def compareResults(reference_file, results_file):
settings_check_process = KratosMultiphysics.Parameters("""
{
"reference_file_name" : "",
"output_file_name" : "",
"comparison_type" : "dat_file",
"remove_output_file" : true,
"tolerance" : 1e-6
}
""")
settings_check_process["reference_file_name"].SetString(reference_file)
settings_check_process["output_file_name"].SetString(results_file)
# creating a dummy model
check_process = CompareTwoFilesCheckProcess(settings_check_process)
check_process.ExecuteInitialize()
check_process.ExecuteBeforeSolutionLoop()
check_process.ExecuteInitializeSolutionStep()
check_process.ExecuteFinalizeSolutionStep()
check_process.ExecuteBeforeOutputStep()
check_process.ExecuteAfterOutputStep()
check_process.ExecuteFinalize()
def test_PostprocessEigenvaluesProcess(self):
test_model = KratosMultiphysics.Model()
model_part = KratosMultiphysics.ModelPart("computing_domain")
model_part.AddNodalSolutionStepVariable(
KratosMultiphysics.DISPLACEMENT)
model_part.AddNodalSolutionStepVariable(KratosMultiphysics.REACTION)
model_part.AddNodalSolutionStepVariable(KratosMultiphysics.ROTATION)
model_part.AddNodalSolutionStepVariable(KratosMultiphysics.TORQUE)
CreateNodes(model_part)
# adding dofs is needed for the process internally
KratosMultiphysics.VariableUtils().AddDof(
KratosMultiphysics.DISPLACEMENT_X, KratosMultiphysics.REACTION_X,
model_part)
KratosMultiphysics.VariableUtils().AddDof(
KratosMultiphysics.DISPLACEMENT_Y, KratosMultiphysics.REACTION_Y,
model_part)
KratosMultiphysics.VariableUtils().AddDof(
KratosMultiphysics.DISPLACEMENT_Z, KratosMultiphysics.REACTION_Z,
model_part)
KratosMultiphysics.VariableUtils().AddDof(
KratosMultiphysics.ROTATION_X, KratosMultiphysics.TORQUE_X,
model_part)
KratosMultiphysics.VariableUtils().AddDof(
KratosMultiphysics.ROTATION_Y, KratosMultiphysics.TORQUE_Y,
model_part)
KratosMultiphysics.VariableUtils().AddDof(
KratosMultiphysics.ROTATION_Z, KratosMultiphysics.TORQUE_Z,
model_part)
test_model.AddModelPart(model_part)
# set EigenValues and -Vectors
num_eigenvalues = 4
eigenval_vector = GetEigenValueVector(num_eigenvalues)
model_part.ProcessInfo[
StructuralMechanicsApplication.EIGENVALUE_VECTOR] = eigenval_vector
for node in model_part.Nodes:
node.SetValue(StructuralMechanicsApplication.EIGENVECTOR_MATRIX,
GetEigenVectorMatrix(num_eigenvalues, node.Id))
# Use the process
# here the minimum settings are specified to test the default values!
settings_eigen_process = KratosMultiphysics.Parameters(
"""{"result_file_format_use_ascii" : true}""")
post_eigen_process = PostProcessEigenvaluesProcess(
test_model, settings_eigen_process)
post_eigen_process.ExecuteInitialize()
post_eigen_process.ExecuteBeforeSolutionLoop()
post_eigen_process.ExecuteInitializeSolutionStep()
post_eigen_process.ExecuteFinalizeSolutionStep()
post_eigen_process.ExecuteBeforeOutputStep()
post_eigen_process.ExecuteAfterOutputStep()
post_eigen_process.ExecuteFinalize()
# check the results
settings_check_process = KratosMultiphysics.Parameters("""
{
"reference_file_name" : "",
"output_file_name" : "",
"remove_output_file" : true,
"comparison_type" : "post_res_file"
}
""")
settings_check_process["reference_file_name"].SetString(
GetFilePath("test_postprocess_eigenvalues_process.ref"))
settings_check_process["output_file_name"].SetString(
"Structure_EigenResults_0.post.res")
check_process = CompareTwoFilesCheckProcess(test_model,
settings_check_process)
check_process.ExecuteInitialize()
check_process.ExecuteBeforeSolutionLoop()
check_process.ExecuteInitializeSolutionStep()
check_process.ExecuteFinalizeSolutionStep()
check_process.ExecuteBeforeOutputStep()
check_process.ExecuteAfterOutputStep()
check_process.ExecuteFinalize()
def test_isosurface_remesh_sphere(self):
KratosMultiphysics.Logger.GetDefaultOutput().SetSeverity(
KratosMultiphysics.Logger.Severity.WARNING)
# We create the model part
current_model = KratosMultiphysics.Model()
main_model_part = current_model.CreateModelPart("MainModelPart")
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.DOMAIN_SIZE, 3)
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.TIME, 0.0)
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.DELTA_TIME,
1.0)
#main_model_part.ProcessInfo.SetValue(KratosMultiphysics.STEP, 1)
# We add the variables needed
main_model_part.AddNodalSolutionStepVariable(
KratosMultiphysics.DISTANCE)
main_model_part.AddNodalSolutionStepVariable(
KratosMultiphysics.DISTANCE_GRADIENT)
# We import the model main_model_part
file_path = os.path.dirname(os.path.realpath(__file__))
KratosMultiphysics.ModelPartIO(
file_path +
"/mmg_eulerian_test/test_sphere_isosurface").ReadModelPart(
main_model_part)
# Set manually a distance function
circle_radious = 0.25
center_coordinates = [0.5, 0.5, 0.5]
for node in main_model_part.Nodes:
distance = (
(node.X - center_coordinates[0])**2 +
(node.Y - center_coordinates[1])**2 +
(node.Z - center_coordinates[2])**2)**0.5 - circle_radious
node.SetSolutionStepValue(KratosMultiphysics.DISTANCE, distance)
# We calculate the gradient of the distance variable
find_nodal_h = KratosMultiphysics.FindNodalHNonHistoricalProcess(
main_model_part)
find_nodal_h.Execute()
mmg_parameters = KratosMultiphysics.Parameters("""
{
"discretization_type" : "Isosurface",
"filename" : "mmg_eulerian_test/test_sphere_isosurface",
"save_external_files" : true,
"echo_level" : 0
}
""")
# We create the remeshing utility
mmg_parameters["filename"].SetString(
file_path + "/" + mmg_parameters["filename"].GetString())
mmg_process = MeshingApplication.MmgProcess3D(main_model_part,
mmg_parameters)
# We remesh
mmg_process.Execute()
# Finally we export to GiD
from gid_output_process import GiDOutputProcess
gid_output = GiDOutputProcess(
main_model_part, "gid_output",
KratosMultiphysics.Parameters("""
{
"result_file_configuration" : {
"gidpost_flags": {
"GiDPostMode": "GiD_PostBinary",
"WriteDeformedMeshFlag": "WriteUndeformed",
"WriteConditionsFlag": "WriteConditions",
"MultiFileFlag": "SingleFile"
},
"nodal_results" : ["DISTANCE"]
}
}
"""))
#gid_output.ExecuteInitialize()
#gid_output.ExecuteBeforeSolutionLoop()
#gid_output.ExecuteInitializeSolutionStep()
#gid_output.PrintOutput()
#gid_output.ExecuteFinalizeSolutionStep()
#gid_output.ExecuteFinalize()
from compare_two_files_check_process import CompareTwoFilesCheckProcess
check_parameters = KratosMultiphysics.Parameters("""
{
"reference_file_name" : "mmg_eulerian_test/test_sphere_isosurface_result.sol",
"output_file_name" : "mmg_eulerian_test/test_sphere_isosurface_step=0.o.sol",
"dimension" : 3,
"comparison_type" : "sol_file"
}
""")
check_parameters["reference_file_name"].SetString(
file_path + "/" +
check_parameters["reference_file_name"].GetString())
check_parameters["output_file_name"].SetString(
file_path + "/" + check_parameters["output_file_name"].GetString())
check_files = CompareTwoFilesCheckProcess(check_parameters)
check_files.ExecuteInitialize()
check_files.ExecuteBeforeSolutionLoop()
check_files.ExecuteInitializeSolutionStep()
check_files.ExecuteFinalizeSolutionStep()
check_files.ExecuteFinalize()
def test_remesh_sphere_skin_prisms(self):
KratosMultiphysics.Logger.GetDefaultOutput().SetSeverity(
KratosMultiphysics.Logger.Severity.WARNING)
# We create the model part
current_model = KratosMultiphysics.Model()
main_model_part = current_model.CreateModelPart("MainModelPart")
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.DOMAIN_SIZE, 3)
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.TIME, 0.0)
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.DELTA_TIME,
1.0)
#main_model_part.ProcessInfo.SetValue(KratosMultiphysics.STEP, 1)
# We add the variables needed
main_model_part.AddNodalSolutionStepVariable(
KratosMultiphysics.DISTANCE)
# We import the model main_model_part
file_path = os.path.dirname(os.path.realpath(__file__))
KratosMultiphysics.ModelPartIO(
file_path +
"/mmg_eulerian_test/coarse_sphere_skin_prisms_test").ReadModelPart(
main_model_part)
for node in main_model_part.Nodes:
node.SetSolutionStepValue(KratosMultiphysics.DISTANCE, abs(node.X))
# We calculate the gradient of the distance variable
KratosMultiphysics.VariableUtils().SetNonHistoricalVariable(
KratosMultiphysics.NODAL_H, 0.0, main_model_part.Nodes)
find_nodal_h = KratosMultiphysics.FindNodalHNonHistoricalProcess(
main_model_part)
find_nodal_h.Execute()
# We set to zero the metric
metric_vector = KratosMultiphysics.Vector(6)
metric_vector[0] = 1.0
metric_vector[1] = 1.0
metric_vector[2] = 1.0
metric_vector[3] = 0.0
metric_vector[4] = 0.0
metric_vector[5] = 0.0
for node in main_model_part.Nodes:
node.SetValue(MeshingApplication.METRIC_TENSOR_3D, metric_vector)
mmg_parameters = KratosMultiphysics.Parameters("""
{
"filename" : "mmg_eulerian_test/coarse_sphere_skin_prisms_test",
"collapse_prisms_elements" : true,
"save_external_files" : true,
"echo_level" : 0
}
""")
# We create the remeshing utility
mmg_parameters["filename"].SetString(
file_path + "/" + mmg_parameters["filename"].GetString())
mmg_process = MeshingApplication.MmgProcess3DSurfaces(
main_model_part, mmg_parameters)
# We remesh
mmg_process.Execute()
## Finally we export to GiD
#from gid_output_process import GiDOutputProcess
#gid_output = GiDOutputProcess(main_model_part,
#"gid_output",
#KratosMultiphysics.Parameters("""
#{
#"result_file_configuration" : {
#"gidpost_flags": {
#"GiDPostMode": "GiD_PostBinary",
#"WriteDeformedMeshFlag": "WriteUndeformed",
#"WriteConditionsFlag": "WriteConditions",
#"MultiFileFlag": "SingleFile"
#},
#"nodal_results" : ["DISTANCE"]
#}
#}
#""")
#)
#gid_output.ExecuteInitialize()
#gid_output.ExecuteBeforeSolutionLoop()
#gid_output.ExecuteInitializeSolutionStep()
#gid_output.PrintOutput()
#gid_output.ExecuteFinalizeSolutionStep()
#gid_output.ExecuteFinalize()
from compare_two_files_check_process import CompareTwoFilesCheckProcess
check_parameters = KratosMultiphysics.Parameters("""
{
"reference_file_name" : "mmg_eulerian_test/coarse_sphere_skin_prisms_test_result.sol",
"output_file_name" : "mmg_eulerian_test/coarse_sphere_skin_prisms_test_step=0.sol",
"dimension" : 3,
"comparison_type" : "sol_file"
}
""")
check_parameters["reference_file_name"].SetString(
file_path + "/" +
check_parameters["reference_file_name"].GetString())
check_parameters["output_file_name"].SetString(
file_path + "/" + check_parameters["output_file_name"].GetString())
check_files = CompareTwoFilesCheckProcess(check_parameters)
check_files.ExecuteInitialize()
check_files.ExecuteBeforeSolutionLoop()
check_files.ExecuteInitializeSolutionStep()
check_files.ExecuteFinalizeSolutionStep()
check_files.ExecuteFinalize()
def test_remesh_sphere(self):
KratosMultiphysics.Logger.GetDefaultOutput().SetSeverity(
KratosMultiphysics.Logger.Severity.WARNING)
# We create the model part
current_model = KratosMultiphysics.Model()
main_model_part = current_model.CreateModelPart("MainModelPart")
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.DOMAIN_SIZE, 3)
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.TIME, 0.0)
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.DELTA_TIME,
1.0)
#main_model_part.ProcessInfo.SetValue(KratosMultiphysics.STEP, 1)
# We add the variables needed
main_model_part.AddNodalSolutionStepVariable(
KratosMultiphysics.DISTANCE)
main_model_part.AddNodalSolutionStepVariable(
KratosMultiphysics.DISTANCE_GRADIENT)
# We import the model main_model_part
file_path = os.path.dirname(os.path.realpath(__file__))
KratosMultiphysics.ModelPartIO(file_path +
"/mmg_eulerian_test/coarse_sphere_test"
).ReadModelPart(main_model_part)
# We calculate the gradient of the distance variable
find_nodal_h = KratosMultiphysics.FindNodalHNonHistoricalProcess(
main_model_part)
find_nodal_h.Execute()
KratosMultiphysics.VariableUtils().SetNonHistoricalVariable(
KratosMultiphysics.NODAL_AREA, 0.0, main_model_part.Nodes)
local_gradient = KratosMultiphysics.ComputeNodalGradientProcess3D(
main_model_part, KratosMultiphysics.DISTANCE,
KratosMultiphysics.DISTANCE_GRADIENT,
KratosMultiphysics.NODAL_AREA)
local_gradient.Execute()
# We set to zero the metric
ZeroVector = KratosMultiphysics.Vector(6)
ZeroVector[0] = 0.0
ZeroVector[1] = 0.0
ZeroVector[2] = 0.0
ZeroVector[3] = 0.0
ZeroVector[4] = 0.0
ZeroVector[5] = 0.0
for node in main_model_part.Nodes:
node.SetValue(MeshingApplication.METRIC_TENSOR_3D, ZeroVector)
# We define a metric using the ComputeLevelSetSolMetricProcess
MetricParameters = KratosMultiphysics.Parameters("""
{
"minimal_size" : 1.0e-1,
"enforce_current" : false,
"anisotropy_remeshing" : false,
"anisotropy_parameters" :{
"hmin_over_hmax_anisotropic_ratio" : 0.15,
"boundary_layer_max_distance" : 1.0e-4,
"interpolation" : "Linear"
}
}
""")
metric_process = MeshingApplication.ComputeLevelSetSolMetricProcess3D(
main_model_part, KratosMultiphysics.DISTANCE_GRADIENT,
MetricParameters)
metric_process.Execute()
mmg_parameters = KratosMultiphysics.Parameters("""
{
"filename" : "mmg_eulerian_test/coarse_sphere_test",
"save_external_files" : true,
"echo_level" : 0
}
""")
# We create the remeshing utility
mmg_parameters["filename"].SetString(
file_path + "/" + mmg_parameters["filename"].GetString())
mmg_process = MeshingApplication.MmgProcess3D(main_model_part,
mmg_parameters)
# We remesh
mmg_process.Execute()
# Finally we export to GiD
from gid_output_process import GiDOutputProcess
gid_output = GiDOutputProcess(
main_model_part, "gid_output",
KratosMultiphysics.Parameters("""
{
"result_file_configuration" : {
"gidpost_flags": {
"GiDPostMode": "GiD_PostBinary",
"WriteDeformedMeshFlag": "WriteUndeformed",
"WriteConditionsFlag": "WriteConditions",
"MultiFileFlag": "SingleFile"
},
"nodal_results" : ["DISTANCE"]
}
}
"""))
#gid_output.ExecuteInitialize()
#gid_output.ExecuteBeforeSolutionLoop()
#gid_output.ExecuteInitializeSolutionStep()
#gid_output.PrintOutput()
#gid_output.ExecuteFinalizeSolutionStep()
#gid_output.ExecuteFinalize()
from compare_two_files_check_process import CompareTwoFilesCheckProcess
check_parameters = KratosMultiphysics.Parameters("""
{
"reference_file_name" : "mmg_eulerian_test/coarse_sphere_test_result.sol",
"output_file_name" : "mmg_eulerian_test/coarse_sphere_test_step=0.sol",
"dimension" : 3,
"comparison_type" : "sol_file"
}
""")
check_parameters["reference_file_name"].SetString(
file_path + "/" +
check_parameters["reference_file_name"].GetString())
check_parameters["output_file_name"].SetString(
file_path + "/" + check_parameters["output_file_name"].GetString())
check_files = CompareTwoFilesCheckProcess(check_parameters)
check_files.ExecuteInitialize()
check_files.ExecuteBeforeSolutionLoop()
check_files.ExecuteInitializeSolutionStep()
check_files.ExecuteFinalizeSolutionStep()
check_files.ExecuteFinalize()
import from_json_check_result_process
check_parameters = KratosMultiphysics.Parameters("""
{
"check_variables" : ["DISTANCE"],
"input_file_name" : "mmg_eulerian_test/distante_extrapolation.json",
"model_part_name" : "MainModelPart",
"time_frequency" : 0.0
}
""")
check_parameters["input_file_name"].SetString(
file_path + "/" + check_parameters["input_file_name"].GetString())
check = from_json_check_result_process.FromJsonCheckResultProcess(
current_model, check_parameters)
check.ExecuteInitialize()
check.ExecuteBeforeSolutionLoop()
check.ExecuteFinalizeSolutionStep()
def test_remesh_rectangle_hessian(self):
KratosMultiphysics.Logger.GetDefaultOutput().SetSeverity(
KratosMultiphysics.Logger.Severity.WARNING)
# We create the model part
current_model = KratosMultiphysics.Model()
main_model_part = current_model.CreateModelPart("MainModelPart", 2)
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.DOMAIN_SIZE, 2)
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.TIME, 0.0)
main_model_part.ProcessInfo.SetValue(KratosMultiphysics.DELTA_TIME,
1.0)
#main_model_part.ProcessInfo.SetValue(KratosMultiphysics.STEP, 1)
# We add the variables needed
main_model_part.AddNodalSolutionStepVariable(
KratosMultiphysics.DISTANCE)
# We import the model main_model_part
file_path = os.path.dirname(os.path.realpath(__file__))
KratosMultiphysics.ModelPartIO(file_path +
"/mmg_lagrangian_test/remesh_rectangle"
).ReadModelPart(main_model_part)
# We calculate the gradient of the distance variable
find_nodal_h = KratosMultiphysics.FindNodalHNonHistoricalProcess(
main_model_part)
find_nodal_h.Execute()
KratosMultiphysics.VariableUtils().SetNonHistoricalVariable(
KratosMultiphysics.NODAL_AREA, 0.0, main_model_part.Nodes)
main_model_part.Nodes[1].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 9.86358e-08)
main_model_part.Nodes[2].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 4.88117e-07)
main_model_part.Nodes[3].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 8.21649e-07)
main_model_part.Nodes[4].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 2.98426e-06)
main_model_part.Nodes[5].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 1.9462e-06)
main_model_part.Nodes[6].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 3.20072e-06)
main_model_part.Nodes[7].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 8.13038e-07)
main_model_part.Nodes[8].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 1.74975e-06)
main_model_part.Nodes[9].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 8.66819e-06)
main_model_part.Nodes[10].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 6.24329e-06)
main_model_part.Nodes[11].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 1.10461e-05)
main_model_part.Nodes[12].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 7.01043e-07)
main_model_part.Nodes[13].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 1.90256e-05)
main_model_part.Nodes[14].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 2.51694e-06)
main_model_part.Nodes[15].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 1.51568e-05)
main_model_part.Nodes[16].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 3.0177e-05)
main_model_part.Nodes[17].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 8.48471e-06)
main_model_part.Nodes[18].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 8.37749e-08)
main_model_part.Nodes[19].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 4.64653e-07)
main_model_part.Nodes[20].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 2.64854e-05)
main_model_part.Nodes[21].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 3.71692e-05)
main_model_part.Nodes[22].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 3.28506e-06)
main_model_part.Nodes[23].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 1.97626e-05)
main_model_part.Nodes[24].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 6.49145e-05)
main_model_part.Nodes[25].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 1, 20e-02)
main_model_part.Nodes[26].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 4.05303e-05)
main_model_part.Nodes[27].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 6.49053e-05)
main_model_part.Nodes[28].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 3.71567e-05)
main_model_part.Nodes[29].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 3.01782e-05)
main_model_part.Nodes[30].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000118602)
main_model_part.Nodes[31].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 5.74756e-05)
main_model_part.Nodes[32].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 6.26979e-05)
main_model_part.Nodes[33].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 6.33597e-05)
main_model_part.Nodes[34].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000101589)
main_model_part.Nodes[35].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000192486)
main_model_part.Nodes[36].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 9.93803e-05)
main_model_part.Nodes[37].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000116324)
main_model_part.Nodes[38].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 7.68763e-05)
main_model_part.Nodes[39].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000149051)
main_model_part.Nodes[40].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000289484)
main_model_part.Nodes[41].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000192959)
main_model_part.Nodes[42].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000145925)
main_model_part.Nodes[43].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 9.79472e-05)
main_model_part.Nodes[44].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000201518)
main_model_part.Nodes[45].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000401176)
main_model_part.Nodes[46].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000291243)
main_model_part.Nodes[47].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000205528)
main_model_part.Nodes[48].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000119595)
main_model_part.Nodes[49].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000262135)
main_model_part.Nodes[50].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000415149)
main_model_part.Nodes[51].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.00053798)
main_model_part.Nodes[52].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000268931)
main_model_part.Nodes[53].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000139653)
main_model_part.Nodes[54].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000331001)
main_model_part.Nodes[55].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000546243)
main_model_part.Nodes[56].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000675476)
main_model_part.Nodes[57].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000327043)
main_model_part.Nodes[58].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000158685)
main_model_part.Nodes[59].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.00039571)
main_model_part.Nodes[60].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000651727)
main_model_part.Nodes[61].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000370579)
main_model_part.Nodes[62].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000809699)
main_model_part.Nodes[63].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000170989)
main_model_part.Nodes[64].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000445764)
main_model_part.Nodes[65].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000784852)
main_model_part.Nodes[66].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000433683)
main_model_part.Nodes[67].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000914023)
main_model_part.Nodes[68].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000179197)
main_model_part.Nodes[69].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.00047077)
main_model_part.Nodes[70].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000904417)
main_model_part.Nodes[71].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000464902)
main_model_part.Nodes[72].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000994274)
main_model_part.Nodes[73].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000173952)
main_model_part.Nodes[74].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000466276)
main_model_part.Nodes[75].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000971188)
main_model_part.Nodes[76].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000474027)
main_model_part.Nodes[77].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000946149)
main_model_part.Nodes[78].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000160469)
main_model_part.Nodes[79].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000397979)
main_model_part.Nodes[80].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000996743)
main_model_part.Nodes[81].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000455294)
main_model_part.Nodes[82].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000925016)
main_model_part.Nodes[83].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000132904)
main_model_part.Nodes[84].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000373155)
main_model_part.Nodes[85].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000963824)
main_model_part.Nodes[86].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000386671)
main_model_part.Nodes[87].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000858186)
main_model_part.Nodes[88].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 9.47787e-05)
main_model_part.Nodes[89].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000851174)
main_model_part.Nodes[90].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000282759)
main_model_part.Nodes[91].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000285314)
main_model_part.Nodes[92].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000688848)
main_model_part.Nodes[93].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 4.35228e-05)
main_model_part.Nodes[94].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000686866)
main_model_part.Nodes[95].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000179265)
main_model_part.Nodes[96].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000175715)
main_model_part.Nodes[97].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000386179)
main_model_part.Nodes[98].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 1.59849e-05)
main_model_part.Nodes[99].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 1.7304e-05)
main_model_part.Nodes[100].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0.000382607)
main_model_part.Nodes[101].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0)
main_model_part.Nodes[102].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0)
main_model_part.Nodes[103].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0)
main_model_part.Nodes[104].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0)
main_model_part.Nodes[105].SetSolutionStepValue(
KratosMultiphysics.DISTANCE, 0)
# We set to zero the metric
ZeroVector = KratosMultiphysics.Vector(3)
ZeroVector[0] = 0.0
ZeroVector[1] = 0.0
ZeroVector[2] = 0.0
for node in main_model_part.Nodes:
node.SetValue(MeshingApplication.METRIC_TENSOR_2D, ZeroVector)
# We define a metric using the ComputeLevelSetSolMetricProcess
MetricParameters = KratosMultiphysics.Parameters("""
{
"hessian_strategy_parameters" :{
"metric_variable" : ["DISTANCE"],
"estimate_interpolation_error" : false,
"interpolation_error" : 1.0e-6,
"mesh_dependent_constant" : 0.28125
},
"minimal_size" : 0.015,
"maximal_size" : 0.5,
"sizing_parameters":
{
"reference_variable_name" : "DISTANCE",
"boundary_layer_max_distance" : 1.0,
"interpolation" : "constant"
},
"enforce_current" : false,
"anisotropy_remeshing" : false,
"enforce_anisotropy_relative_variable" : false
}
""")
metric_process = MeshingApplication.ComputeHessianSolMetricProcess(
main_model_part, KratosMultiphysics.DISTANCE, MetricParameters)
metric_process.Execute()
mmg_parameters = KratosMultiphysics.Parameters("""
{
"filename" : "mmg_lagrangian_test/remesh_rectangle",
"save_external_files" : true,
"echo_level" : 0
}
""")
# We create the remeshing utility
mmg_parameters["filename"].SetString(
file_path + "/" + mmg_parameters["filename"].GetString())
mmg_process = MeshingApplication.MmgProcess2D(main_model_part,
mmg_parameters)
# We remesh
mmg_process.Execute()
## Finally we export to GiD
#from gid_output_process import GiDOutputProcess
#gid_output = GiDOutputProcess(main_model_part,
#"gid_output",
#KratosMultiphysics.Parameters("""
#{
#"result_file_configuration" : {
#"gidpost_flags": {
#"GiDPostMode": "GiD_PostBinary",
#"WriteDeformedMeshFlag": "WriteUndeformed",
#"WriteConditionsFlag": "WriteConditions",
#"MultiFileFlag": "SingleFile"
#},
#"nodal_results" : ["DISTANCE"],
#"nodal_nonhistorical_results": ["METRIC_TENSOR_2D","AUXILIAR_GRADIENT","AUXILIAR_HESSIAN"]
#}
#}
#""")
#)
#gid_output.ExecuteInitialize()
#gid_output.ExecuteBeforeSolutionLoop()
#gid_output.ExecuteInitializeSolutionStep()
#gid_output.PrintOutput()
#gid_output.ExecuteFinalizeSolutionStep()
#gid_output.ExecuteFinalize()
# We check the solution
from compare_two_files_check_process import CompareTwoFilesCheckProcess
check_parameters = KratosMultiphysics.Parameters("""
{
"reference_file_name" : "mmg_lagrangian_test/remesh_rectangle_result.sol",
"output_file_name" : "mmg_lagrangian_test/remesh_rectangle_step=0.sol",
"dimension" : 2,
"comparison_type" : "sol_file"
}
""")
check_parameters["reference_file_name"].SetString(
file_path + "/" +
check_parameters["reference_file_name"].GetString())
check_parameters["output_file_name"].SetString(
file_path + "/" + check_parameters["output_file_name"].GetString())
check_files = CompareTwoFilesCheckProcess(check_parameters)
check_files.ExecuteInitialize()
check_files.ExecuteBeforeSolutionLoop()
check_files.ExecuteInitializeSolutionStep()
check_files.ExecuteFinalizeSolutionStep()
check_files.ExecuteFinalize()
