def Initialize(self): Say('Initializing simulation...\n') self.run_code = self.GetRunCode() # Moving to the recently created folder os.chdir(self.main_path) if self.do_print_results: [self.post_path, data_and_results, self.graphs_path, MPI_results] = \ self.procedures.CreateDirectories(str(self.main_path), str(self.project_parameters["problem_data"]["problem_name"].GetString()), self.run_code) SDP.CopyInputFilesIntoFolder(self.main_path, self.post_path) self.MPI_results = MPI_results self.FluidInitialize() self.DispersePhaseInitialize() self.SetAllModelParts() if self.project_parameters.Has( 'sdem_output_processes') and self.do_print_results: gid_output_options = self.project_parameters[ "sdem_output_processes"]["gid_output"][0]["Parameters"] result_file_configuration = gid_output_options[ "postprocess_parameters"]["result_file_configuration"] write_conditions_option = result_file_configuration[ "gidpost_flags"]["WriteConditionsFlag"].GetString( ) == "WriteConditions" deformed_mesh_option = result_file_configuration["gidpost_flags"][ "WriteDeformedMeshFlag"].GetString() == "WriteDeformed" old_gid_output_post_options_dict = { 'GiD_PostAscii': 'Ascii', 'GiD_PostBinary': 'Binary', 'GiD_PostAsciiZipped': 'AsciiZipped' } old_gid_output_multiple_file_option_dict = { 'SingleFile': 'Single', 'MultipleFiles': 'Multiples' } post_mode_key = result_file_configuration["gidpost_flags"][ "GiDPostMode"].GetString() multiple_files_option_key = result_file_configuration[ "gidpost_flags"]["MultiFileFlag"].GetString() self.swimming_DEM_gid_io = \ swimming_DEM_gid_output.SwimmingDEMGiDOutput( file_name = self.project_parameters["problem_data"]["problem_name"].GetString(), vol_output = result_file_configuration["body_output"].GetBool(), post_mode = old_gid_output_post_options_dict[post_mode_key], multifile = old_gid_output_multiple_file_option_dict[multiple_files_option_key], deformed_mesh = deformed_mesh_option, write_conditions = write_conditions_option) self.swimming_DEM_gid_io.initialize_swimming_DEM_results( self.spheres_model_part, self.cluster_model_part, self.rigid_face_model_part, self.mixed_model_part) self.SetPointGraphPrinter() self.AssignKinematicViscosityFromDynamicViscosity() super(SwimmingDEMAnalysis, self).Initialize() # coarse-graining: applying changes to the physical properties of the model to adjust for # the similarity transformation if required (fluid effects only). SDP.ApplySimilarityTransformations( self.fluid_model_part, self.project_parameters["similarity"] ["similarity_transformation_type"].GetInt(), self.project_parameters["similarity"] ["model_over_real_diameter_factor"].GetDouble()) if self.do_print_results: self.SetPostUtils() # creating an IOTools object to perform other printing tasks self.io_tools = SDP.IOTools(self.project_parameters) dem_physics_calculator = DEM.SphericElementGlobalPhysicsCalculator( self.spheres_model_part) if self.project_parameters["coupling"]["coupling_level_type"].GetInt(): default_meso_scale_length_needed = ( self.project_parameters["coupling"]["backward_coupling"] ["meso_scale_length"].GetDouble() <= 0.0 and self.spheres_model_part.NumberOfElements(0) > 0) if default_meso_scale_length_needed: biggest_size = ( 2 * dem_physics_calculator.CalculateMaxNodalVariable( self.spheres_model_part, Kratos.RADIUS)) self.project_parameters["coupling"]["backward_coupling"][ "meso_scale_length"].SetDouble(20 * biggest_size) elif self.spheres_model_part.NumberOfElements(0) == 0: self.project_parameters["coupling"]["backward_coupling"][ "meso_scale_length"].SetDouble(1.0) # creating a custom functions calculator for the implementation of # additional custom functions fluid_domain_dimension = self.project_parameters["fluid_parameters"][ "solver_settings"]["domain_size"].GetInt() self.custom_functions_tool = SDP.FunctionsCalculator( fluid_domain_dimension) # creating a debug tool self.dem_volume_tool = self.GetVolumeDebugTool() #self.SetEmbeddedTools() Say('Initialization Complete\n') if self.project_parameters["custom_fluid"][ "flow_in_porous_DEM_medium_option"].GetBool(): SDP.FixModelPart(self.spheres_model_part) ################################################## # I N I T I A L I Z I N G T I M E L O O P ################################################## self.step = 0 self.time = self.fluid_parameters["problem_data"][ "start_time"].GetDouble() self.fluid_time_step = self._GetFluidAnalysis()._GetSolver( )._ComputeDeltaTime() self.time_step = self.spheres_model_part.ProcessInfo.GetValue( Kratos.DELTA_TIME) self.rigid_face_model_part.ProcessInfo[ Kratos.DELTA_TIME] = self.time_step self.cluster_model_part.ProcessInfo[Kratos.DELTA_TIME] = self.time_step self.stationarity = False # setting up loop counters: self.DEM_to_fluid_counter = self.GetBackwardCouplingCounter() self.stationarity_counter = self.GetStationarityCounter() self.print_counter = self.GetPrintCounter() self.debug_info_counter = self.GetDebugInfo() self.particles_results_counter = self.GetParticlesResultsCounter() self.quadrature_counter = self.GetHistoryForceQuadratureCounter() # Phantom self._GetDEMAnalysis( ).analytic_data_counter = self.ProcessAnalyticDataCounter() self.mat_deriv_averager = SDP.Averager(1, 3) self.laplacian_averager = SDP.Averager(1, 3) self.report.total_steps_expected = int(self.end_time / self.time_step) Say(self.report.BeginReport(self.timer)) # creating a Post Utils object that executes several post-related tasks self.post_utils_DEM = DP.PostUtils( self.project_parameters['dem_parameters'], self.spheres_model_part) # otherwise variables are set to 0 by default: SDP.InitializeVariablesWithNonZeroValues(self.project_parameters, self.fluid_model_part, self.spheres_model_part) if self.do_print_results: self.SetUpResultsDatabase() # ANALYTICS BEGIN self.project_parameters.AddEmptyValue( "perform_analytics_option").SetBool(False) if self.project_parameters["perform_analytics_option"].GetBool(): import KratosMultiphysics.SwimmingDEMApplication.analytics as analytics variables_to_measure = [Kratos.PRESSURE] steps_between_measurements = 100 gauge = analytics.Gauge(self.fluid_model_part, self.fluid_time_step, self.end_time, variables_to_measure, steps_between_measurements) point_coors = [0.0, 0.0, 0.01] target_node = SDP.FindClosestNode(self.fluid_model_part, point_coors) target_id = target_node.Id Say(target_node.X, target_node.Y, target_node.Z) Say(target_id) def condition(node): return node.Id == target_id gauge.ConstructArrayOfNodes(condition) Say(gauge.variables) # ANALYTICS END self.FillHistoryForcePrecalculatedVectors() self.PerformZeroStepInitializations() if self.do_print_results: self._Print()
def InitializeVariablesWithNonZeroValues(self): SDP.InitializeVariablesWithNonZeroValues(self.project_parameters, self.fluid_model_part, self.spheres_model_part)