def Run(self):
num_coupling_interfaces = self.settings["coupling_interfaces"].size()
self.__CustomPrint(
1,
colors.cyan("Starting export") + " of CouplingInterfaces ...")
for i in range(num_coupling_interfaces):
coupling_interface_settings = self.settings["coupling_interfaces"][
i]
sub_model_part_name = coupling_interface_settings[
"sub_model_part_name"].GetString()
comm_name = coupling_interface_settings["comm_name"].GetString()
receive_interface = False
operation = "Exporting"
if coupling_interface_settings.Has("receive_interface"):
receive_interface = coupling_interface_settings[
"receive_interface"].GetBool()
operation = "Importing"
self.__CustomPrint(
2,
colors.cyan(operation) +
' coupling-interface "{}" on ModelPart "{}"'.format(
comm_name, sub_model_part_name))
if not self.dry_run:
if receive_interface:
# use an aux-modelpart, which will not be used again
KratosCoSim.EMPIRE_API.EMPIRE_API_recvMesh(
self.model.CreateModelPart(sub_model_part_name),
comm_name)
# TODO maybe restructure and do all receives after all sends
else:
KratosCoSim.EMPIRE_API.EMPIRE_API_sendMesh(
self.model["ExtSolver." + sub_model_part_name],
comm_name)
else:
self.__CustomPrint(2, colors.magenta('... skipped'))
self.__CustomPrint(
1,
colors.cyan("Finished " + operation) +
" of CouplingInterfaces")
# time loop
self.__CustomPrint(1, "Starting Solution Loop")
for i in range(self.settings["num_steps"].GetInt()):
if self.echo_level > 0: print() # newline
self.__CustomPrint(
1,
colors.bold('Step: {}/{}'.format(
i + 1, self.settings["num_steps"].GetInt())))
self.SolveSolutionStep()
self.__CustomPrint(1, "Finished")
def SolveSolutionStep(self):
for k in range(self.num_coupling_iterations):
if self.echo_level > 0:
cs_tools.cs_print_info(
self._ClassName(), colors.cyan("Coupling iteration:"),
colors.bold(
str(k + 1) + " / " +
str(self.num_coupling_iterations)))
for coupling_op in self.coupling_operations_dict.values():
coupling_op.InitializeCouplingIteration()
for conv_acc in self.convergence_accelerators_list:
conv_acc.InitializeNonLinearIteration()
for conv_crit in self.convergence_criteria_list:
conv_crit.InitializeNonLinearIteration()
for solver_name, solver in self.solver_wrappers.items():
self._SynchronizeInputData(solver_name)
solver.SolveSolutionStep()
self._SynchronizeOutputData(solver_name)
for coupling_op in self.coupling_operations_dict.values():
coupling_op.FinalizeCouplingIteration()
for conv_acc in self.convergence_accelerators_list:
conv_acc.FinalizeNonLinearIteration()
for conv_crit in self.convergence_criteria_list:
conv_crit.FinalizeNonLinearIteration()
is_converged = all([
conv_crit.IsConverged()
for conv_crit in self.convergence_criteria_list
])
if is_converged:
if self.echo_level > 0:
cs_tools.cs_print_info(
self._ClassName(),
colors.green("### CONVERGENCE WAS ACHIEVED ###"))
self.__CommunicateStateOfConvergence(True)
return True
if k + 1 >= self.num_coupling_iterations and self.echo_level > 0:
cs_tools.cs_print_info(
self._ClassName(),
colors.red("XXX CONVERGENCE WAS NOT ACHIEVED XXX"))
self.__CommunicateStateOfConvergence(
True
) # True because max number of iterations is achieved. Otherwise external solver is stuck in time
return False
# if it reaches here it means that the coupling has not converged and this was not the last coupling iteration
self.__CommunicateStateOfConvergence(False)
# do relaxation only if this iteration is not the last iteration of this timestep
for conv_acc in self.convergence_accelerators_list:
conv_acc.ComputeAndApplyUpdate()
def SolveSolutionStep(self):
for k in range(self.num_coupling_iterations):
if self.echo_level > 0:
cs_tools.cs_print_info(
self._ClassName(), colors.cyan("Coupling iteration:"),
colors.bold(
str(k + 1) + " / " +
str(self.num_coupling_iterations)))
for coupling_op in self.coupling_operations_dict.values():
coupling_op.InitializeCouplingIteration()
for conv_acc in self.convergence_accelerators_list:
conv_acc.InitializeNonLinearIteration()
for conv_crit in self.convergence_criteria_list:
conv_crit.InitializeNonLinearIteration()
for solver_name, solver in self.solver_wrappers.items():
self._SynchronizeInputData(solver_name)
solver.SolveSolutionStep()
self._SynchronizeOutputData(solver_name)
for coupling_op in self.coupling_operations_dict.values():
coupling_op.FinalizeCouplingIteration()
for conv_acc in self.convergence_accelerators_list:
conv_acc.FinalizeNonLinearIteration()
for conv_crit in self.convergence_criteria_list:
conv_crit.FinalizeNonLinearIteration()
is_converged = all([
conv_crit.IsConverged()
for conv_crit in self.convergence_criteria_list
])
self.__CommunicateStateOfConvergence(is_converged)
if is_converged:
if self.echo_level > 0:
cs_tools.cs_print_info(
self._ClassName(),
colors.green("### CONVERGENCE WAS ACHIEVED ###"))
return True
else:
# TODO I think this should not be done in the last iterations if the solution does not converge in this timestep
for conv_acc in self.convergence_accelerators_list:
conv_acc.ComputeAndApplyUpdate()
if k + 1 >= self.num_coupling_iterations and self.echo_level > 0:
cs_tools.cs_print_info(
self._ClassName(),
colors.red("XXX CONVERGENCE WAS NOT ACHIEVED XXX"))
return False
def SolveSolutionStep(self):
num_coupling_interfaces = self.settings["coupling_interfaces"].size()
self.__CustomPrint(
1,
colors.green("Starting import") + " of CouplingInterfaceData ...")
for i in range(num_coupling_interfaces):
coupling_interface_settings = self.settings["coupling_interfaces"][
i]
if not coupling_interface_settings.Has("data_field_recv"):
continue
sub_model_part_name = coupling_interface_settings[
"sub_model_part_name"].GetString()
data_field_settings = coupling_interface_settings[
"data_field_recv"]
data_field_name = data_field_settings["data_field_name"].GetString(
)
self.__CustomPrint(
2,
colors.green('Importing') +
' data-field "{}" on ModelPart "{}"'.format(
data_field_name, sub_model_part_name))
variables = GenerateVariableListFromInput(
data_field_settings["variables"])
if not self.dry_run:
KratosCoSim.EMPIRE_API.EMPIRE_API_recvDataField(
self.model["ExtSolver." + sub_model_part_name],
data_field_name,
*variables) # passing all varibales from the list
else:
self.__CustomPrint(2, colors.magenta('... skipped'))
self.__CustomPrint(
1,
colors.green("Finished import") + " of CouplingInterfaceData")
if self.echo_level > 0: print() # newline
self.__CustomPrint(1, colors.blue("Solving ..."))
time.sleep(self.solving_time)
self.__CustomPrint(2,
"Solving took {} [sec]".format(self.solving_time))
if self.echo_level > 0: print() # newline
# TODO implement random values ... ?
self.__CustomPrint(
1,
colors.cyan("Starting export") + " of CouplingInterfaceData ...")
for i in range(num_coupling_interfaces):
coupling_interface_settings = self.settings["coupling_interfaces"][
i]
if not coupling_interface_settings.Has("data_field_send"):
continue
sub_model_part_name = coupling_interface_settings[
"sub_model_part_name"].GetString()
data_field_settings = coupling_interface_settings[
"data_field_send"]
data_field_name = data_field_settings["data_field_name"].GetString(
)
self.__CustomPrint(
2,
colors.cyan('Exporting') +
' data-field "{}" on ModelPart "{}"'.format(
data_field_name, sub_model_part_name))
variables = GenerateVariableListFromInput(
data_field_settings["variables"])
if not self.dry_run:
KratosCoSim.EMPIRE_API.EMPIRE_API_sendDataField(
self.model["ExtSolver." + sub_model_part_name],
data_field_name,
*variables) # passing all varibales from the list
else:
self.__CustomPrint(2, colors.magenta('... skipped'))
self.__CustomPrint(
1,
colors.cyan("Finished export") + " of CouplingInterfaceData")
