def test_with_defences(self):
        # Get MNIST
        (x_train, y_train), (x_test, y_test) = self.mnist
        x_train, y_train = x_train[:NB_TRAIN], y_train[:NB_TRAIN]
        x_test, y_test = x_test[:NB_TEST], y_test[:NB_TEST]

        # Get the ready-trained Keras model
        model = self.classifier_k._model
        classifier = KerasClassifier((0, 1), model, defences='featsqueeze1')

        attack = FastGradientMethod(classifier, eps=1)
        x_train_adv = attack.generate(x_train)
        x_test_adv = attack.generate(x_test)

        self.assertFalse((x_train == x_train_adv).all())
        self.assertFalse((x_test == x_test_adv).all())

        train_y_pred = get_labels_np_array(classifier.predict(x_train_adv))
        test_y_pred = get_labels_np_array(classifier.predict(x_test_adv))

        self.assertFalse((y_train == train_y_pred).all())
        self.assertFalse((y_test == test_y_pred).all())

        preds = classifier.predict(x_train_adv)
        acc = np.sum(np.argmax(preds, axis=1) == np.argmax(
            y_train, axis=1)) / y_train.shape[0]
        print(
            '\nAccuracy on adversarial train examples with feature squeezing: %.2f%%'
            % (acc * 100))

        preds = classifier.predict(x_test_adv)
        acc = np.sum(np.argmax(preds, axis=1) == np.argmax(
            y_test, axis=1)) / y_test.shape[0]
        print('\naccuracy on adversarial test examples: %.2f%%' % (acc * 100))
    def test_krclassifier(self):
        """
        Second test with the KerasClassifier.
        :return:
        """
        # Initialize a tf session
        session = tf.Session()
        k.set_session(session)

        # Get MNIST
        batch_size, nb_train, nb_test = 100, 1000, 10
        (x_train, y_train), (x_test, y_test), _, _ = load_mnist()
        x_train, y_train = x_train[:nb_train], y_train[:nb_train]
        x_test, y_test = x_test[:nb_test], y_test[:nb_test]

        # Create simple CNN
        model = Sequential()
        model.add(Conv2D(4, kernel_size=(5, 5), activation='relu', input_shape=(28, 28, 1)))
        model.add(MaxPooling2D(pool_size=(2, 2)))
        model.add(Flatten())
        model.add(Dense(10, activation='softmax'))

        model.compile(loss=keras.losses.categorical_crossentropy, optimizer=keras.optimizers.Adam(lr=0.01),
                      metrics=['accuracy'])

        # Get classifier
        krc = KerasClassifier((0, 1), model, use_logits=False)
        krc.fit(x_train, y_train, batch_size=batch_size, nb_epochs=2)

        # First attack
        cl2m = CarliniL2Method(classifier=krc, targeted=True, max_iter=100, binary_search_steps=10,
                               learning_rate=2e-2, initial_const=3, decay=1e-2)
        params = {'y': random_targets(y_test, krc.nb_classes)}
        x_test_adv = cl2m.generate(x_test, **params)
        self.assertFalse((x_test == x_test_adv).all())
        target = np.argmax(params['y'], axis=1)
        y_pred_adv = np.argmax(krc.predict(x_test_adv), axis=1)
        self.assertTrue((target == y_pred_adv).any())

        # Second attack
        cl2m = CarliniL2Method(classifier=krc, targeted=False, max_iter=100, binary_search_steps=10,
                               learning_rate=2e-2, initial_const=3, decay=1e-2)
        params = {'y': random_targets(y_test, krc.nb_classes)}
        x_test_adv = cl2m.generate(x_test, **params)
        self.assertFalse((x_test == x_test_adv).all())
        target = np.argmax(params['y'], axis=1)
        y_pred_adv = np.argmax(krc.predict(x_test_adv), axis=1)
        self.assertTrue((target != y_pred_adv).all())

        # Third attack
        cl2m = CarliniL2Method(classifier=krc, targeted=False, max_iter=100, binary_search_steps=10,
                               learning_rate=2e-2, initial_const=3, decay=1e-2)
        params = {}
        x_test_adv = cl2m.generate(x_test, **params)
        self.assertFalse((x_test == x_test_adv).all())
        y_pred = np.argmax(krc.predict(x_test), axis=1)
        y_pred_adv = np.argmax(krc.predict(x_test_adv), axis=1)
        self.assertTrue((y_pred != y_pred_adv).any())
Exemplo n.º 3
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    def test_krclassifier(self):
        """
        Second test with the KerasClassifier.
        :return:
        """
        # Initialize a tf session
        session = tf.Session()
        k.set_session(session)

        # Get MNIST
        batch_size, nb_train, nb_test = 10, 10, 10
        (x_train, y_train), (x_test, y_test), _, _ = load_mnist()
        x_train, y_train = x_train[:nb_train], y_train[:nb_train]
        x_test, y_test = x_test[:nb_test], y_test[:nb_test]

        # Create simple CNN
        model = Sequential()
        model.add(
            Conv2D(4,
                   kernel_size=(5, 5),
                   activation='relu',
                   input_shape=(28, 28, 1)))
        model.add(MaxPooling2D(pool_size=(2, 2)))
        model.add(Flatten())
        model.add(Dense(10, activation='softmax'))

        model.compile(loss=keras.losses.categorical_crossentropy,
                      optimizer=keras.optimizers.Adam(lr=0.01),
                      metrics=['accuracy'])

        # Get classifier
        krc = KerasClassifier((0, 1), model, use_logits=False)
        krc.fit(x_train, y_train, batch_size=batch_size, nb_epochs=2)

        # Attack
        # TODO Launch with all possible attacks
        attack_params = {
            "attacker": "newtonfool",
            "attacker_params": {
                "max_iter": 20
            }
        }
        up = UniversalPerturbation(krc)
        x_train_adv = up.generate(x_train, **attack_params)
        self.assertTrue((up.fooling_rate >= 0.2) or not up.converged)

        x_test_adv = x_test + up.v
        self.assertFalse((x_test == x_test_adv).all())

        train_y_pred = np.argmax(krc.predict(x_train_adv), axis=1)
        test_y_pred = np.argmax(krc.predict(x_test_adv), axis=1)
        self.assertFalse((np.argmax(y_test, axis=1) == test_y_pred).all())
        self.assertFalse((np.argmax(y_train, axis=1) == train_y_pred).all())
    def test_krclassifier(self):
        """
        Second test with the KerasClassifier.
        :return:
        """
        # Get MNIST
        batch_size, nb_train, nb_test = 100, 1000, 10
        (x_train, y_train), (x_test, y_test), _, _ = load_mnist()
        x_train, y_train = x_train[:nb_train], y_train[:nb_train]
        x_test, y_test = x_test[:nb_test], y_test[:nb_test]

        # Create simple CNN
        model = Sequential()
        model.add(
            Conv2D(4,
                   kernel_size=(5, 5),
                   activation='relu',
                   input_shape=(28, 28, 1)))
        model.add(MaxPooling2D(pool_size=(2, 2)))
        model.add(Flatten())
        model.add(Dense(10, activation='softmax'))

        model.compile(loss=keras.losses.categorical_crossentropy,
                      optimizer=keras.optimizers.Adam(lr=0.01),
                      metrics=['accuracy'])

        # Get classifier
        krc = KerasClassifier((0, 1), model, use_logits=False)
        krc.fit(x_train, y_train, batch_size=batch_size, nb_epochs=2)

        # Attack
        nf = NewtonFool(krc)
        nf.set_params(max_iter=5)
        x_test_adv = nf.generate(x_test)
        self.assertFalse((x_test == x_test_adv).all())

        y_pred = krc.predict(x_test)
        y_pred_adv = krc.predict(x_test_adv)
        y_pred_bool = y_pred.max(axis=1, keepdims=1) == y_pred
        y_pred_max = y_pred.max(axis=1)
        y_pred_adv_max = y_pred_adv[y_pred_bool]
        self.assertTrue((y_pred_max >= y_pred_adv_max).all())
    def test_krclassifier(self):
        """
        Second test with the KerasClassifier.
        :return:
        """
        # Initialize a tf session
        session = tf.Session()
        k.set_session(session)

        # Get MNIST
        (x_train, y_train), (x_test, y_test) = self.mnist

        # Create simple CNN
        model = Sequential()
        model.add(
            Conv2D(4,
                   kernel_size=(5, 5),
                   activation='relu',
                   input_shape=(28, 28, 1)))
        model.add(MaxPooling2D(pool_size=(2, 2)))
        model.add(Flatten())
        model.add(Dense(10, activation='softmax'))

        model.compile(loss=keras.losses.categorical_crossentropy,
                      optimizer=keras.optimizers.Adam(lr=0.01),
                      metrics=['accuracy'])

        # Get classifier
        krc = KerasClassifier((0, 1), model, use_logits=False)
        krc.fit(x_train, y_train, batch_size=BATCH_SIZE, nb_epochs=10)

        # First attack
        cl2m = CarliniL2Method(classifier=krc,
                               targeted=True,
                               max_iter=100,
                               binary_search_steps=1,
                               learning_rate=1,
                               initial_const=10,
                               decay=0)
        params = {'y': random_targets(y_test, krc.nb_classes)}
        x_test_adv = cl2m.generate(x_test, **params)
        self.assertFalse((x_test == x_test_adv).all())
        self.assertTrue((x_test_adv <= 1.0001).all())
        self.assertTrue((x_test_adv >= -0.0001).all())
        target = np.argmax(params['y'], axis=1)
        y_pred_adv = np.argmax(krc.predict(x_test_adv), axis=1)
        print("CW2 Target: %s" % target)
        print("CW2 Actual: %s" % y_pred_adv)
        print("CW2 Success Rate: %f" %
              (sum(target == y_pred_adv) / float(len(target))))
        self.assertTrue((target == y_pred_adv).any())

        # Second attack
        cl2m = CarliniL2Method(classifier=krc,
                               targeted=False,
                               max_iter=100,
                               binary_search_steps=1,
                               learning_rate=1,
                               initial_const=10,
                               decay=0)
        params = {'y': random_targets(y_test, krc.nb_classes)}
        x_test_adv = cl2m.generate(x_test, **params)
        self.assertFalse((x_test == x_test_adv).all())
        self.assertTrue((x_test_adv <= 1.0001).all())
        self.assertTrue((x_test_adv >= -0.0001).all())
        target = np.argmax(params['y'], axis=1)
        y_pred_adv = np.argmax(krc.predict(x_test_adv), axis=1)
        print("CW2 Target: %s" % target)
        print("CW2 Actual: %s" % y_pred_adv)
        print("CW2 Success Rate: %f" %
              (sum(target != y_pred_adv) / float(len(target))))
        self.assertTrue((target != y_pred_adv).any())

        # Third attack
        cl2m = CarliniL2Method(classifier=krc,
                               targeted=False,
                               max_iter=100,
                               binary_search_steps=1,
                               learning_rate=1,
                               initial_const=10,
                               decay=0)
        params = {}
        x_test_adv = cl2m.generate(x_test, **params)
        self.assertFalse((x_test == x_test_adv).all())
        self.assertTrue((x_test_adv <= 1.0001).all())
        self.assertTrue((x_test_adv >= -0.0001).all())
        y_pred = np.argmax(krc.predict(x_test), axis=1)
        y_pred_adv = np.argmax(krc.predict(x_test_adv), axis=1)
        print("CW2 Target: %s" % y_pred)
        print("CW2 Actual: %s" % y_pred_adv)
        print("CW2 Success Rate: %f" %
              (sum(y_pred != y_pred_adv) / float(len(y_pred))))
        self.assertTrue((y_pred != y_pred_adv).any())