def main():
observations = load_titanic()
# Transform the data set, using keras_pandas
categorical_vars = ['pclass', 'sex', 'survived']
numerical_vars = [
'age', 'siblings_spouses_aboard', 'parents_children_aboard', 'fare'
]
text_vars = ['name']
auto = Automater(categorical_vars=categorical_vars,
numerical_vars=numerical_vars,
text_vars=text_vars,
response_var='survived')
X, y = auto.fit_transform(observations)
# Start model with provided input nub
x = auto.input_nub
# Fill in your own hidden layers
x = Dense(256)(x)
x = Dense(256, activation='relu')(x)
x = Dense(256)(x)
# End model with provided output nub
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='Adam', loss=auto.loss, metrics=['accuracy'])
# Train model
model.fit(X, y, epochs=15, validation_split=.2)
def main():
# List out which components are supplied by Automater
# In this example, we're utilizing X and y generated by the Automater, auto.input_nub, auto.input_layers,
# auto.output_nub, and auto.suggest_loss
save_results = True
# Load data
observations = lib.load_lending_club()
print('Observation columns: {}'.format(list(observations.columns)))
print('Class balance:\n {}'.format(observations['loan_status'].value_counts()))
# Train /test split
train_observations, test_observations = train_test_split(observations)
train_observations = train_observations.copy()
test_observations = test_observations.copy()
# List out variable types
data_type_dict = {'numerical': ['loan_amnt', 'annual_inc', 'open_acc', 'dti', 'delinq_2yrs',
'inq_last_6mths', 'mths_since_last_delinq', 'pub_rec', 'revol_bal',
'revol_util',
'total_acc', 'pub_rec_bankruptcies'],
'categorical': ['term', 'grade', 'emp_length', 'home_ownership', 'loan_status', 'addr_state',
'application_type', 'disbursement_method'],
'text': ['desc', 'purpose', 'title']}
output_var = 'loan_status'
# Create and fit Automater
auto = Automater(data_type_dict=data_type_dict, output_var=output_var)
auto.fit(train_observations)
# Transform data
train_X, train_y = auto.fit_transform(train_observations)
test_X, test_y = auto.transform(test_observations)
# Create and fit keras (deep learning) model.
x = auto.input_nub
x = Dense(32)(x)
x = Dense(32)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='adam', loss=auto.suggest_loss())
model.fit(train_X, train_y)
# Make model predictions and inverse transform model predictions, to get usable results
pred_test_y = model.predict(test_X)
auto.inverse_transform_output(pred_test_y)
# Save all results
if save_results:
temp_dir = lib.get_temp_dir()
model.save(os.path.join(temp_dir, 'model.h5py'))
pickle.dump(train_X, open(os.path.join(temp_dir, 'train_X.pkl'), 'wb'))
pickle.dump(train_y, open(os.path.join(temp_dir, 'train_y.pkl'), 'wb'))
pickle.dump(test_X, open(os.path.join(temp_dir, 'test_X.pkl'), 'wb'))
pickle.dump(test_y, open(os.path.join(temp_dir, 'test_y.pkl'), 'wb'))
pickle.dump(pred_test_y, open(os.path.join(temp_dir, 'pred_test_y.pkl'), 'wb'))
def main():
# TODO List out which components are supplied by Automater
# In this example, we're utilizing X and y generated by the Automater, auto.input_nub, auto.input_layers,
# auto.output_nub, and auto.suggest_loss
save_results = True
# TODO Load data
observations = None
print('Observation columns: {}'.format(list(observations.columns)))
# TODO Train /test split
train_observations, test_observations = train_test_split(observations)
train_observations = train_observations.copy()
test_observations = test_observations.copy()
# TODO List out variable types
data_type_dict = {
'numerical': [],
'categorical': [],
'text': [],
'timeseries': []
}
output_var = None
# Create and fit Automater
auto = Automater(data_type_dict=data_type_dict, output_var=output_var)
auto.fit(train_observations)
# Transform data
train_X, train_y = auto.fit_transform(train_observations)
test_X, test_y = auto.transform(test_observations)
# TODO Create and fit keras (deep learning) model.
x = auto.input_nub
x = Dense(32)(x)
x = Dense(32)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='adam', loss=auto.suggest_loss())
model.fit(train_X, train_y)
# Make model predictions and inverse transform model predictions, to get usable results
pred_test_y = model.predict(test_X)
auto.inverse_transform_output(pred_test_y)
# Save all results
if save_results:
temp_dir = lib.get_temp_dir()
model.save(os.path.join(temp_dir, 'model.h5py'))
pickle.dump(train_X, open(os.path.join(temp_dir, 'train_X.pkl'), 'wb'))
pickle.dump(train_y, open(os.path.join(temp_dir, 'train_y.pkl'), 'wb'))
pickle.dump(test_X, open(os.path.join(temp_dir, 'test_X.pkl'), 'wb'))
pickle.dump(test_y, open(os.path.join(temp_dir, 'test_y.pkl'), 'wb'))
pickle.dump(pred_test_y,
open(os.path.join(temp_dir, 'pred_test_y.pkl'), 'wb'))
def main():
logging.getLogger().setLevel(logging.INFO)
# Reference variables
test_run = True
observations = load_lending_club()
if test_run:
observations = observations.sample(n=100)
# Transform the data set, using keras_pandas
categorical_vars = [
'term', 'grade', 'sub_grade', 'emp_length', 'home_ownership',
'verification_status', 'issue_d', 'pymnt_plan', 'purpose',
'addr_state', 'initial_list_status', 'application_type',
'disbursement_method', 'loan_status'
]
numerical_vars = [
'loan_amnt', 'funded_amnt', 'funded_amnt_inv', 'annual_inc',
'installment', 'dti', 'inq_last_6mths', 'open_acc', 'pub_rec',
'revol_bal', 'total_acc', 'pub_rec_bankruptcies', 'int_rate',
'revol_util'
]
text_vars = ['desc', 'title']
for categorical_var in categorical_vars:
observations[categorical_var] = observations[categorical_var].fillna(
'None')
observations[categorical_var] = observations[categorical_var].apply(
str)
auto = Automater(categorical_vars=categorical_vars,
numerical_vars=numerical_vars,
text_vars=text_vars,
response_var='loan_status')
X, y = auto.fit_transform(observations)
# Start model with provided input nub
x = auto.input_nub
# Fill in your own hidden layers
x = Dense(8)(x)
x = Dense(16, activation='relu')(x)
x = Dense(8)(x)
# End model with provided output nub
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='Adam', loss=auto.loss, metrics=['accuracy'])
# Train model
logging.warning(
'Settle in! This training normally takes about 5-20 minutes on CPU')
model.fit(X, y, epochs=1, validation_split=.2)
pass
def main():
# Load data
observations = lib.load_mushroom()
# observations = lib.load_lending_club(test_run=False)
print('Observation columns: {}'.format(list(observations.columns)))
print('Class balance:\n {}'.format(observations['class'].value_counts()))
# List out variable types
numerical_vars = []
categorical_vars = [
'class', 'cap-shape', 'cap-surface', 'cap-color', 'bruises', 'odor',
'gill-attachment', 'gill-spacing', 'gill-size', 'gill-color',
'stalk-shape', 'stalk-root', 'stalk-surface-above-ring',
'stalk-surface-below-ring', 'stalk-color-above-ring',
'stalk-color-below-ring', 'veil-type', 'veil-color', 'ring-number',
'ring-type', 'spore-print-color', 'population', 'habitat'
]
text_vars = []
train_observations, test_observations = train_test_split(observations)
train_observations = train_observations.copy()
test_observations = test_observations.copy()
# Create and fit Automater
auto = Automater(numerical_vars=numerical_vars,
categorical_vars=categorical_vars,
text_vars=text_vars,
response_var='class')
auto.fit(train_observations)
# Create and fit keras (deep learning) model
# The auto.transform, auto.input_nub, auto.input_layers, and auto.loss are provided by keras-pandas, and
# everything else is core Keras
train_X, train_y = auto.transform(train_observations)
test_X, test_y = auto.transform(test_observations)
x = auto.input_nub
x = Dense(32)(x)
x = Dense(32, activation='relu')(x)
x = Dense(32)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='Adam', loss=auto.loss, metrics=['accuracy'])
model.fit(train_X, train_y)
test_y_pred = model.predict(test_X)
# Inverse transform model output, to get usable results and save all results
test_observations[auto.response_var +
'_pred'] = auto.inverse_transform_output(test_y_pred)
print('Predictions: {}'.format(test_observations[auto.response_var +
'_pred']))
pass
def test_inverse_transform_numerical_response(self):
# :oad data
observations = lib.load_lending_club()
# Set to test run
observations = observations.sample(n=100)
# Declare variable types
categorical_vars = ['term', 'grade', 'sub_grade', 'emp_length', 'home_ownership', 'verification_status',
'issue_d',
'pymnt_plan', 'purpose', 'addr_state', 'initial_list_status', 'application_type',
'disbursement_method', 'loan_status']
numerical_vars = ['loan_amnt', 'funded_amnt', 'funded_amnt_inv', 'annual_inc', 'installment', 'dti',
'inq_last_6mths', 'open_acc', 'pub_rec', 'revol_bal', 'total_acc', 'pub_rec_bankruptcies',
'int_rate', 'revol_util']
text_vars = ['desc', 'title']
# Manual null filling
for categorical_var in categorical_vars:
observations[categorical_var] = observations[categorical_var].fillna('None')
observations[categorical_var] = observations[categorical_var].apply(str)
auto = Automater(categorical_vars=categorical_vars, numerical_vars=numerical_vars, text_vars=text_vars,
response_var='funded_amnt')
X, y = auto.fit_transform(observations)
# Start model with provided input nub
x = auto.input_nub
# Fill in your own hidden layers
x = Dense(8)(x)
x = Dense(16, activation='relu')(x)
x = Dense(8)(x)
# End model with provided output nub
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='Adam', loss=auto.loss, metrics=['accuracy'])
# Train model
logging.warning('Settle in! This training normally takes about 5-20 minutes on CPU')
model.fit(X, y, epochs=1, validation_split=.2)
unscaled_preds = model.predict(X)
logging.debug('unscaled_preds: {}'.format(list(unscaled_preds)))
scaled_preds = auto.inverse_transform_output(unscaled_preds)
logging.debug('scaled_preds: {}'.format(list(scaled_preds)))
self.assertNotAlmostEquals(0, numpy.mean(scaled_preds))
self.assertNotAlmostEquals(1, numpy.std(scaled_preds))
def main():
# Load data
observations = lib.load_titanic()
# observations = lib.load_lending_club(test_run=False)
print('Observation columns: {}'.format(list(observations.columns)))
print('Class balance:\n {}'.format(
observations['survived'].value_counts()))
# List out variable types
numerical_vars = [
'age', 'siblings_spouses_aboard', 'parents_children_aboard', 'fare'
]
categorical_vars = ['survived', 'pclass', 'sex']
text_vars = ['name']
for var in categorical_vars:
observations[var] = observations[var].astype(str)
train_observations, test_observations = train_test_split(observations)
train_observations = train_observations.copy()
test_observations = test_observations.copy()
# Create and fit Automater
auto = Automater(numerical_vars=numerical_vars,
categorical_vars=categorical_vars,
text_vars=text_vars,
response_var='survived')
auto.fit(train_observations)
# Create and fit keras (deep learning) model
# The auto.transform, auto.input_nub, auto.input_layers, and auto.loss are provided by keras-pandas, and
# everything else is core Keras
train_X, train_y = auto.transform(train_observations)
test_X, test_y = auto.transform(test_observations)
x = auto.input_nub
x = Dense(32)(x)
x = Dense(32, activation='relu')(x)
x = Dense(32)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='Adam', loss=auto.loss, metrics=['accuracy'])
model.fit(train_X, train_y)
test_y_pred = model.predict(test_X)
# Inverse transform model output, to get usable results and save all results
test_observations[auto.response_var +
'_pred'] = auto.inverse_transform_output(test_y_pred)
print('Predictions: {}'.format(test_observations[auto.response_var +
'_pred']))
pass
def main():
# Load data
observations = lib.load_instanbul_stocks(as_ts=True)
print('Observation columns: {}'.format(list(observations.columns)))
# Heuristic data transformations
# Train /test split
train_observations, test_observations = train_test_split(observations)
train_observations = train_observations.copy()
test_observations = test_observations.copy()
# List out variable types
timeseries_vars = ['ise_lagged', 'ise.1_lagged', 'sp_lagged', 'dax_lagged']
numerical_vars = ['ise']
# Create and fit Automater
auto = Automater(numerical_vars=numerical_vars, timeseries_vars=timeseries_vars,
response_var='ise')
auto.fit(train_observations)
# Create and fit keras (deep learning) model.
# The auto.transform, auto.input_nub, auto.input_layers, auto.output_nub, and auto.loss are provided by
# keras-pandas, and everything else is core Keras
x = auto.input_nub
x = Dense(16)(x)
x = Dense(16, activation='relu')(x)
x = Dense(16)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='adam', loss=auto.loss)
train_X, train_y = auto.transform(train_observations)
model.fit(train_X, train_y)
# Inverse transform model output, to get usable results
test_X, test_y = auto.transform(test_observations)
test_y_pred = model.predict(test_X)
test_observations[auto.response_var + '_pred'] = auto.inverse_transform_output(test_y_pred)
print('Predictions: {}'.format(test_observations[auto.response_var + '_pred']))
# TODO Save all results
pass
def main():
logging.getLogger().setLevel(logging.DEBUG)
observations = load_mushrooms()
# Transform the data set, using keras_pandas
auto = Automater(categorical_vars=observations.columns,
response_var='class')
X, y = auto.fit_transform(observations)
# Create model
x = auto.input_nub
x = Dense(30)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='Adam', loss=auto.loss, metrics=['accuracy'])
# Train model
model.fit(X, y, epochs=10, validation_split=.5)
pass
def test_whole(self):
data = lib.load_titanic()
msk = numpy.random.rand(len(data)) < 0.95
data_train = data[msk]
data_test = data[~msk]
text_vars = ['name']
categorical_vars = ['survived']
# Create auto
auto = Automater(text_vars=text_vars,
categorical_vars=categorical_vars,
response_var='survived')
# Train auto
auto.fit(data_train)
X_train, y_train = auto.transform(data)
# Create model
x = auto.input_nub
x = Dense(30, activation='relu')(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='Adam', loss=auto.loss)
# Train DL model
model.fit(X_train, y_train)
# Transform test set
data_test = data_test.drop('survived', axis=1)
X_test, y_test = auto.transform(data_test)
model.predict(X_test)
pass
def test_timeseries_whole(self):
observations = lib.load_instanbul_stocks(as_ts=True)
# Train test split
train_observations, test_observations = train_test_split(observations)
train_observations = train_observations.copy()
test_observations = test_observations.copy()
# Create data type lists
timeseries_vars = ['ise_lagged', 'sp_lagged']
numerical_vars = ['ise']
# Create automater
auto = Automater(numerical_vars=numerical_vars,
timeseries_vars=timeseries_vars,
response_var='ise')
# Fit automater
auto.fit(train_observations)
# Create model
x = auto.input_nub
x = Dense(32)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='adam', loss=auto.loss)
# Train model
train_X, train_y = auto.transform(train_observations)
print(len(train_X))
print(train_X[0].shape)
model.fit(train_X, train_y)
# TODO Use model to predict
pass
def main():
# Load data
observations = lib.load_lending_club()
print('Observation columns: {}'.format(list(observations.columns)))
print('Class balance:\n {}'.format(
observations['loan_status'].value_counts()))
# Heuristic data transformations
for var in ['int_rate', 'revol_util']:
# Strip out percent signs
observations[var] = observations[var].apply(
lambda x: str(x).replace('%', ''))
observations[var] = pandas.to_numeric(observations[var],
errors='coerce')
for var in ['mths_since_last_delinq', 'annual_inc_joint']:
# Heuristic null filling for some variables
observations[var] = observations[var].fillna(0)
# List out variable types
numerical_vars = [
'loan_amnt', 'annual_inc', 'open_acc', 'dti', 'delinq_2yrs',
'inq_last_6mths', 'mths_since_last_delinq', 'pub_rec', 'revol_bal',
'revol_util', 'total_acc', 'pub_rec_bankruptcies'
]
categorical_vars = [
'term', 'grade', 'emp_length', 'home_ownership', 'addr_state',
'application_type', 'disbursement_method'
]
text_vars = ['desc', 'purpose', 'title']
# Train /test split
train_observations, test_observations = train_test_split(observations)
train_observations = train_observations.copy()
test_observations = test_observations.copy()
# Create and fit Automater
auto = Automater(numerical_vars=numerical_vars,
categorical_vars=categorical_vars,
text_vars=text_vars,
response_var='loan_amnt')
auto.fit(train_observations)
# Create and fit keras (deep learning) model
# The auto.transform, auto.input_nub, auto.input_layers, and auto.loss are provided by keras-pandas, and
# everything else is core Keras
train_X, train_y = auto.transform(train_observations)
test_X, test_y = auto.transform(test_observations)
x = auto.input_nub
x = Dense(32)(x)
x = Dense(32, activation='relu')(x)
x = Dense(32)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='Adam', loss=auto.loss, metrics=['accuracy'])
model.fit(train_X, train_y)
test_y_pred = model.predict(test_X)
# Inverse transform model output, to get usable results and save all results
test_observations[auto.response_var +
'_pred'] = auto.inverse_transform_output(test_y_pred)
print('Predictions: {}'.format(test_observations[auto.response_var +
'_pred']))
pass
def test_supervised(self):
observations = lib.load_lending_club()
# Train /test split
train_observations, test_observations = train_test_split(observations)
train_observations = train_observations.copy()
test_observations = test_observations.copy()
# Supervised
data_type_dict = {
'numerical': [
'loan_amnt', 'annual_inc', 'open_acc', 'dti', 'delinq_2yrs',
'inq_last_6mths', 'mths_since_last_delinq', 'pub_rec',
'revol_bal', 'revol_util', 'total_acc', 'pub_rec_bankruptcies'
],
'categorical': [
'term', 'grade', 'emp_length', 'home_ownership', 'loan_status',
'addr_state', 'application_type'
],
'text': ['desc', 'purpose', 'title']
}
output_var = 'loan_status'
auto = Automater(data_type_dict=data_type_dict, output_var=output_var)
self.assertTrue(auto.supervised)
expected_input_vars = reduce(lambda x, y: x + y,
data_type_dict.values())
expected_input_vars.remove(output_var)
self.assertCountEqual(expected_input_vars, auto.input_vars)
self.assertEqual(output_var, auto.output_var)
self.assertTrue(isinstance(auto.input_mapper, DataFrameMapper))
self.assertTrue(isinstance(auto.output_mapper, DataFrameMapper))
self.assertFalse(auto.fitted)
self.assertRaises(AssertionError, auto._check_fitted)
# Test fit
auto.fit(train_observations)
self.assertTrue(auto.fitted)
self.assertIsNotNone(auto.input_mapper.built_features)
self.assertTrue(isinstance(auto.input_layers, list))
self.assertEqual(len(expected_input_vars), len(auto.input_layers))
self.assertIsNotNone(auto.input_nub)
self.assertIsNotNone(auto.output_nub)
self.assertIsNotNone(auto.output_mapper.built_features)
# Test transform, df_out=False
train_X, train_y = auto.transform(train_observations)
test_X, test_y = auto.transform(test_observations)
self.assertTrue(isinstance(test_X, list))
self.assertTrue(isinstance(test_y, numpy.ndarray))
self.assertEqual(test_observations.shape[0],
test_X[0].shape[0]) # Correct number of rows back
self.assertEqual(test_observations.shape[0],
test_y.shape[0]) # Correct number of rows back
# Test transform, df_out=True
transformed_observations = auto.transform(test_observations,
df_out=True)
self.assertTrue(isinstance(transformed_observations, pandas.DataFrame))
self.assertEqual(
test_observations.shape[0],
transformed_observations.shape[0]) # Correct number of rows back
# Test suggest_loss
suggested_loss = auto.suggest_loss()
self.assertTrue(callable(suggested_loss))
# Test model building
x = auto.input_nub
x = Dense(32)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='Adam', loss=auto.suggest_loss())
model.fit(train_X, train_y)
pred_y = model.predict(test_X)
# Test inverse_transform_output
inv_transformed_pred_y = auto.inverse_transform_output(pred_y)
self.assertEqual(test_observations.shape[0],
inv_transformed_pred_y.shape[0])
def main():
# List out which components are supplied by Automater
# In this example, we're utilizing X and y generated by the Automater, auto.input_nub, auto.input_layers,
# auto.output_nub, and auto.suggest_loss
save_results = True
# Load data
observations = lib.load_instanbul_stocks(as_ts=True)
print('Observation columns: {}'.format(list(observations.columns)))
# Notice that the lagged variables are an array of values
print('One of the lagged variables: \n{}'.format(
observations['ise_lagged']))
# Train /test split
train_observations, test_observations = train_test_split(observations)
train_observations = train_observations.copy()
test_observations = test_observations.copy()
# List out variable types
data_type_dict = {
'numerical':
['ise', 'ise.1', 'sp', 'dax', 'ftse', 'nikkei', 'bovespa', 'eu', 'em'],
'categorical': [],
'text': [],
'timeseries':
['ise_lagged', 'ise.1_lagged', 'sp_lagged', 'dax_lagged']
}
output_var = 'ise'
# Create and fit Automater
auto = Automater(data_type_dict=data_type_dict, output_var=output_var)
auto.fit(train_observations)
# Transform data
train_X, train_y = auto.fit_transform(train_observations)
test_X, test_y = auto.transform(test_observations)
# Create and fit keras (deep learning) model.
x = auto.input_nub
x = Dense(32)(x)
x = Dense(32)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='adam', loss=auto.suggest_loss())
model.fit(train_X, train_y)
# Make model predictions and inverse transform model predictions, to get usable results
pred_test_y = model.predict(test_X)
auto.inverse_transform_output(pred_test_y)
# Save all results
if save_results:
temp_dir = lib.get_temp_dir()
model.save(os.path.join(temp_dir, 'model.h5py'))
pickle.dump(train_X, open(os.path.join(temp_dir, 'train_X.pkl'), 'wb'))
pickle.dump(train_y, open(os.path.join(temp_dir, 'train_y.pkl'), 'wb'))
pickle.dump(test_X, open(os.path.join(temp_dir, 'test_X.pkl'), 'wb'))
pickle.dump(test_y, open(os.path.join(temp_dir, 'test_y.pkl'), 'wb'))
pickle.dump(pred_test_y,
open(os.path.join(temp_dir, 'pred_test_y.pkl'), 'wb'))
def main():
# TODO List out which components are supplied by Automater
# In this example, we're utilizing X and y generated by the Automater, auto.input_nub, auto.input_layers,
# auto.output_nub, and auto.suggest_loss
save_results = False
# TODO Load data
observations = lib.load_titanic()
print('Observation columns: {}'.format(list(observations.columns)))
# TODO Train /test split
train_observations, test_observations = train_test_split(observations)
train_observations = train_observations.copy()
test_observations = test_observations.copy()
# TODO List out variable types
data_type_dict = {'numerical': ['age', 'siblings_spouses_aboard', 'parents_children_aboard', 'fare'],
'categorical': ['survived', 'pclass', 'sex'],
'text': ['name'],
'timeseries': []
}
output_var = 'survived'
# Create and fit Automater
auto = Automater(data_type_dict=data_type_dict, output_var=output_var)
auto.fit(train_observations)
# Transform data
train_X, train_y = auto.fit_transform(train_observations)
test_X, test_y = auto.transform(test_observations)
# TODO Create and fit keras (deep learning) model.
x = auto.input_nub
x = Dense(32)(x)
x = Dense(32)(x)
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
print(f'Suggested loss: {auto.suggest_loss()}\n\n')
model.compile(optimizer='adam', loss=auto.suggest_loss(), metrics=['acc'])
# model.fit(train_X, train_y)
model.summary()
print('\n\n' + '^' * 21)
print(train_X)
print('\n\n' + '^' * 21)
print(train_y)
model.fit(train_X, train_y, batch_size=32, epochs=1, validation_split=0.1)
# Make model predictions and inverse transform model predictions, to get usable results
pred_test_y = model.predict(test_X)
auto.inverse_transform_output(pred_test_y)
# Save all results
if save_results:
temp_dir = lib.get_temp_dir()
model.save(os.path.join(temp_dir, 'model.h5py'))
pickle.dump(train_X, open(os.path.join(temp_dir, 'train_X.pkl'), 'wb'))
pickle.dump(train_y, open(os.path.join(temp_dir, 'train_y.pkl'), 'wb'))
pickle.dump(test_X, open(os.path.join(temp_dir, 'test_X.pkl'), 'wb'))
pickle.dump(test_y, open(os.path.join(temp_dir, 'test_y.pkl'), 'wb'))
pickle.dump(pred_test_y, open(os.path.join(temp_dir, 'pred_test_y.pkl'), 'wb'))
# Transform the data set, using keras_pandas
categorical_vars = ['pclass', 'sex', 'survived']
numerical_vars = [
'age', 'siblings_spouses_aboard', 'parents_children_aboard', 'fare'
]
text_vars = ['name']
auto = Automater(categorical_vars=categorical_vars,
numerical_vars=numerical_vars,
text_vars=text_vars,
response_var='survived')
X, y = auto.fit_transform(observations)
# Start model with provided input nub
x = auto.input_nub
# Fill in your own hidden layers
x = Dense(32)(x)
x = Dense(32, activation='relu')(x)
x = Dense(32)(x)
# End model with provided output nub
x = auto.output_nub(x)
model = Model(inputs=auto.input_layers, outputs=x)
model.compile(optimizer='Adam',
loss='sparse_categorical_crossentropy',
metrics=['accuracy'])
# Train model
model.fit(X, y, epochs=4, validation_split=.2)
