Put phase-field test into function -> otherwise test is executed during py.test collection phase

lbmpy_tests/phasefield_allen_cahn/test_codegen_3D.py

-from lbmpy.phasefield_allen_cahn.analytical import analytic_rising_speed
-from lbmpy.phasefield_allen_cahn.parameter_calculation import calculate_dimensionless_rising_bubble, \
-    calculate_parameters_rti
-from pystencils import fields, AssignmentCollection
-from pystencils.simp import sympy_cse
+from collections import OrderedDict
+
+import numpy as np
 
 from lbmpy.creationfunctions import create_lb_method, create_lb_update_rule
-from lbmpy.stencils import get_stencil
 from lbmpy.methods.creationfunctions import create_with_discrete_maxwellian_eq_moments
-
-from lbmpy.phasefield_allen_cahn.kernel_equations import initializer_kernel_hydro_lb, \
-    initializer_kernel_phase_field_lb, get_collision_assignments_hydro, interface_tracking_force, hydrodynamic_force
+from lbmpy.phasefield_allen_cahn.analytical import analytic_rising_speed
 from lbmpy.phasefield_allen_cahn.force_model import MultiphaseForceModel
+from lbmpy.phasefield_allen_cahn.kernel_equations import (
+    get_collision_assignments_hydro, hydrodynamic_force, initializer_kernel_hydro_lb, initializer_kernel_phase_field_lb,
+    interface_tracking_force)
+from lbmpy.phasefield_allen_cahn.parameter_calculation import (
+    calculate_dimensionless_rising_bubble, calculate_parameters_rti)
+from lbmpy.stencils import get_stencil
+from pystencils import AssignmentCollection, fields
+from pystencils.simp import sympy_cse
 
-from collections import OrderedDict
-
-import numpy as np
-
-stencil_phase = get_stencil("D3Q15")
-stencil_hydro = get_stencil("D3Q27")
-assert (len(stencil_phase[0]) == len(stencil_hydro[0]))
-dimensions = len(stencil_hydro[0])
-
-parameters = calculate_dimensionless_rising_bubble(reference_time=18000,
-                                                   density_heavy=1.0,
-                                                   bubble_radius=16,
-                                                   bond_number=30,
-                                                   reynolds_number=420,
-                                                   density_ratio=1000,
-                                                   viscosity_ratio=100)
-
-np.isclose(parameters["density_light"], 0.001, rtol=1e-05, atol=1e-08, equal_nan=False)
-np.isclose(parameters["gravitational_acceleration"], -9.876543209876543e-08, rtol=1e-05, atol=1e-08, equal_nan=False)
-
-parameters = calculate_parameters_rti(reference_length=128,
-                                      reference_time=18000,
-                                      density_heavy=1.0,
-                                      capillary_number=9.1,
-                                      reynolds_number=128,
-                                      atwood_number=1.0,
-                                      peclet_number=744,
-                                      density_ratio=3,
-                                      viscosity_ratio=3)
-
-np.isclose(parameters["density_light"], 1/3, rtol=1e-05, atol=1e-08, equal_nan=False)
-np.isclose(parameters["gravitational_acceleration"], -3.9506172839506174e-07, rtol=1e-05, atol=1e-08, equal_nan=False)
-np.isclose(parameters["mobility"], 0.0012234169653524492, rtol=1e-05, atol=1e-08, equal_nan=False)
-
-rs = analytic_rising_speed(1-6, 20, 0.01)
-np.isclose(rs, 16666.666666666668, rtol=1e-05, atol=1e-08, equal_nan=False)
-
-density_liquid = 1.0
-density_gas = 0.001
-surface_tension = 0.0001
-M = 0.02
-
-# phase-field parameter
-drho3 = (density_liquid - density_gas) / 3
-# interface thickness
-W = 5
-# coefficient related to surface tension
-beta = 12.0 * (surface_tension / W)
-# coefficient related to surface tension
-kappa = 1.5 * surface_tension * W
-# relaxation rate allen cahn (h)
-w_c = 1.0 / (0.5 + (3.0 * M))
-
-# fields
-u = fields("vel_field(" + str(dimensions) + "): [" + str(dimensions) + "D]", layout='fzyx')
-C = fields("phase_field: [" + str(dimensions) + "D]", layout='fzyx')
-force = fields("force(" + str(dimensions) + "): [" + str(dimensions) + "D]", layout='fzyx')
-
-h = fields("lb_phase_field(" + str(len(stencil_phase)) + "): [" + str(dimensions) + "D]", layout='fzyx')
-h_tmp = fields("lb_phase_field_tmp(" + str(len(stencil_phase)) + "): [" + str(dimensions) + "D]", layout='fzyx')
-
-g = fields("lb_velocity_field(" + str(len(stencil_hydro)) + "): [" + str(dimensions) + "D]", layout='fzyx')
-g_tmp = fields("lb_velocity_field_tmp(" + str(len(stencil_hydro)) + "): [" + str(dimensions) + "D]", layout='fzyx')
-
-# calculate the relaxation rate for the hydro lb as well as the body force
-density = density_gas + C.center * (density_liquid - density_gas)
-# force acting on all phases of the model
-body_force = np.array([0, 1e-6, 0])
-
-relaxation_time = 0.03 + 0.5
-relaxation_rate = 1.0 / relaxation_time
-
-method_phase = create_lb_method(stencil=stencil_phase, method='srt', relaxation_rate=w_c, compressible=True)
-
-mrt = create_lb_method(method="mrt", weighted=False, stencil=stencil_hydro,
-                       relaxation_rates=[1, 1, relaxation_rate, 1, 1, 1, 1])
-rr_dict = OrderedDict(zip(mrt.moments, mrt.relaxation_rates))
-
-method_hydro = create_with_discrete_maxwellian_eq_moments(stencil_hydro, rr_dict, compressible=False)
-
-# create the kernels for the initialization of the g and h field
-h_updates = initializer_kernel_phase_field_lb(h, C, u, method_phase, W)
-g_updates = initializer_kernel_hydro_lb(g, u, method_hydro)
-
-force_h = [f / 3 for f in interface_tracking_force(C, stencil_phase, W)]
-force_model_h = MultiphaseForceModel(force=force_h)
-
-force_g = hydrodynamic_force(g, C, method_hydro, relaxation_time, density_liquid, density_gas, kappa, beta, body_force)
-force_model_g = MultiphaseForceModel(force=force_g, rho=density)
-
-h_tmp_symbol_list = [h_tmp.center(i) for i, _ in enumerate(stencil_phase)]
-sum_h = np.sum(h_tmp_symbol_list[:])
-
-method_phase = create_lb_method(stencil=stencil_phase,
-                                method='srt',
-                                relaxation_rate=w_c,
-                                compressible=True,
-                                force_model=force_model_h)
-
-allen_cahn_lb = create_lb_update_rule(lb_method=method_phase,
-                                      velocity_input=u,
-                                      compressible=True,
-                                      optimization={"symbolic_field": h,
-                                                    "symbolic_temporary_field": h_tmp},
-                                      kernel_type='stream_pull_collide')
-
-allen_cahn_lb.set_main_assignments_from_dict({**allen_cahn_lb.main_assignments_dict, **{C.center: sum_h}})
-allen_cahn_update_rule = AssignmentCollection(main_assignments=allen_cahn_lb.main_assignments,
-                                              subexpressions=allen_cahn_lb.subexpressions)
-allen_cahn_update_rule = sympy_cse(allen_cahn_update_rule)
-
-# ---------------------------------------------------------------------------------------------------------
-
-method_hydro = create_with_discrete_maxwellian_eq_moments(stencil_hydro, rr_dict, force_model=force_model_g)
-
-hydro_lb_update_rule = get_collision_assignments_hydro(lb_method=method_hydro,
-                                                       density=density,
-                                                       velocity_input=u,
-                                                       force=force_g,
-                                                       optimization={"symbolic_field": g,
-                                                                     "symbolic_temporary_field": g_tmp},
-                                                       kernel_type='collide_only')
-
-# streaming of the hydrodynamic distribution
-stream_hydro = create_lb_update_rule(stencil=stencil_hydro,
-                                     optimization={"symbolic_field": g,
-                                                   "symbolic_temporary_field": g_tmp},
-                                     kernel_type='stream_pull_only')
 
+def test_codegen_3D():
+    stencil_phase = get_stencil("D3Q15")
+    stencil_hydro = get_stencil("D3Q27")
+    assert (len(stencil_phase[0]) == len(stencil_hydro[0]))
+    dimensions = len(stencil_hydro[0])
+
+    parameters = calculate_dimensionless_rising_bubble(reference_time=18000,
+                                                       density_heavy=1.0,
+                                                       bubble_radius=16,
+                                                       bond_number=30,
+                                                       reynolds_number=420,
+                                                       density_ratio=1000,
+                                                       viscosity_ratio=100)
+
+    np.isclose(parameters["density_light"], 0.001, rtol=1e-05, atol=1e-08, equal_nan=False)
+    np.isclose(parameters["gravitational_acceleration"], -9.876543209876543e-08, rtol=1e-05, atol=1e-08, equal_nan=False)
+
+    parameters = calculate_parameters_rti(reference_length=128,
+                                          reference_time=18000,
+                                          density_heavy=1.0,
+                                          capillary_number=9.1,
+                                          reynolds_number=128,
+                                          atwood_number=1.0,
+                                          peclet_number=744,
+                                          density_ratio=3,
+                                          viscosity_ratio=3)
+
+    np.isclose(parameters["density_light"], 1/3, rtol=1e-05, atol=1e-08, equal_nan=False)
+    np.isclose(parameters["gravitational_acceleration"], -3.9506172839506174e-07, rtol=1e-05, atol=1e-08, equal_nan=False)
+    np.isclose(parameters["mobility"], 0.0012234169653524492, rtol=1e-05, atol=1e-08, equal_nan=False)
+
+    rs = analytic_rising_speed(1-6, 20, 0.01)
+    np.isclose(rs, 16666.666666666668, rtol=1e-05, atol=1e-08, equal_nan=False)
+
+    density_liquid = 1.0
+    density_gas = 0.001
+    surface_tension = 0.0001
+    M = 0.02
+
+    # phase-field parameter
+    drho3 = (density_liquid - density_gas) / 3
+    # interface thickness
+    W = 5
+    # coefficient related to surface tension
+    beta = 12.0 * (surface_tension / W)
+    # coefficient related to surface tension
+    kappa = 1.5 * surface_tension * W
+    # relaxation rate allen cahn (h)
+    w_c = 1.0 / (0.5 + (3.0 * M))
+
+    # fields
+    u = fields("vel_field(" + str(dimensions) + "): [" + str(dimensions) + "D]", layout='fzyx')
+    C = fields("phase_field: [" + str(dimensions) + "D]", layout='fzyx')
+    force = fields("force(" + str(dimensions) + "): [" + str(dimensions) + "D]", layout='fzyx')
+
+    h = fields("lb_phase_field(" + str(len(stencil_phase)) + "): [" + str(dimensions) + "D]", layout='fzyx')
+    h_tmp = fields("lb_phase_field_tmp(" + str(len(stencil_phase)) + "): [" + str(dimensions) + "D]", layout='fzyx')
+
+    g = fields("lb_velocity_field(" + str(len(stencil_hydro)) + "): [" + str(dimensions) + "D]", layout='fzyx')
+    g_tmp = fields("lb_velocity_field_tmp(" + str(len(stencil_hydro)) + "): [" + str(dimensions) + "D]", layout='fzyx')
+
+    # calculate the relaxation rate for the hydro lb as well as the body force
+    density = density_gas + C.center * (density_liquid - density_gas)
+    # force acting on all phases of the model
+    body_force = np.array([0, 1e-6, 0])
+
+    relaxation_time = 0.03 + 0.5
+    relaxation_rate = 1.0 / relaxation_time
+
+    method_phase = create_lb_method(stencil=stencil_phase, method='srt', relaxation_rate=w_c, compressible=True)
+
+    mrt = create_lb_method(method="mrt", weighted=False, stencil=stencil_hydro,
+                           relaxation_rates=[1, 1, relaxation_rate, 1, 1, 1, 1])
+    rr_dict = OrderedDict(zip(mrt.moments, mrt.relaxation_rates))
+
+    method_hydro = create_with_discrete_maxwellian_eq_moments(stencil_hydro, rr_dict, compressible=False)
+
+    # create the kernels for the initialization of the g and h field
+    h_updates = initializer_kernel_phase_field_lb(h, C, u, method_phase, W)
+    g_updates = initializer_kernel_hydro_lb(g, u, method_hydro)
+
+    force_h = [f / 3 for f in interface_tracking_force(C, stencil_phase, W)]
+    force_model_h = MultiphaseForceModel(force=force_h)
+
+    force_g = hydrodynamic_force(g, C, method_hydro, relaxation_time, density_liquid, density_gas, kappa, beta, body_force)
+    force_model_g = MultiphaseForceModel(force=force_g, rho=density)
+
+    h_tmp_symbol_list = [h_tmp.center(i) for i, _ in enumerate(stencil_phase)]
+    sum_h = np.sum(h_tmp_symbol_list[:])
+
+    method_phase = create_lb_method(stencil=stencil_phase,
+                                    method='srt',
+                                    relaxation_rate=w_c,
+                                    compressible=True,
+                                    force_model=force_model_h)
+
+    allen_cahn_lb = create_lb_update_rule(lb_method=method_phase,
+                                          velocity_input=u,
+                                          compressible=True,
+                                          optimization={"symbolic_field": h,
+                                                        "symbolic_temporary_field": h_tmp},
+                                          kernel_type='stream_pull_collide')
+
+    allen_cahn_lb.set_main_assignments_from_dict({**allen_cahn_lb.main_assignments_dict, **{C.center: sum_h}})
+    allen_cahn_update_rule = AssignmentCollection(main_assignments=allen_cahn_lb.main_assignments,
+                                                  subexpressions=allen_cahn_lb.subexpressions)
+    allen_cahn_update_rule = sympy_cse(allen_cahn_update_rule)
+
+    # ---------------------------------------------------------------------------------------------------------
+
+    method_hydro = create_with_discrete_maxwellian_eq_moments(stencil_hydro, rr_dict, force_model=force_model_g)
+
+    hydro_lb_update_rule = get_collision_assignments_hydro(lb_method=method_hydro,
+                                                           density=density,
+                                                           velocity_input=u,
+                                                           force=force_g,
+                                                           optimization={"symbolic_field": g,
+                                                                         "symbolic_temporary_field": g_tmp},
+                                                           kernel_type='collide_only')
+
+    # streaming of the hydrodynamic distribution
+    stream_hydro = create_lb_update_rule(stencil=stencil_hydro,
+                                         optimization={"symbolic_field": g,
+                                                       "symbolic_temporary_field": g_tmp},
+                                         kernel_type='stream_pull_only')