def setUp(self):
self.factory = PUFoamFactory(plugin={'id': '0', 'name': 'test'})
self.data_source = self.factory.create_data_source()
self.model = self.factory.create_model()
self.rectangle = RectangularMesh(length=10,
width=2,
height=20,
resolution=5,
units="cm")
self.cylinder = CylinderMesh(radius=6, resolution=10, units="cm")
self.complex = ComplexMesh(source_path=get("cone.stl"),
inside_location=[0, 0, 2.5],
units="cm")
def _parse_mold_data(self, geo_data, mesh_data, fill_data):
mesh_data = self._parse_mesh_data(mesh_data)
fill_data = self._parse_fill_data(fill_data)
geo = geo_data.get(oclass=emmo.TwoManifold)
if geo:
geo_file = geo_data.get(oclass=emmo.File)
if geo[0].is_a(emmo.Rectangle) and not geo_file:
geo_data = self._parse_rectangle_data(geo_data)
self._geometry = RectangularMesh(
**geo_data, **mesh_data, **fill_data
)
elif geo[0].is_a(emmo.Cylinder) and not geo_file:
geo_data = self._parse_cylinder_data(geo_data)
self._geometry = CylinderMesh(
**geo_data, **mesh_data, **fill_data
)
elif geo[0].is_a(emmo.Complex) or geo_file:
geo_data = {
'source_path': self._parse_geometry_file(geo_file[0]),
'units': self._get_si_unit(geo_data)
}
self._geometry = ComplexMesh(
**mesh_data, **geo_data, **fill_data
)
else:
raise ValueError(
'Target geometry not recognized or geometry file not found'
)
def setUp(self):
# Define rectangular mesh and its properties
self.rectangular = RectangularMesh(length=20,
width=10,
height=150,
resolution=4,
filling_fraction=0.5,
units="mm")
self.rectangular_block_extent = extent(max_extent=[20, 10, 150])
self.rectangular_filling_extent = [[0, 0, 0], [0.02, 0.01, 0.075]]
self.rectangular_ncells = [80, 40, 600]
self.rectangular_volume = 30000
# Define cylindrical mesh and its properties
self.cylinder = CylinderMesh(radius=5,
height=20,
resolution=7,
filling_fraction=0.5,
units="cm")
self.cylinder_stl_extent = extent([-0.05, -0.05, 0], [0.05, 0.05, 0.2])
self.cylinder_block_extent = extent([-5, -5, 0], [5, 5, 20])
self.cylinder_filling_extent = [0.05, 0.1]
self.cylinder_ncells = [70, 70, 140]
self.cylinder_location = [0, 0, 0.1]
self.cylinder_volume = 25 * 20 * np.pi
# Define complex mesh and its properties
self.complex_radius = 5
self.complex_height = 10
self.complex_resolution = 10
self.complex = ComplexMesh(source_path=get("cone.stl"),
inside_location=[0, 0, 5],
resolution=10,
filling_fraction=0.5,
units="cm")
self.complex_stl_extent = extent([-0.05, -0.05, 0], [0.05, 0.05, 0.1])
self.complex_block_extent = extent([-5, -5, 0], [5, 5, 10])
self.complex_filling_extent = [[-0.05, -0.05, 0], [0.05, 0.05, 0.05]]
self.complex_ncells = [100, 100, 100]
self.complex_location = [0, 0, 0.05]
self.complex_cutoff = 0.5
self.complex_volume = 1 / 3 * (np.pi * self.complex_radius**2 *
self.complex_height)
self.complex_volume_cutoff = 1 / 3 * (
self.complex_radius *
(1 - self.complex_cutoff))**2 * np.pi * (self.complex_height *
self.complex_cutoff)
def create_complex_mesh(self, model):
"""Placeholder for a function that stores the link
to an .stl-file for an OpenFOAM simulation
"""
mesh = ComplexMesh(units=model.units,
resolution=model.resolution,
source_path=model.path,
inside_location=model.inside_location)
return mesh
def setUp(self):
# Define rectangular mesh and its properties
self.rectangular = RectangularMesh(
x_length=0.02,
y_length=0.01,
z_length=0.15,
resolution=0.001,
filling_fraction=0.5,
units="m"
)
self.rectangular_max_extent = extent(
max_extent=[0.02, 0.01, 0.15]
)
self.rectangular_filling_extent = extent(
max_extent=[0.02, 0.01, 0.075]
)
self.rectangular_inside_location = [0.01, 0.005, 0.075]
self.rectangular_volume = 3e-5
self.rectangular_stl_ref = os.path.join(
path, 'rectangle_ref.stl'
)
self.rectangular_geo_ref = os.path.join(
path, 'rectangle_ref.geo'
)
# Define cylindrical mesh and its properties
self.cylinder = CylinderMesh(
xy_radius=0.05,
z_length=0.2,
resolution=0.0014,
filling_fraction=0.5,
units="m"
)
self.cylinder_max_extent = extent(
[-0.05, -0.05, 0], [0.05, 0.05, 0.2]
)
self.cylinder_filling_extent = extent(
[-0.05, -0.05, 0], [0.05, 0.05, 0.1]
)
self.cylinder_inside_location = [0, 0, 0.1]
self.cylinder_volume = 0.025**2*0.2*np.pi
self.cylinder_stl_ref = os.path.join(
path, 'cylinder_ref.stl'
)
self.cylinder_geo_ref = os.path.join(
path, 'cylinder_ref.geo'
)
# Define complex mesh and its properties
self.complex_xy_radius = 5
self.complex_z_length = 10
self.complex_cutoff = 0.5
self.complex = ComplexMesh(
source_path=os.path.join(path, "cone.stl"),
inside_location=[0.0, 0.0, 5.0],
filling_fraction=0.5,
units="mm"
)
self.complex_max_extent = extent(
[-5.0, -5.0, 0.0], [5.0, 5.0, 10.0]
)
self.complex_filling_extent = extent(
[-5.0, -5.0, 0.0], [5.0, 5.0, 5.0]
)
self.complex_inside_location = [0.0, 0.0, 5.0]
self.complex_volume = 1/3*(np.pi*5**2*10)
self.complex_volume_cutoff = \
1/3*(5/10*10*0.5)**2*np.pi*(10*0.5)
class TestMeshes(TestCase):
def setUp(self):
# Define rectangular mesh and its properties
self.rectangular = RectangularMesh(
x_length=0.02,
y_length=0.01,
z_length=0.15,
resolution=0.001,
filling_fraction=0.5,
units="m"
)
self.rectangular_max_extent = extent(
max_extent=[0.02, 0.01, 0.15]
)
self.rectangular_filling_extent = extent(
max_extent=[0.02, 0.01, 0.075]
)
self.rectangular_inside_location = [0.01, 0.005, 0.075]
self.rectangular_volume = 3e-5
self.rectangular_stl_ref = os.path.join(
path, 'rectangle_ref.stl'
)
self.rectangular_geo_ref = os.path.join(
path, 'rectangle_ref.geo'
)
# Define cylindrical mesh and its properties
self.cylinder = CylinderMesh(
xy_radius=0.05,
z_length=0.2,
resolution=0.0014,
filling_fraction=0.5,
units="m"
)
self.cylinder_max_extent = extent(
[-0.05, -0.05, 0], [0.05, 0.05, 0.2]
)
self.cylinder_filling_extent = extent(
[-0.05, -0.05, 0], [0.05, 0.05, 0.1]
)
self.cylinder_inside_location = [0, 0, 0.1]
self.cylinder_volume = 0.025**2*0.2*np.pi
self.cylinder_stl_ref = os.path.join(
path, 'cylinder_ref.stl'
)
self.cylinder_geo_ref = os.path.join(
path, 'cylinder_ref.geo'
)
# Define complex mesh and its properties
self.complex_xy_radius = 5
self.complex_z_length = 10
self.complex_cutoff = 0.5
self.complex = ComplexMesh(
source_path=os.path.join(path, "cone.stl"),
inside_location=[0.0, 0.0, 5.0],
filling_fraction=0.5,
units="mm"
)
self.complex_max_extent = extent(
[-5.0, -5.0, 0.0], [5.0, 5.0, 10.0]
)
self.complex_filling_extent = extent(
[-5.0, -5.0, 0.0], [5.0, 5.0, 5.0]
)
self.complex_inside_location = [0.0, 0.0, 5.0]
self.complex_volume = 1/3*(np.pi*5**2*10)
self.complex_volume_cutoff = \
1/3*(5/10*10*0.5)**2*np.pi*(10*0.5)
def test_rectangular(self):
with TemporaryDirectory() as temp_dir:
stl_path = os.path.join(temp_dir, 'new_surface.stl')
geo_path = os.path.join(temp_dir, 'new_surface.geo')
self.rectangular.write_mesh(temp_dir)
self.assertTrue(os.path.exists(stl_path))
self.assertTrue(os.path.exists(geo_path))
for ax in self.rectangular_max_extent.keys():
for direction in self.rectangular_max_extent[ax].keys():
self.assertEqual(
self.rectangular.max_extent[ax][direction],
self.rectangular_max_extent[ax][direction]
)
self.assertEqual(
self.rectangular.filling_extent[ax][direction],
self.rectangular_filling_extent[ax][direction]
)
self.assertListEqual(
self.rectangular.inside_location,
self.rectangular_inside_location
)
self.assertEqual(
self.rectangular_volume,
self.rectangular.volume
)
self.compare_files(
stl_path, self.rectangular_stl_ref
)
self.compare_files(
geo_path, self.rectangular_geo_ref
)
def test_cylinder(self):
with TemporaryDirectory() as temp_dir:
stl_path = os.path.join(temp_dir, 'new_surface.stl')
geo_path = os.path.join(temp_dir, 'new_surface.geo')
self.cylinder.write_mesh(temp_dir)
self.assertTrue(os.path.exists(stl_path))
self.assertTrue(os.path.exists(geo_path))
for ax in self.cylinder_max_extent.keys():
for direction in self.cylinder_max_extent[ax].keys():
self.assertEqual(
self.cylinder.max_extent[ax][direction],
self.cylinder_max_extent[ax][direction]
)
self.assertEqual(
self.cylinder.filling_extent[ax][direction],
self.cylinder_filling_extent[ax][direction]
)
self.assertListEqual(
self.cylinder.inside_location,
self.cylinder_inside_location
)
self.assertAlmostEqual(
self.cylinder_volume,
self.cylinder.volume,
places=1
)
self.compare_files(
stl_path, self.cylinder_stl_ref
)
self.compare_files(
geo_path, self.cylinder_geo_ref
)
def test_complex(self):
warnings.warn(
"The destinction between true and "
"apparent filling_fractions is currently "
"not supported for ComplexMesh-geometries"
)
# NOTE: in case that ComplexMesh::cutoff_volume() will
# deliver reasonable values in the future, please uncomment
# the following code:
# self.assertAlmostEqual(
# self.complex_volume_cutoff,
# self.complex.cutoff_volume(self.complex_cutoff),
# delta=3
# )
self.complex.inspect_file()
for ax in self.complex_max_extent.keys():
for direction in self.complex_max_extent[ax].keys():
self.assertAlmostEqual(
self.complex.max_extent[ax][direction],
self.complex_max_extent[ax][direction],
)
self.assertAlmostEqual(
self.complex.filling_extent[ax][direction],
self.complex_filling_extent[ax][direction],
)
self.assertListEqual(
self.complex.inside_location,
self.complex_inside_location
)
self.assertAlmostEqual(
self.complex_volume,
self.complex.volume,
delta=3
)
def compare_files(self, target_path, ref_path):
with open(target_path, "r") as target, \
open(ref_path, "r") as ref:
target_text = "".join(target.read().split())
ref_text = "".join(ref.read().split())
self.assertEqual(target_text, ref_text)
class TestMeshes(TestCase):
def setUp(self):
# Define rectangular mesh and its properties
self.rectangular = RectangularMesh(length=20,
width=10,
height=150,
resolution=4,
filling_fraction=0.5,
units="mm")
self.rectangular_block_extent = extent(max_extent=[20, 10, 150])
self.rectangular_filling_extent = [[0, 0, 0], [0.02, 0.01, 0.075]]
self.rectangular_ncells = [80, 40, 600]
self.rectangular_volume = 30000
# Define cylindrical mesh and its properties
self.cylinder = CylinderMesh(radius=5,
height=20,
resolution=7,
filling_fraction=0.5,
units="cm")
self.cylinder_stl_extent = extent([-0.05, -0.05, 0], [0.05, 0.05, 0.2])
self.cylinder_block_extent = extent([-5, -5, 0], [5, 5, 20])
self.cylinder_filling_extent = [0.05, 0.1]
self.cylinder_ncells = [70, 70, 140]
self.cylinder_location = [0, 0, 0.1]
self.cylinder_volume = 25 * 20 * np.pi
# Define complex mesh and its properties
self.complex_radius = 5
self.complex_height = 10
self.complex_resolution = 10
self.complex = ComplexMesh(source_path=get("cone.stl"),
inside_location=[0, 0, 5],
resolution=10,
filling_fraction=0.5,
units="cm")
self.complex_stl_extent = extent([-0.05, -0.05, 0], [0.05, 0.05, 0.1])
self.complex_block_extent = extent([-5, -5, 0], [5, 5, 10])
self.complex_filling_extent = [[-0.05, -0.05, 0], [0.05, 0.05, 0.05]]
self.complex_ncells = [100, 100, 100]
self.complex_location = [0, 0, 0.05]
self.complex_cutoff = 0.5
self.complex_volume = 1 / 3 * (np.pi * self.complex_radius**2 *
self.complex_height)
self.complex_volume_cutoff = 1 / 3 * (
self.complex_radius *
(1 - self.complex_cutoff))**2 * np.pi * (self.complex_height *
self.complex_cutoff)
def test_rectangular(self):
self.rectangular.write_mesh()
for ax in self.rectangular_block_extent.keys():
for direction in self.rectangular_block_extent[ax].keys():
self.assertEqual(
self.rectangular.blockmesh_extent[ax][direction],
self.rectangular_block_extent[ax][direction])
self.assertListEqual(self.rectangular.ncells, self.rectangular_ncells)
self.assertListEqual(self.rectangular_filling_extent,
self.rectangular.filling_extent)
self.assertEqual(self.rectangular_volume, self.rectangular.volume)
def test_cylinder(self):
with TemporaryDirectory() as temp_dir:
file_path = os.path.join(temp_dir, 'new_surface.stl')
self.cylinder.write_mesh(temp_dir)
self.assertTrue(os.path.exists(file_path))
for ax in self.cylinder_stl_extent.keys():
for direction in self.cylinder_stl_extent[ax].keys():
self.assertEqual(self.cylinder.stl_extent[ax][direction],
self.cylinder_stl_extent[ax][direction])
self.assertEqual(
self.cylinder.blockmesh_extent[ax][direction],
self.cylinder_block_extent[ax][direction])
self.assertListEqual(self.cylinder.ncells, self.cylinder_ncells)
self.assertListEqual(self.cylinder.inside_location,
self.cylinder_location)
self.assertListEqual(self.cylinder_filling_extent,
self.cylinder.filling_extent)
self.assertAlmostEqual(self.cylinder_volume,
self.cylinder.volume,
places=1)
def test_complex(self):
warnings.warn("The destinction between true and "
"apparent filling_fractions is currently "
"not supported for ComplexMesh-geometries")
# NOTE: in case that ComplexMesh::cutoff_volume() will
# deliver reasonable values in the future, please uncomment
# the following code:
# self.assertAlmostEqual(
# self.complex_volume_cutoff,
# self.complex.cutoff_volume(self.complex_cutoff),
# delta=3
# )
with TemporaryDirectory() as temp_dir:
file_path = os.path.join(temp_dir, 'new_surface.stl')
self.complex.write_mesh(temp_dir)
self.assertTrue(os.path.exists(file_path))
for ax in self.complex_stl_extent.keys():
for direction in self.complex_stl_extent[ax].keys():
self.assertAlmostEqual(
self.complex.stl_extent[ax][direction],
self.complex_stl_extent[ax][direction],
)
self.assertAlmostEqual(
self.complex.blockmesh_extent[ax][direction],
self.complex_block_extent[ax][direction])
self.assertListEqual(self.complex.ncells, self.complex_ncells)
self.assertListEqual(self.complex.inside_location,
self.complex_location)
self.assertListEqual(self.complex.filling_extent,
self.complex_filling_extent)
self.assertAlmostEqual(self.complex_volume,
self.complex.volume,
delta=3)
class TestPUFoamDataSource(TestCase):
def setUp(self):
self.factory = PUFoamFactory(plugin={'id': '0', 'name': 'test'})
self.data_source = self.factory.create_data_source()
self.model = self.factory.create_model()
self.rectangle = RectangularMesh(length=10,
width=2,
height=20,
resolution=5,
units="cm")
self.cylinder = CylinderMesh(radius=6, resolution=10, units="cm")
self.complex = ComplexMesh(source_path=get("cone.stl"),
inside_location=[0, 0, 2.5],
units="cm")
def test__calculate_filling_fraction(self):
formulation = ProbeFormulation()
formulation.chemicals = [formulation.chemicals[2]]
self.model.use_mass = True
foam_volume = 1e-4
rectangle_volume = 4e-4
cylinder_volume = 1.1304e-3
complex_volume = 2.6180e-4
filling_fraction = self.data_source._calculate_filling_fraction(
self.model, formulation, self.rectangle)
self.assertAlmostEqual(foam_volume / rectangle_volume,
filling_fraction)
filling_fraction = self.data_source._calculate_filling_fraction(
self.model, formulation, self.cylinder)
self.assertAlmostEqual(foam_volume / cylinder_volume,
filling_fraction,
delta=1e-4)
self.model.foam_mass = 394.78
self.model.foam_volume = 0.5
foam_volume = 3.9478e-4
filling_fraction = self.data_source._calculate_filling_fraction(
self.model, formulation, self.complex)
self.assertAlmostEqual(foam_volume / complex_volume,
filling_fraction,
delta=0.01)
warnings.warn("The destinction between true and apparent "
"filling_fractions is currently not supported "
"for ComplexMesh-geometries.")
# NOTE: in case that ComplexMesh::cutoff_volume() will
# deliver reasonable values in the future, please delete
# the assertion before the warning and uncomment the
# following code:
# self.assertAlmostEqual(
# foam_volume/complex_volume,
# filling_fraction,
# delta=0.01
# )
self.model.use_mass = False
filling_fraction = self.data_source._calculate_filling_fraction(
self.model, formulation, self.rectangle)
self.assertAlmostEqual(self.model.foam_volume, filling_fraction)
filling_fraction = self.data_source._calculate_filling_fraction(
self.model, formulation, self.cylinder)
self.assertAlmostEqual(self.model.foam_volume, filling_fraction)
filling_fraction = self.data_source._calculate_filling_fraction(
self.model, formulation, self.complex)
self.assertAlmostEqual(self.model.foam_volume, filling_fraction)
def test__update_simulation_data(self):
is_updated = self.data_source._update_simulation_data(
DataValue(type="A_OH", value=2))
self.assertTrue(is_updated)
self.assertEqual(
2, self.data_source.data_dicts[0].data["GellingConstants"]["A_OH"])
is_updated = self.data_source._update_simulation_data(
DataValue(type="B_OH", value=2))
self.assertFalse(is_updated)
def test__prepare_mesh(self):
def return_url_name(url, **kwargs):
return ProbeResponse(text=url)
with TemporaryDirectory() as temp_dir:
self.model.simulation_directory = temp_dir
self.data_source.update_mesh_data(self.rectangle, self.model)
with mock.patch('requests.post') as mock_post, \
mock.patch('requests.get') as mock_get:
mock_post.side_effect = return_url_name
mock_get.side_effect = return_url_name
session = PUFoamSession()
self.assertEqual(
'http://0.0.0.0:5000/block_mesh',
self.data_source._prepare_mesh(session, self.model).text)
self.data_source.update_mesh_data(self.cylinder, self.model)
with mock.patch('requests.post') as mock_post, \
mock.patch('requests.get') as mock_get:
mock_post.side_effect = return_url_name
mock_get.side_effect = return_url_name
session = PUFoamSession()
self.assertEqual(
'http://0.0.0.0:5000/transform/constant/triSurface',
self.data_source._prepare_mesh(session, self.model).text)
self.data_source.update_mesh_data(self.complex, self.model)
with mock.patch('requests.post') as mock_post, \
mock.patch('requests.get') as mock_get:
mock_post.side_effect = return_url_name
mock_get.side_effect = return_url_name
session = PUFoamSession()
self.assertEqual(
'http://0.0.0.0:5000/transform/constant/triSurface',
self.data_source._prepare_mesh(session, self.model).text)
def test_update_formulation_data(self):
formulation = ProbeFormulation()
data_dict = self.data_source.data_dicts[0]
self.data_source.update_formulation_data(formulation)
self.assertAlmostEqual(1118.44312716,
data_dict.data["GellingConstants"]["initCOH"])
self.assertAlmostEqual(11184.43127166,
data_dict.data["GellingConstants"]["initCNCO"])
self.assertAlmostEqual(50951.29801538,
data_dict.data["GellingConstants"]["initCW"])
self.assertAlmostEqual(
0.00050125313,
data_dict.data["GenericConstants"]["initBlowingAgent"])
self.assertAlmostEqual(
2231.29403869, data_dict.data["GenericConstants"]["rhoPolymer"])
self.assertAlmostEqual(
10000, data_dict.data["GenericConstants"]["rhoBlowingAgent"])
def test_update_mesh_data(self):
with TemporaryDirectory() as temp_dir:
self.model.simulation_directory = temp_dir
blockmesh = self.data_source.data_dicts[1]
snappyhex = self.data_source.data_dicts[4]
self.data_source.update_mesh_data(self.rectangle, self.model)
for ax in self.rectangle.blockmesh_extent.keys():
for direction in self.rectangle.blockmesh_extent[ax].keys():
self.assertEqual(
self.rectangle.blockmesh_extent[ax][direction],
blockmesh.data[ax + direction])
self.assertListEqual(self.rectangle.ncells,
blockmesh.data["blocks"][0][2])
self.assertEqual(0.01, blockmesh.data["convertToMeters"])
self.rectangle.units = 'mm'
self.data_source.update_mesh_data(self.rectangle, self.model)
self.assertEqual(0.001, blockmesh.data["convertToMeters"])
self.rectangle.units = 'm'
self.data_source.update_mesh_data(self.rectangle, self.model)
self.assertEqual(1.0, blockmesh.data["convertToMeters"])
self.data_source.update_mesh_data(self.cylinder, self.model)
box = snappyhex.data['geometry']["refinementBox"]
loc = snappyhex.data['castellatedMeshControls']['locationInMesh']
for num, ax in enumerate(self.cylinder.blockmesh_extent.keys()):
for direction in self.cylinder.blockmesh_extent[ax].keys():
self.assertEqual(
self.cylinder.blockmesh_extent[ax][direction],
blockmesh.data[ax + direction])
self.assertEqual(self.cylinder.stl_extent[ax][direction],
box[direction][num])
self.assertListEqual(self.cylinder.inside_location, loc)
self.assertListEqual(self.cylinder.ncells,
blockmesh.data["blocks"][0][2])
self.assertListEqual(self.cylinder.ncells,
blockmesh.data["blocks"][0][2])
self.assertEqual(0.01, blockmesh.data["convertToMeters"])
self.cylinder.units = 'mm'
self.data_source.update_mesh_data(self.cylinder, self.model)
self.assertEqual(0.001, blockmesh.data["convertToMeters"])
self.cylinder.units = 'm'
self.data_source.update_mesh_data(self.cylinder, self.model)
self.assertEqual(1.0, blockmesh.data["convertToMeters"])
self.data_source.update_mesh_data(self.complex, self.model)
box = snappyhex.data['geometry']["refinementBox"]
loc = snappyhex.data['castellatedMeshControls']['locationInMesh']
for num, ax in enumerate(self.complex.blockmesh_extent.keys()):
for direction in self.complex.blockmesh_extent[ax].keys():
self.assertEqual(
self.complex.blockmesh_extent[ax][direction],
blockmesh.data[ax + direction])
self.assertEqual(self.complex.stl_extent[ax][direction],
box[direction][num])
self.assertListEqual(self.complex.inside_location, loc)
self.assertListEqual(self.complex.ncells,
blockmesh.data["blocks"][0][2])
self.assertEqual(0.01, blockmesh.data["convertToMeters"])
self.complex.units = 'mm'
self.data_source.update_mesh_data(self.complex, self.model)
self.assertEqual(0.001, blockmesh.data["convertToMeters"])
self.complex.units = 'm'
self.data_source.update_mesh_data(self.complex, self.model)
self.assertEqual(1.0, blockmesh.data["convertToMeters"])
def test_update_control_data(self):
self.model.time_steps = 100
self.data_source.update_control_data(self.model)
self.assertEqual(100, self.data_source.data_dicts[2].data["endTime"])
def test_update_fields_data(self):
fraction = 0.2
with TemporaryDirectory() as temp_dir:
fields_dict = self.data_source.data_dicts[3]
self.rectangle.write_mesh()
self.cylinder.write_mesh(temp_dir)
self.complex.write_mesh(temp_dir)
self.data_source.update_fields_data(self.rectangle, fraction)
self.assertListEqual(
[[0, 0, 0],
[
self.rectangle.length * self.rectangle.convert_to_meters,
self.rectangle.width * self.rectangle.convert_to_meters,
round(
self.rectangle.height *
self.rectangle.convert_to_meters * fraction, 2)
]], fields_dict.regions[0]['boxToCell']['box'])
self.data_source.update_fields_data(self.cylinder, fraction)
self.assertEqual(
self.cylinder.radius * self.cylinder.convert_to_meters,
fields_dict.regions[1]['cylinderToCell']['radius'])
self.assertEqual(
fraction * self.cylinder.height *
self.cylinder.convert_to_meters,
fields_dict.regions[1]['cylinderToCell']['p2'][-1])
self.data_source.update_fields_data(self.complex, fraction)
self.assertListEqual([
[self.complex.stl_extent[ax]["min"] for ax in ["x", "y", "z"]],
[
self.complex.stl_extent[ax]["max"] * fraction
if ax == "z" else self.complex.stl_extent[ax]["max"]
for ax in ["x", "y", "z"]
]
], fields_dict.regions[0]['boxToCell']['box'])
def test_update_reaction_data(self):
reaction_dict = self.data_source.data_dicts[0]
mapping = {"A_OH": 10, "E_OH": 5, "deltaOH": 1, "gellingPoint": 2.5}
self.data_source.update_reaction_data(mapping)
self.assertEqual(10, reaction_dict.data["GellingConstants"]["A_OH"])
self.assertEqual(5, reaction_dict.data["GellingConstants"]["E_OH"])
self.assertEqual(1, reaction_dict.data["EnthalpyConstants"]["deltaOH"])
self.assertEqual(
2.5, reaction_dict.data["GellingConstants"]["gellingPoint"])
mapping = {"A_W": 10, "E_W": 5, "deltaW": 1, "latentHeat": 2.5}
self.data_source.update_reaction_data(mapping)
self.assertEqual(10, reaction_dict.data["BlowingConstants"]["A_W"])
self.assertEqual(5, reaction_dict.data["BlowingConstants"]["E_W"])
self.assertEqual(1, reaction_dict.data["EnthalpyConstants"]["deltaW"])
self.assertEqual(2.5,
reaction_dict.data["EnthalpyConstants"]["latentHeat"])
def test_verify(self):
errors = self.model.verify()
self.assertEqual(2, len(errors))
self.model.foam_volume = 2
errors = self.model.verify()
self.assertEqual(3, len(errors))
self.assertEqual("PUFoam initial volume must be between 0 - 1",
errors[-1].global_error)
self.model.foam_volume = -1
errors = self.model.verify()
self.assertEqual(3, len(errors))
self.assertEqual("PUFoam initial volume must be between 0 - 1",
errors[-1].global_error)
def test_change_slots(self):
slots = self.data_source.slots(self.model)
self.assertEqual(4, len(slots[0]))
self.assertEqual(1, len(slots[1]))
self.model.input_method = 'Parameter'
slots = self.data_source.slots(self.model)
self.assertEqual(5, len(slots[0]))
self.assertEqual(1, len(slots[1]))
self.assertEqual('FILLING_FRACTION', slots[0][-1].type)
self.model.use_mass = True
slots = self.data_source.slots(self.model)
self.assertEqual(5, len(slots[0]))
self.assertEqual(1, len(slots[1]))
self.assertEqual('MASS', slots[0][-1].type)