def _cls_setstate(self, _function): """ For class dependent attribute retrieval override this method! :param state: FunctionProto :return: None """ self.attr = dict([pb2attr(attr) for attr in _function.attr])
def __copy__(self): result = self.__class__.__new__(self.__class__) result._id_name = self._id_name result.input_mapping = dict(self.input_mapping) result.variables = [v.__copy__() for v in self.variables] result.attr = dict([pb2attr(attr2pb(key, value)) for key, value in self.attr.items()]) return result
def __setstate__(self, state):
def build_function(pb):
result = Function.__new__(Function)
result.__setstate__(pb)
return result
if isinstance(state, str) or isinstance(state, bytes):
_nn = NeuralNetworkProto()
_nn.ParseFromString(state)
elif isinstance(state, NeuralNetworkProto):
_nn = state
else:
return
self._id_name = _nn.id_name
self.output_targets = dict([pb2val(v) for v in _nn.output_ntss.v])
self.function_cls = [
Function.getClassByName(f_cls) for f_cls in _nn.function_cls
]
self._inputs = dict([(ioMP.in_label, (ioMP.out_label, ioMP.df_id_name))
for ioMP in _nn.input_mapping])
self.output_mapping = dict([(ioMP.in_label, (ioMP.out_label,
ioMP.df_id_name))
for ioMP in _nn.output_mapping])
self.functions = [build_function(_f) for _f in _nn.functions]
self.attr = dict([pb2attr(attr) for attr in _nn.attr])
self.input_mapping = self.attr.pop(self.arg_INPUTS)
def __setstate__(self, state):
if isinstance(state, str) or isinstance(state, bytes):
_initializer = InitializerProto()
_initializer.ParseFromString(state)
elif isinstance(state, InitializerProto):
_initializer = state
else:
return
for sub_cls in Initializer.__subclasses__():
if sub_cls.__name__ == _initializer.cls_name:
self.__class__ = sub_cls
break
self.attr = dict([pb2attr(attr) for attr in _initializer.attr])
def __setstate__(self, state):
if isinstance(state, str) or isinstance(state, bytes):
_regularisation = RegularisationProto()
_regularisation.ParseFromString(state)
elif isinstance(state, RegularisationProto):
_regularisation = state
else:
return
for sub_cls in Regularisation.__subclasses__():
if sub_cls.__name__ == _regularisation.cls_name:
self.__class__ = sub_cls
break
self.attr = dict([pb2attr(attr) for attr in _regularisation.attr])
def __setstate__(self, state):
if isinstance(state, str) or isinstance(state, bytes):
_cmp = CompareClassProto()
_cmp.ParseFromString(state)
elif isinstance(state, CompareClassProto):
_cmp = state
else:
return
attr = dict([pb2attr(pb) for pb in state.attr])
self.primary_objective = attr.get(self.arg_PRIMARY_OBJECTIVE,
Accuracy.ID)
self.primary_alpha = attr.get(self.arg_PRIMARY_ALPHA, 1)
self.primary_threshold = attr.get(self.arg_PRIMARY_THRESHOLD, .6)
self.secondary_objectives = attr.get(self.arg_SECONDARY_OBJECTIVES, {})
def recombine(self, other):
result = WeightAgnosticIndividual.__new__(WeightAgnosticIndividual)
result.metrics = dict()
result.attr = dict(
[pb2attr(attr2pb(key, value)) for key, value in self.attr.items()])
result._data_nts = {
label: (nts.__copy__(), id_name)
for label, (nts, id_name) in self._data_nts.items()
}
result._losses = list(self._losses)
result.loss = self.loss
result._networks = self.network.recombine(other.network)
result.network = result._networks[0]
result._id_name = self.getNewName()
return [result]
def mutate(self, prob):
result = ClassifierIndividualOPACDG.__new__(ClassifierIndividualOPACDG)
result.metrics = dict()
result.attr = dict(
[pb2attr(attr2pb(key, value)) for key, value in self.attr.items()])
result._data_nts = {
label: (nts.__copy__(), id_name)
for label, (nts, id_name) in self._data_nts.items()
}
result._losses = list(self._losses)
result.loss = self.loss
result.network = self.network.mutate(prob=prob)[0]
result._networks = [result.network]
result._id_name = self.getNewName()
return [result]
def __setstate__(self, state):
if isinstance(state, str) or isinstance(state, bytes):
_dataset = DatasetProto()
_dataset.ParseFromString(state)
elif isinstance(state, DatasetProto):
_dataset = state
else:
return
cls_name = _dataset.cls_name
try:
self.__class__ = DatasetInterface.getClassByName(cls_name)
except:
pass
self._id_name = _dataset.name_val
attr_d = dict([pb2attr(attr) for attr in _dataset.attr_val])
self.restore_attributes(attr_d)
def __setstate__(self, state):
if isinstance(state, str) or isinstance(state, bytes):
_nn = NeuralNetworkProto()
_nn.ParseFromString(state)
elif isinstance(state, NeuralNetworkProto):
_nn = state
else:
return
self._id_name = _nn.id_name
self.function_cls = [Function.getClassByName(f_cls) for f_cls in _nn.function_cls]
self.output_targets = dict([pb2val(v) for v in _nn.output_ntss.v])
self._inputs = dict([(ioMP.in_label, (ioMP.out_label, ioMP.df_id_name)) for ioMP in _nn.input_mapping])
self.output_mapping = dict([(ioMP.in_label, (ioMP.out_label, ioMP.df_id_name)) for ioMP in _nn.output_mapping])
self.functions = [Function.get_instance(_f) for _f in _nn.functions]
self.variable_pool = dict()
for _v in _nn.variables:
v_ = Variable.__new__(Variable)
v_.__setstate__(_v)
self.variable_pool[v_.name] = self.variable_pool.get(v_.name, []) + [v_]
self.attr = dict([pb2attr(attr) for attr in _nn.attr])
def _cls_setstate(self, state):
"""
Individual specific reconstruction from ProtobufIndividual object or serialised ProtobufIndividual object.
For class dependent attribute retrieval override this method!
:param state: optional result ProtobufIndividual object to modify; if None, one is created
:return: ProtobufIndividual object
"""
if isinstance(state, str) or isinstance(state, bytes):
_individual = IndividualProto()
_individual.ParseFromString(state)
elif isinstance(state, IndividualProto):
_individual = state
else:
return
self._id_name = _individual.id_name
self.metrics = dict([(m.id_name, m.value)
for m in _individual.metrics])
self.attr = dict([
pb2attr(attr) for attr in _individual.attr
if attr.name != self.arg_METRICS
])
def distinct_copy(self):
result = NeuralNetwork.__new__(NeuralNetwork)
result._id_name = self.id_name
result.function_cls = list(self.function_cls)
result.output_targets = dict([(label, value.__copy__()) for label, value in self.output_targets.items()])
result._inputs = dict(self._inputs)
result.output_mapping = dict(self.output_mapping)
result.functions = list()
function_mapping = dict()
for _f in self.functions:
new_f = Function.__new__(Function)
new_f.__setstate__(_f.get_pb())
new_f._id_name = new_f.getNewName(new_f)
result.functions.append(new_f)
function_mapping[_f.id_name] = new_f.id_name
for _f in result.functions:
for key, (v1, old_f_id) in _f.input_mapping.items():
_f.input_mapping[key] = (v1, function_mapping.get(old_f_id, old_f_id))
for in_label, (out_label, f_id) in result.output_mapping.items():
result.output_mapping[in_label] = (out_label, function_mapping.get(f_id, f_id))
result.variable_pool = dict([(key, list(value_l)) for key, value_l in self.variable_pool.items()])
result.attr = dict([pb2attr(attr) for attr in [attr2pb(key, value) for key, value in self.attr.items()]])
return result
def __copy__(self):
result = WeightAgnosticNeuralNetwork.__new__(
WeightAgnosticNeuralNetwork)
result.input_mapping = {
key: (l0, v.__copy__(), l1)
for key, (l0, v, l1) in self.input_mapping.items()
}
result.output_targets = {
key: ts.__copy__()
for key, ts in self.output_targets.items()
}
result.function_cls = list(self.function_cls)
result._inputs = {k: (v0, v1) for k, (v0, v1) in self._inputs.items()}
result.output_mapping = {
k: (v0, v1)
for k, (v0, v1) in self.output_mapping.items()
}
result.functions = [f.__copy__() for f in self.functions]
result.attr = dict(
[pb2attr(attr2pb(key, value)) for key, value in self.attr.items()])
self._id_name = self.getNewName()
return result
