def Initialize(self): print("::[Pfem Fluid Solver]:: -START-") print(self.main_model_part.SetBufferSize(self.settings["buffer_size"].GetInt())) # Get the computing model part self.computing_model_part = self.GetComputingModelPart() self.fluid_solver = KratosPfemFluid.TwoStepVPDEMcouplingStrategy(self.computing_model_part, self.velocity_linear_solver, self.pressure_linear_solver, self.settings["reform_dofs_at_each_step"].GetBool(), self.settings["velocity_tolerance"].GetDouble(), self.settings["pressure_tolerance"].GetDouble(), self.settings["maximum_pressure_iterations"].GetInt(), self.settings["time_order"].GetInt(), self.main_model_part.ProcessInfo[KratosMultiphysics.SPACE_DIMENSION]) echo_level = self.settings["echo_level"].GetInt() # Set echo_level self.fluid_solver.SetEchoLevel(echo_level) # Set initialize flag if( self.main_model_part.ProcessInfo[KratosMultiphysics.IS_RESTARTED] == True ): self.mechanical_solver.SetInitializePerformedFlag(True) # Check if everything is assigned correctly self.fluid_solver.Check() print("::[Pfem Fluid Solver]:: -END- ")
def Initialize(self): KratosMultiphysics.Logger.PrintInfo( "SwimmingDEM", self.main_model_part.SetBufferSize( self.settings["buffer_size"].GetInt())) # Get the computing model part self.computing_model_part = self.GetComputingModelPart() self.fluid_solver = KratosPfemFluid.TwoStepVPDEMcouplingStrategy( self.computing_model_part, self.velocity_linear_solver, self.pressure_linear_solver, self.settings["reform_dofs_at_each_step"].GetBool(), self.settings["velocity_tolerance"].GetDouble(), self.settings["pressure_tolerance"].GetDouble(), self.settings["maximum_pressure_iterations"].GetInt(), self.settings["time_order"].GetInt(), self.main_model_part.ProcessInfo[ KratosMultiphysics.SPACE_DIMENSION]) echo_level = self.settings["echo_level"].GetInt() # Set echo_level self.fluid_solver.SetEchoLevel(echo_level) # Check if everything is assigned correctly self.fluid_solver.Check()