def ExecuteInitialize(self):
self.interval = KratosMultiphysics.Vector(2)
self.interval[0] = self.params["interval"][0].GetDouble()
self.interval[1] = self.params["interval"][1].GetDouble()
self.print_drag_to_screen = self.params["print_drag_to_screen"].GetBool()
self.write_drag_output_file = self.params["write_drag_output_file"].GetBool()
if (self.model_part.GetCommunicator().MyPID() == 0):
if (self.write_drag_output_file):
output_file_name = self.params["model_part_name"].GetString() + "_drag.dat"
file_handler_params = KratosMultiphysics.Parameters(self.params["output_file_settings"])
if file_handler_params.Has("file_name"):
warn_msg = 'Unexpected user-specified entry found in "output_file_settings": {"file_name": '
warn_msg += '"' + file_handler_params["file_name"].GetString() + '"}\n'
warn_msg += 'Using this specififed file name instead of the default "' + output_file_name + '"'
KratosMultiphysics.Logger.PrintWarning("ComputeDragProcess", warn_msg)
else:
file_handler_params.AddEmptyValue("file_name")
file_handler_params["file_name"].SetString(output_file_name)
file_header = self._GetFileHeader()
self.output_file = TimeBasedAsciiFileWriterUtility(self.model_part,
file_handler_params, file_header).file
def __init__(self, Model, settings):
KratosMultiphysics.Process.__init__(self)
default_settings = KratosMultiphysics.Parameters("""
{
"model_part_name" : "please_specify_model_part_name",
"interval" : [0.0, 1e30],
"reference_point" : [0.0, 0.0, 0.0],
"print_drag_to_screen" : false,
"print_format" : ".8f",
"write_drag_output_file" : true,
"output_file_settings": {}
}
""")
self.settings = settings
# Detect "End" as a tag and replace it by a large number
if (self.settings.Has("interval")):
if (self.settings["interval"][1].IsString()):
if (self.settings["interval"][1].GetString() == "End"):
self.settings["interval"][1].SetDouble(1e30)
else:
raise Exception(
"The second value of interval can be \"End\" or a number, interval currently:"
+ self.settings["interval"].PrettyPrintJsonString())
self.settings.ValidateAndAssignDefaults(default_settings)
self.model_part = Model[self.settings["model_part_name"].GetString()]
self.interval = KratosMultiphysics.Vector(2)
self.interval[0] = self.settings["interval"][0].GetDouble()
self.interval[1] = self.settings["interval"][1].GetDouble()
self.print_drag_to_screen = self.settings[
"print_drag_to_screen"].GetBool()
self.write_drag_output_file = self.settings[
"write_drag_output_file"].GetBool()
self.format = self.settings["print_format"].GetString()
# PMT: added reference point for moment calculation
self.reference_x = self.settings["reference_point"][0].GetDouble()
self.reference_y = self.settings["reference_point"][1].GetDouble()
self.reference_z = self.settings["reference_point"][2].GetDouble()
if (self.model_part.GetCommunicator().MyPID() == 0):
if (self.write_drag_output_file):
file_handler_params = KratosMultiphysics.Parameters(
settings["output_file_settings"])
file_header = self._GetFileHeader()
self.output_file = TimeBasedAsciiFileWriterUtility(
self.model_part, file_handler_params, file_header).file
def ExecuteInitialize(self):
self.interval = KratosMultiphysics.Vector(2)
self.interval[0] = self.params["interval"][0].GetDouble()
self.interval[1] = self.params["interval"][1].GetDouble()
self.print_to_screen = self.params["print_to_screen"].GetBool()
self.write_output_file = self.params["write_output_file"].GetBool()
if (self.model_part.GetCommunicator().MyPID() == 0):
if (self.write_output_file):
file_handler_params = KratosMultiphysics.Parameters(
self.params["output_file_settings"])
file_header = self._GetFileHeader()
self.output_file = TimeBasedAsciiFileWriterUtility(
self.model_part, file_handler_params, file_header).file
def ExecuteInitialize(self):
# getting the ModelPart from the Model
model_part_name = self.params["model_part_name"].GetString()
if model_part_name == "":
raise Exception('No "model_part_name" was specified!')
self.model_part = self.model[model_part_name]
# retrieving the position of the entity
point_position = self.params["position"].GetVector()
if point_position.Size() != 3:
raise Exception(
'The position has to be provided with 3 coordinates!')
point = KratosMultiphysics.Point(point_position[0], point_position[1],
point_position[2])
# retrieving the output variables
output_var_names = self.params["output_variables"]
variable_names = [
output_var_names[i].GetString()
for i in range(output_var_names.size())
]
output_vars = [
KratosMultiphysics.KratosGlobals.GetVariable(var)
for var in variable_names
]
if len(output_vars) == 0:
raise Exception('No variables specified for output!')
self.output_variables.append(output_vars)
# validate types of variables
for var in self.output_variables[0]:
self.__CheckVariableIsSolutionStepVariable(var)
if type(var) == KratosMultiphysics.DoubleVariable:
continue
elif type(var) == KratosMultiphysics.Array1DVariable3:
continue
elif type(var) == KratosMultiphysics.Array1DComponentVariable:
continue
else:
err_msg = 'Type of variable "' + var.Name(
) + '" is not valid\n'
err_msg += 'It can only be double, component or array3d!'
raise Exception(err_msg)
# retrieving the entity type
entity_type = self.params["entity_type"].GetString()
if entity_type == "node":
tol = 1e-12
found_id = KratosMultiphysics.BruteForcePointLocator(
self.model_part).FindNode(point, tol)
if found_id > -1:
self.entity.append(self.model_part.Nodes[found_id]
) # note that this is a find!
self.area_coordinates.append(
"dummy") # needed for looping later
elif entity_type == "element":
self.sf_values = KratosMultiphysics.Vector()
found_id = KratosMultiphysics.BruteForcePointLocator(
self.model_part).FindElement(point, self.sf_values)
if found_id > -1:
self.entity.append(self.model_part.Elements[found_id]
) # note that this is a find!
self.area_coordinates.append(self.sf_values)
elif entity_type == "condition":
self.sf_values = KratosMultiphysics.Vector()
found_id = KratosMultiphysics.BruteForcePointLocator(
self.model_part).FindCondition(point, self.sf_values)
if found_id > -1:
self.entity.append(self.model_part.Conditions[found_id]
) # note that this is a find!
self.area_coordinates.append(self.sf_values)
else:
err_msg = 'Invalid "entity_type" specified, it can only be:\n'
err_msg += '"node", "element", "condition"'
raise Exception(err_msg)
# Check if a point was found, and initalize output
# NOTE: If the search was not successful (i.e. found_id = -1), we fail silently and
# do nothing. This is BY DESIGN, as we are supposed to work on MPI too, and the point
# in question might lie on a different partition.
# Here we also check if the point has been found in more than one partition
# In sich a case only one rank (the one with the larger PID) writes the output!
my_rank = -1 # dummy to indicate that the point is not in my partition
if found_id > -1: # the point lies in my partition
my_rank = self.model_part.GetCommunicator().MyPID()
writing_rank = self.model_part.GetCommunicator().MaxAll(
my_rank) # The partition with the larger rank writes
if my_rank == writing_rank:
file_handler_params = KratosMultiphysics.Parameters(
self.params["output_file_settings"])
file_header = GetFileHeader(entity_type, found_id, point,
self.output_variables[0])
self.output_file.append(
TimeBasedAsciiFileWriterUtility(self.model_part,
file_handler_params,
file_header).file)
class ComputeDragProcess(KratosMultiphysics.Process):
"""
Auxiliary base class to output total flow forces
over obstacles in fluid dynamics problems.
A derived class needs to be implemented to be able to use
this functionality, as calling the base class alone is not enough.
"""
def __init__(self, model, params ):
"""
Auxiliary class to output total flow forces over obstacles
in fluid dynamics problems for a body fitted model part.
"""
super(ComputeDragProcess,self).__init__()
default_settings = KratosMultiphysics.Parameters("""
{
"model_part_name" : "",
"interval" : [0.0, 1e30],
"print_drag_to_screen" : false,
"print_format" : ".8f",
"write_drag_output_file" : true,
"output_file_settings": {}
}
""")
self.params = params
# Detect "End" as a tag and replace it by a large number
if(self.params.Has("interval")):
if(self.params["interval"][1].IsString()):
if(self.params["interval"][1].GetString() == "End"):
self.params["interval"][1].SetDouble(1e30)
else:
raise Exception("The second value of interval can be \"End\" or a number, interval currently:"+self.params["interval"].PrettyPrintJsonString())
self.params.ValidateAndAssignDefaults(default_settings)
self.format = self.params["print_format"].GetString()
# getting the ModelPart from the Model
model_part_name = self.params["model_part_name"].GetString()
if model_part_name == "":
raise Exception('No "model_part_name" was specified!')
else:
self.model_part = model[self.params["model_part_name"].GetString()]
def ExecuteInitialize(self):
self.interval = KratosMultiphysics.Vector(2)
self.interval[0] = self.params["interval"][0].GetDouble()
self.interval[1] = self.params["interval"][1].GetDouble()
self.print_drag_to_screen = self.params["print_drag_to_screen"].GetBool()
self.write_drag_output_file = self.params["write_drag_output_file"].GetBool()
if (self.model_part.GetCommunicator().MyPID() == 0):
if (self.write_drag_output_file):
output_file_name = self.params["model_part_name"].GetString() + "_drag.dat"
file_handler_params = KratosMultiphysics.Parameters(self.params["output_file_settings"])
if file_handler_params.Has("file_name"):
warn_msg = 'Unexpected user-specified entry found in "output_file_settings": {"file_name": '
warn_msg += '"' + file_handler_params["file_name"].GetString() + '"}\n'
warn_msg += 'Using this specififed file name instead of the default "' + output_file_name + '"'
KratosMultiphysics.Logger.PrintWarning("ComputeDragProcess", warn_msg)
else:
file_handler_params.AddEmptyValue("file_name")
file_handler_params["file_name"].SetString(output_file_name)
file_header = self._GetFileHeader()
self.output_file = TimeBasedAsciiFileWriterUtility(self.model_part,
file_handler_params, file_header).file
def ExecuteFinalizeSolutionStep(self):
current_time = self.model_part.ProcessInfo[KratosMultiphysics.TIME]
if((current_time >= self.interval[0]) and (current_time < self.interval[1])):
# Compute the drag force
drag_force = self._GetCorrespondingDragForce()
# Write the drag force values
if (self.model_part.GetCommunicator().MyPID() == 0):
if (self.print_drag_to_screen):
result_msg = str(current_time) + " x-drag: " + format(drag_force[0],self.format) + " y-drag: " + format(drag_force[1],self.format) + " z-drag: " + format(drag_force[2],self.format)
self._PrintToScreen(result_msg)
if (self.write_drag_output_file):
self.output_file.write(format(current_time, self.format)+" "+format(drag_force[0],self.format)+" "+format(drag_force[1],self.format)+" "+format(drag_force[2],self.format)+"\n")
def ExecuteFinalize(self):
if (self.model_part.GetCommunicator().MyPID() == 0):
self.output_file.close()
def _GetFileHeader(self):
err_msg = 'ComputeDragProcess: _GetFileHeader called in base class\n'
err_msg += 'this needs to be implemented and called from derived class'
raise Exception(err_msg)
def _PrintToScreen(self,result_msg):
err_msg = 'ComputeDragProcess: _PrinToScreen called in base class\n'
err_msg += 'this needs to be implemented and called from derived class'
raise Exception(err_msg)
def _GetCorrespondingDragForce(self):
err_msg = 'ComputeDragProcess: _GetCorrespondingDragForce called in base class\n'
err_msg += 'this needs to be implemented and called from derived class'
raise Exception(err_msg)
class ComputeCustomBaseReactionProcess(KratosMultiphysics.Process):
def __init__(self, Model, settings):
KratosMultiphysics.Process.__init__(self)
default_settings = KratosMultiphysics.Parameters("""
{
"model_part_name" : "please_specify_model_part_name",
"interval" : [0.0, 1e30],
"reference_point" : [0.0, 0.0, 0.0],
"print_drag_to_screen" : false,
"print_format" : ".8f",
"write_drag_output_file" : true,
"output_file_settings": {}
}
""")
self.settings = settings
# Detect "End" as a tag and replace it by a large number
if (self.settings.Has("interval")):
if (self.settings["interval"][1].IsString()):
if (self.settings["interval"][1].GetString() == "End"):
self.settings["interval"][1].SetDouble(1e30)
else:
raise Exception(
"The second value of interval can be \"End\" or a number, interval currently:"
+ self.settings["interval"].PrettyPrintJsonString())
self.settings.ValidateAndAssignDefaults(default_settings)
self.model_part = Model[self.settings["model_part_name"].GetString()]
self.interval = KratosMultiphysics.Vector(2)
self.interval[0] = self.settings["interval"][0].GetDouble()
self.interval[1] = self.settings["interval"][1].GetDouble()
self.print_drag_to_screen = self.settings[
"print_drag_to_screen"].GetBool()
self.write_drag_output_file = self.settings[
"write_drag_output_file"].GetBool()
self.format = self.settings["print_format"].GetString()
# PMT: added reference point for moment calculation
self.reference_x = self.settings["reference_point"][0].GetDouble()
self.reference_y = self.settings["reference_point"][1].GetDouble()
self.reference_z = self.settings["reference_point"][2].GetDouble()
if (self.model_part.GetCommunicator().MyPID() == 0):
if (self.write_drag_output_file):
file_handler_params = KratosMultiphysics.Parameters(
settings["output_file_settings"])
file_header = self._GetFileHeader()
self.output_file = TimeBasedAsciiFileWriterUtility(
self.model_part, file_handler_params, file_header).file
def ExecuteFinalizeSolutionStep(self):
current_time = self.model_part.ProcessInfo[KratosMultiphysics.TIME]
if ((current_time >= self.interval[0])
and (current_time < self.interval[1])):
# Note that MPI communication is done within VariableUtils().SumHistoricalNodeVectorVariable()
#reaction_vector = KratosMultiphysics.VariableUtils().SumHistoricalNodeVectorVariable(KratosMultiphysics.REACTION, self.model_part, 0)
# PMT: TODO: only checked for OpenMP, update for MPI
fx = 0.0
fy = 0.0
fz = 0.0
mx = 0.0
my = 0.0
mz = 0.0
for node in self.model_part.Nodes:
reaction = node.GetSolutionStepValue(
KratosMultiphysics.REACTION, 0)
moment_reaction = node.GetSolutionStepValue(
KratosMultiphysics.REACTION_MOMENT, 0)
# PMT: NOTE: sign is flipped to go from reaction to action
fx += (-1) * reaction[0]
fy += (-1) * reaction[1]
fz += (-1) * reaction[2]
x = node.X - self.reference_x
y = node.Y - self.reference_y
z = node.Z - self.reference_z
mx += y * (-1) * reaction[2] - z * (-1) * reaction[1] + (
-1) * moment_reaction[0]
my += z * (-1) * reaction[0] - x * (-1) * reaction[2] + (
-1) * moment_reaction[1]
mz += x * (-1) * reaction[1] - y * (-1) * reaction[0] + (
-1) * moment_reaction[2]
if (self.model_part.GetCommunicator().MyPID() == 0):
if (self.print_drag_to_screen):
print("CUSTOM BASE REACTION RESULTS:")
print("Current time: " + str(current_time))
print("Forces:" + " Fx: " + str(fx) + " Fy: " + str(fy) +
" Fz: " + str(fz))
print("Moments:" + " Mx: " + str(mx) + " My: " + str(my) +
" Mz: " + str(mz))
if (self.write_drag_output_file):
# with open(self.drag_filename, 'a') as file:
# output_str = str(current_time)
# output_str += " " + str(fx) + " " + str(fy) + " " + str(fz)
# output_str += " " + str(mx) + " " + str(my) + " " + str(mz) + "\n"
# file.write(output_str)
# file.close()
# if (self.write_output_file):
# output_str = str(current_time)
# output_str += " " + format(fx, self.format) + " " + format(fy, self.format) + " " + format(fz, self.format)
# output_str += " " + format(mx, self.format) + " " + format(my, self.format) + " " + format(mz, self.format) + "\n"
output_str = str(current_time)
output_str += " " + str(fx) + " " + str(
fy) + " " + str(fz)
output_str += " " + str(mx) + " " + str(
my) + " " + str(mz) + "\n"
self.output_file.write(output_str)
# self.output_file.write(str(current_time)+" "+format(integral_value[0], self.format)+" "+format(
# integral_value[1], self.format)+" "+format(integral_value[2], self.format)+"\n")
def _GetFileHeader(self):
header = '# Integral value for model part ' + self.settings[
"model_part_name"].GetString() + 'at reference point X = ' + str(
self.reference_x) + ', Y = ' + str(
self.reference_y) + ', Z = ' + str(self.reference_z) + '\n'
header += '# Time Fx: Fy: Fz: Mx: My: Mz:\n'
return header
def ExecuteFinalize(self):
if (self.model_part.GetCommunicator().MyPID() == 0):
self.output_file.close()
class ComputeIntegralValueProcess(KratosMultiphysics.Process):
"""
Auxiliary base class to output total flow forces
over obstacles in fluid dynamics problems.
A derived class needs to be implemented to be able to use
this functionality, as calling the base class alone is not enough.
"""
def __init__(self, model, params):
"""
Auxiliary class to output total flow forces over obstacles
in fluid dynamics problems for a body fitted model part.
"""
KratosMultiphysics.Process.__init__(self)
default_settings = KratosMultiphysics.Parameters("""
{
"model_part_name" : "",
"interval" : [0.0, 1e30],
"print_to_screen" : false,
"variable_name" : "",
"print_format" : ".8f",
"write_output_file" : true,
"output_file_settings": {}
}
""")
self.kratos_vars = {} # dict storing name-KratosVars,
# hopefully faster than accessing KratosComponents all the time
self.params = params
# Detect "End" as a tag and replace it by a large number
if (self.params.Has("interval")):
if (self.params["interval"][1].IsString()):
if (self.params["interval"][1].GetString() == "End"):
self.params["interval"][1].SetDouble(1e30)
else:
raise Exception(
"The second value of interval can be \"End\" or a number, interval currently:"
+ self.params["interval"].PrettyPrintJsonString())
self.params.ValidateAndAssignDefaults(default_settings)
self.format = self.params["print_format"].GetString()
# getting the ModelPart from the Model
self.model_part_name = self.params["model_part_name"].GetString()
if self.model_part_name == "":
raise Exception('No "model_part_name" was specified!')
else:
self.model_part = model[self.model_part_name]
self.var_name = self.params["variable_name"].GetString()
if self.var_name == "":
raise Exception('No "var_name" was specified!')
else:
self.var = self.__GetKratosVariable(self.var_name)
def ExecuteInitialize(self):
self.interval = KratosMultiphysics.Vector(2)
self.interval[0] = self.params["interval"][0].GetDouble()
self.interval[1] = self.params["interval"][1].GetDouble()
self.print_to_screen = self.params["print_to_screen"].GetBool()
self.write_output_file = self.params["write_output_file"].GetBool()
if (self.model_part.GetCommunicator().MyPID() == 0):
if (self.write_output_file):
file_handler_params = KratosMultiphysics.Parameters(
self.params["output_file_settings"])
file_header = self._GetFileHeader()
self.output_file = TimeBasedAsciiFileWriterUtility(
self.model_part, file_handler_params, file_header).file
def ExecuteFinalizeSolutionStep(self):
current_time = self.model_part.ProcessInfo[KratosMultiphysics.TIME]
if ((current_time >= self.interval[0])
and (current_time < self.interval[1])):
# Compute the force
integral_value = self._GetCorrespondingIntegralValue()
# Write the value components
if (self.model_part.GetCommunicator().MyPID() == 0):
if (self.print_to_screen):
result_msg='Integral value for model part ' + \
self.model_part_name + ' and variable ' + self.var_name + '\n'
result_msg += str(current_time) + " x-comp: " + format(
integral_value[0], self.format) + " y-comp: " + format(
integral_value[1],
self.format) + " z-comp: " + format(
integral_value[2], self.format)
self._PrintToScreen(result_msg)
# not formatting time in order to not lead to problems with time recognition
# in the file writer when restarting
if (self.write_output_file):
self.output_file.write(
str(current_time) + " " +
format(integral_value[0], self.format) + " " +
format(integral_value[1], self.format) + " " +
format(integral_value[2], self.format) + "\n")
def ExecuteFinalize(self):
if (self.model_part.GetCommunicator().MyPID() == 0):
self.output_file.close()
def _GetFileHeader(self):
header = '# Integral value for model part ' + self.model_part_name + ' and variable ' + self.var_name + '\n'
header += '# Time VectorVal[0] VectorVal[1] VectorVal[2]\n'
return header
def _PrintToScreen(self, result_msg):
KratosMultiphysics.Logger.PrintInfo("ComputeIntegralValueProcess",
"INTEGRAL VALUE RESULTS:")
KratosMultiphysics.Logger.PrintInfo("ComputeIntegralValueProcess",
"Current time: " + result_msg)
def _GetCorrespondingIntegralValue(self):
# TODO: for now no type-check, should be checked if vector or not...
'''
SOMETHING LIKE THIS:
if type(kratos_var) == KratosMultiphysics.DoubleVariable or type(kratos_var) == KratosMultiphysics.Array1DComponentVariable:
SetData(model_part, kratos_var, data_array)
elif type(kratos_var) == KratosMultiphysics.Array1DVariable3:
domain_size = model_part.ProcessInfo[KratosMultiphysics.DOMAIN_SIZE]
if not domain_size in [1,2,3]:
raise Exception("DOMAIN_SIZE has to be 1, 2 or 3!")
num_nodes = NumberOfNodes(model_part)
if data_array.size != num_nodes*domain_size:
raise Exception("Size of data does not match number of nodes x domain size!")
ext = ["_X", "_Y", "_Z"]
for i in range(domain_size):
component_var = self.__GetKratosVariable(kratos_var.Name()+ext[i])
range_begin = i*num_nodes
range_end = (i+1)*num_nodes
SetData(model_part, component_var, data_array[range_begin:range_end])
else:
err_msg = 'Type of variable "' + kratos_var.Name() + '" is not valid\n'
err_msg += 'It can only be double, component or array3d!'
raise Exception(err_msg)
'''
vector_val = [0.0, 0.0, 0.0]
for node in self.model_part.Nodes:
nodal_result = node.GetSolutionStepValue(self.var, 0)
vector_val[0] += nodal_result[0]
vector_val[1] += nodal_result[1]
vector_val[2] += nodal_result[2]
return vector_val
def __GetKratosVariable(self, var_name):
if not var_name in self.kratos_vars:
self.kratos_vars[
var_name] = KratosMultiphysics.KratosGlobals.GetVariable(
var_name)
return self.kratos_vars[var_name]