0])

    def test_from_dict(self):

        d = self.propertied_structure.as_dict()
        s = IStructure.from_dict(d)
        self.assertEqual(s[0].magmom, 5)
        d = self.propertied_structure.as_dict(0)
        s2 = IStructure.from_dict(d)
        self.assertEqual(s, s2)

        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 = IStructure.from_dict(d)
        self.assertEqual(s[0].magmom, 5)
        self.assertEqual(s[0].specie.spin, 3)
        self.assertEqual(type(s), IStructure)

    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 = IStructure(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 = IStructure(self.lattice, ["Si"] * 2, coords)
        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si"] * 2, coords2)
        int_s = struct.interpolate(struct2, 10)
        for s in int_s:
            self.assertIsNotNone(s, "Interpolation Failed!")
            self.assertEqual(int_s[0].lattice, s.lattice)
        self.assertArrayEqual(int_s[1][1].frac_coords, [0.725, 0.5, 0.725])

        badlattice = [[1, 0.00, 0.00], [0, 1, 0.00], [0.00, 0, 1]]
        struct2 = IStructure(badlattice, ["Si"] * 2, coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)

        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        struct2 = IStructure(self.struct.lattice, ["Si", "Fe"], coords2)
        self.assertRaises(ValueError, struct.interpolate, struct2)

        # Test autosort feature.
        s1 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3),
                                       ["Fe"], [[0, 0, 0]])
        s1.pop(0)
        s2 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3),
                                       ["Fe"], [[0, 0, 0]])
        s2.pop(2)
        random.shuffle(s2)

        for s in s1.interpolate(s2, autosort_tol=0.5):
            self.assertArrayAlmostEqual(s1[0].frac_coords, s[0].frac_coords)
            self.assertArrayAlmostEqual(s1[2].frac_coords, s[2].frac_coords)

        # Make sure autosort has no effect on simpler interpolations,
        # and with shuffled sites.
        s1 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3),
                                       ["Fe"], [[0, 0, 0]])
        s2 = Structure.from_spacegroup("Fm-3m", Lattice.cubic(3),
                                       ["Fe"], [[0, 0, 0]])
        s2[0] = "Fe", [0.01, 0.01, 0.01]
        random.shuffle(s2)

        for s in s1.interpolate(s2, autosort_tol=0.5):
            self.assertArrayAlmostEqual(s1[1].frac_coords, s[1].frac_coords)
            self.assertArrayAlmostEqual(s1[2].frac_coords, s[2].frac_coords)
            self.assertArrayAlmostEqual(s1[3].frac_coords, s[3].frac_coords)

    def test_interpolate_lattice(self):
        coords = list()
        coords.append([0, 0, 0])
        coords.append([0.75, 0.5, 0.75])
        struct = IStructure(self.lattice, ["Si"] * 2, coords)
        coords2 = list()
        coords2.append([0, 0, 0])
        coords2.append([0.5, 0.5, 0.5])
        l2 = Lattice.from_lengths_and_angles([3,4,4], [100,100,70])
        struct2 = IStructure(l2, ["Si"] * 2, coords2)
        int_s = struct.interpolate(struct2, 2, interpolate_lattices=True)
        self.assertArrayAlmostEqual(struct.lattice.abc,
                                    int_s[0].lattice.abc)
        self.assertArrayAlmostEqual(struct.lattice.angles,
                                    int_s[0].lattice.angles)
        self.assertArrayAlmostEqual(struct2.lattice.abc,
                                    int_s[2].lattice.abc)
        self.assertArrayAlmostEqual(struct2.lattice.angles,
                                    int_s[2].lattice.angles)
        int_angles = [(a + struct2.lattice.angles[i]) / 2
                      for i, a in enumerate(struct.lattice.angles)]
        self.assertArrayAlmostEqual(int_angles,
                                    int_s[1].lattice.angles)

    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 = IStructure(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 = IStructure(Lattice.cubic(4.09), ["Li"] * 2, coords)
        bcc_prim = bcc_li.get_primitive_structure()
        self.assertEqual(len(bcc_prim), 1)
        self.assertAlmostEqual(bcc_prim.lattice.alpha, 109.47122, 3)

        coords = [[0] * 3, [0.5] * 3, [0.25] * 3, [0.26] * 3]
        s = IStructure(Lattice.cubic(4.09), ["Ag"] * 4, coords)
        self.assertEqual(len(s.get_primitive_structure()), 4)

    def test_primitive_cell_site_merging(self):
        l = Lattice.cubic(10)
        coords = [[0, 0, 0], [0, 0, 0.5],
                  [0, 0, 0.26], [0, 0, 0.74]]
        sp = ['Ag', 'Ag', 'Be', 'Be']
        s = Structure(l, sp, coords)
        dm = s.get_primitive_structure().distance_matrix
        self.assertArrayAlmostEqual(dm, [[0, 2.5], [2.5, 0]])

    def test_primitive_on_large_supercell(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)
        fcc_ag.make_supercell([2, 2, 2])
        fcc_ag_prim = fcc_ag.get_primitive_structure()
        self.assertEqual(len(fcc_ag_prim), 1)
        self.assertAlmostEqual(fcc_ag_prim.volume, 17.10448225)

    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_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 = IStructure(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
        nn = s.get_neighbors_in_shell(s[0].frac_coords, 2, 4,
                                       include_index=True)
        self.assertEqual(len(nn), 47)
        self.assertEqual(nn[0][-1], 0)

        r = random.uniform(3, 6)
        all_nn = s.get_all_neighbors(r, True)
        for i in range(len(s)):
            self.assertEqual(len(all_nn[i]), len(s.get_neighbors(s[i], r)))

        for site, nns in zip(s, all_nn):
            for nn in nns:
                self.assertTrue(nn[0].is_periodic_image(s[nn[2]]))
                d = sum((site.coords - nn[0].coords) ** 2) ** 0.5
                self.assertAlmostEqual(d, nn[1])

        s = Structure(Lattice.cubic(1), ['Li'], [[0,0,0]])
        s.make_supercell([2,2,2])
        self.assertEqual(sum(map(len, s.get_all_neighbors(3))), 976)


    def test_get_all_neighbors_outside_cell(self):
        s = Structure(Lattice.cubic(2), ['Li', 'Li', 'Li', 'Si'],
                      [[3.1] * 3, [0.11] * 3, [-1.91] * 3, [0.5] * 3])
        all_nn = s.get_all_neighbors(0.2, True)
        for site, nns in zip(s, all_nn):
            for nn in nns:
                self.assertTrue(nn[0].is_periodic_image(s[nn[2]]))
                d = sum((site.coords - nn[0].coords) ** 2) ** 0.5
                self.assertAlmostEqual(d, nn[1])
        self.assertEqual(list(map(len, all_nn)), [2, 2, 2, 0])

    def test_get_dist_matrix(self):
        ans = [[0., 2.3516318],
               [2.3516318, 0.]]
        self.assertArrayAlmostEqual(self.struct.distance_matrix, ans)

    def test_to_from_file_string(self):
        for fmt in ["cif", "json", "poscar", "cssr"]:
            s = self.struct.to(fmt=fmt)
            self.assertIsNotNone(s)
            ss = IStructure.from_str(s, fmt=fmt)
            self.assertArrayAlmostEqual(
                ss.lattice.lengths_and_angles,
                self.struct.lattice.lengths_and_angles, decimal=5)
            self.assertArrayAlmostEqual(ss.frac_coords, self.struct.frac_coords)
            self.assertIsInstance(ss, IStructure)

        self.struct.to(filename="POSCAR.testing")
        self.assertTrue(os.path.exists("POSCAR.testing"))
        os.remove("POSCAR.testing")

        self.struct.to(filename="Si_testing.yaml")
        self.assertTrue(os.path.exists("Si_testing.yaml"))
        s = Structure.from_file("Si_testing.yaml")
        self.assertEqual(s, self.struct)
        os.remove("Si_testing.yaml")
Esempio n. 49
0
    return batch_x, batch_y


if __name__ == "__main__":
    radius = 3
    max_neighbor_num = 10
    training = 0.9
    test = 0.1

    df = pd.read_csv("./Data/metal-alloy-db.v1/00Total_DB.csv")
    # df = df.sample(n=len(df))
    df = df.sample(n=500)

    cifs = "./Data/metal-alloy-db.v1/" + df['DBname'] + ".cif"
    structures = [IStructure.from_file(cif) for cif in cifs]

    encoded_structures = [structure_encoder(structure, radius, max_neighbor_num) for structure in structures]
    x_data = np.array(encoded_structures)
    x_data = np.expand_dims(x_data, axis=4)

    formation_energy = df['FormationEnergy']
    y_normalization = False
    if y_normalization:
        mean = formation_energy.mean()
        std = formation_energy.std()
        norm_form_energy = (df['FormationEnergy'] - mean) / std

        def norm_back(val, mean, std):
            return val * std + mean
        y_data = [[val] for val in norm_form_energy]