Internal change.

PiperOrigin-RevId: 335385162

tensorflow_privacy/privacy/membership_inference_attack/example.py

@@ -20,6 +20,7 @@ This is using a toy model based on classifying four spacial clusters of data.
 import os
 import tempfile
 
+from absl import app
 import matplotlib.pyplot as plt
 import numpy as np
 import pandas as pd
@@ -117,21 +118,22 @@ def crossentropy(true_labels, predictions):
           keras.backend.variable(predictions)))
 
 
-epoch_results = []
+def main(unused_argv):
+  epoch_results = []
 
-num_epochs = 2
+  num_epochs = 2
-models = {
+  models = {
       "two layer model": two_layer_model,
       "three layer model": three_layer_model,
-}
+  }
-for model_name in models:
+  for model_name in models:
     # Incrementally train the model and store privacy metrics every num_epochs.
     for i in range(1, 6):
       models[model_name].fit(
           training_features,
           to_categorical(training_labels, num_clusters),
-        validation_data=(test_features, to_categorical(test_labels,
+          validation_data=(test_features,
-                                                       num_clusters)),
+                           to_categorical(test_labels, num_clusters)),
           batch_size=64,
           epochs=num_epochs,
           shuffle=True)
@@ -141,8 +143,8 @@ for model_name in models:
 
       # Add metadata to generate a privacy report.
       privacy_report_metadata = PrivacyReportMetadata(
-        accuracy_train=metrics.accuracy_score(training_labels,
+          accuracy_train=metrics.accuracy_score(
-                                              np.argmax(training_pred, axis=1)),
+              training_labels, np.argmax(training_pred, axis=1)),
           accuracy_test=metrics.accuracy_score(test_labels,
                                                np.argmax(test_pred, axis=1)),
           epoch_num=num_epochs * i,
@@ -162,22 +164,23 @@ for model_name in models:
           privacy_report_metadata=privacy_report_metadata)
       epoch_results.append(attack_results)
 
-# Generate privacy reports
+  # Generate privacy reports
-epoch_figure = privacy_report.plot_by_epochs(
+  epoch_figure = privacy_report.plot_by_epochs(
       epoch_results, [PrivacyMetric.ATTACKER_ADVANTAGE, PrivacyMetric.AUC])
-epoch_figure.show()
+  epoch_figure.show()
-privacy_utility_figure = privacy_report.plot_privacy_vs_accuracy_single_model(
+  privacy_utility_figure = privacy_report.plot_privacy_vs_accuracy_single_model(
       epoch_results, [PrivacyMetric.ATTACKER_ADVANTAGE, PrivacyMetric.AUC])
-privacy_utility_figure.show()
+  privacy_utility_figure.show()
 
-# Example of saving the results to the file and loading them back.
+  # Example of saving the results to the file and loading them back.
-with tempfile.TemporaryDirectory() as tmpdirname:
+  with tempfile.TemporaryDirectory() as tmpdirname:
     filepath = os.path.join(tmpdirname, "results.pickle")
     attack_results.save(filepath)
     loaded_results = AttackResults.load(filepath)
+    print(loaded_results.summary(by_slices=False))
 
-# Print attack metrics
+  # Print attack metrics
-for attack_result in attack_results.single_attack_results:
+  for attack_result in attack_results.single_attack_results:
     print("Slice: %s" % attack_result.slice_spec)
     print("Attack type: %s" % attack_result.attack_type)
     print("AUC: %.2f" % attack_result.roc_curve.get_auc())
@@ -185,31 +188,36 @@ for attack_result in attack_results.single_attack_results:
     print("Attacker advantage: %.2f\n" %
           attack_result.roc_curve.get_attacker_advantage())
 
-max_auc_attacker = attack_results.get_result_with_max_auc()
+  max_auc_attacker = attack_results.get_result_with_max_auc()
-print("Attack type with max AUC: %s, AUC of %.2f" %
+  print("Attack type with max AUC: %s, AUC of %.2f" %
         (max_auc_attacker.attack_type, max_auc_attacker.roc_curve.get_auc()))
 
-max_advantage_attacker = attack_results.get_result_with_max_attacker_advantage()
+  max_advantage_attacker = attack_results.get_result_with_max_attacker_advantage(
-print("Attack type with max advantage: %s, Attacker advantage of %.2f" %
+  )
+  print("Attack type with max advantage: %s, Attacker advantage of %.2f" %
         (max_advantage_attacker.attack_type,
          max_advantage_attacker.roc_curve.get_attacker_advantage()))
 
-# Print summary
+  # Print summary
-print("Summary without slices: \n")
+  print("Summary without slices: \n")
-print(attack_results.summary(by_slices=False))
+  print(attack_results.summary(by_slices=False))
 
-print("Summary by slices: \n")
+  print("Summary by slices: \n")
-print(attack_results.summary(by_slices=True))
+  print(attack_results.summary(by_slices=True))
 
-# Print pandas data frame
+  # Print pandas data frame
-print("Pandas frame: \n")
+  print("Pandas frame: \n")
-pd.set_option("display.max_rows", None, "display.max_columns", None)
+  pd.set_option("display.max_rows", None, "display.max_columns", None)
-print(attack_results.calculate_pd_dataframe())
+  print(attack_results.calculate_pd_dataframe())
 
-# Example of ROC curve plotting.
+  # Example of ROC curve plotting.
-figure = plotting.plot_roc_curve(
+  figure = plotting.plot_roc_curve(
       attack_results.single_attack_results[0].roc_curve)
-plt.show()
+  figure.show()
+  plt.show()
 
-# For saving a figure into a file:
+  # For saving a figure into a file:
-# plotting.save_plot(figure, <file_path>)
+  # plotting.save_plot(figure, <file_path>)
+
+if __name__ == "__main__":
+  app.run(main)