I am trying to make a simple GANs to generate digits from the MNIST dataset. However when I get to training(which is custom) I get this annoying warning that I suspect is the cause of not training like I'm used to.

Keep in mind this is all in tensorflow 2.0 using it's default eager execution.

GET THE DATA(not that important)

(train_images,train_labels),(test_images,test_labels) = tf.keras.datasets.mnist.load_data()

train_images = train_images.reshape(train_images.shape[0], 28, 28, 1).astype('float32')
train_images = (train_images - 127.5) / 127.5 # Normalize the images to [-1, 1]


train_dataset = tf.data.Dataset.from_tensor_slices((train_images,train_labels)).shuffle(BUFFER_SIZE).batch(BATCH_SIZE)

GENERATOR MODEL(This is where the Batch Normalization is at)

def make_generator_model():
    model = tf.keras.Sequential()
    model.add(tf.keras.layers.Dense(7*7*256, use_bias=False, input_shape=(100,)))

    model.add(tf.keras.layers.Reshape((7, 7, 256)))
    assert model.output_shape == (None, 7, 7, 256) # Note: None is the batch size

    model.add(tf.keras.layers.Conv2DTranspose(128, (5, 5), strides=(1, 1), padding='same', use_bias=False))
    assert model.output_shape == (None, 7, 7, 128)  

    model.add(tf.keras.layers.Conv2DTranspose(64, (5, 5), strides=(2, 2), padding='same', use_bias=False))
    assert model.output_shape == (None, 14, 14, 64)    

    model.add(tf.keras.layers.Conv2DTranspose(1, (5, 5), strides=(2, 2), padding='same', use_bias=False, activation='tanh'))
    assert model.output_shape == (None, 28, 28, 1)

    return model

DISCRIMINATOR MODEL (likely not that important)

def make_discriminator_model():
    model = tf.keras.Sequential()
    model.add(tf.keras.layers.Conv2D(64, (5, 5), strides=(2, 2),    padding='same'))

    model.add(tf.keras.layers.Conv2D(128, (5, 5), strides=(2, 2), padding='same'))


    return model

INSTANTIATE THE MODELS(likely not that important)

generator = make_generator_model()
discriminator = make_discriminator_model()

DEFINE THE LOSSES(maybe the generator loss is important since that is where the gradient comes from)

def generator_loss(generated_output):
    return tf.nn.sigmoid_cross_entropy_with_logits(labels = tf.ones_like(generated_output), logits = generated_output)

def discriminator_loss(real_output, generated_output):
    # [1,1,...,1] with real output since it is true and we want our generated examples to look like it
    real_loss = tf.nn.sigmoid_cross_entropy_with_logits(labels=tf.ones_like(real_output), logits=real_output)

    # [0,0,...,0] with generated images since they are fake
    generated_loss = tf.nn.sigmoid_cross_entropy_with_logits(labels=tf.zeros_like(generated_output), logits=generated_output)

    total_loss = real_loss + generated_loss

    return total_loss

MAKE THE OPTIMIZERS(likely not important)

generator_optimizer = tf.optimizers.Adam(1e-4)
discriminator_optimizer = tf.optimizers.Adam(1e-4)

RANDOM NOISE FOR THE GENERATOR(likely not important)

noise_dim = 100
num_examples_to_generate = 16

# We'll re-use this random vector used to seed the generator so
# it will be easier to see the improvement over time.
random_vector_for_generation = tf.random.normal([num_examples_to_generate,

A SINGLE TRAIN STEP(This is where I get the error

def train_step(images):
   # generating noise from a normal distribution
    noise = tf.random.normal([BATCH_SIZE, noise_dim])

    with tf.GradientTape() as gen_tape, tf.GradientTape() as disc_tape:
        generated_images = generator(noise, training=True)
        real_output = discriminator(images[0], training=True)
        generated_output = discriminator(generated_images, training=True)

        gen_loss = generator_loss(generated_output)
        disc_loss = discriminator_loss(real_output, generated_output)

This line >>>>>

    gradients_of_generator = gen_tape.gradient(gen_loss, generator.variables)

<<<<< This line 

    gradients_of_discriminator = disc_tape.gradient(disc_loss, discriminator.variables)

    generator_optimizer.apply_gradients(zip(gradients_of_generator, generator.variables))
    discriminator_optimizer.apply_gradients(zip(gradients_of_discriminator, discriminator.variables))

THE FULL TRAIN(not important except that it calls train_step)

def train(dataset, epochs):  
    for epoch in range(epochs):
        start = time.time()

        for images in dataset:

                                   epoch + 1,

        # saving (checkpoint) the model every 15 epochs
        if (epoch + 1) % 15 == 0:
            checkpoint.save(file_prefix = checkpoint_prefix)

        print ('Time taken for epoch {} is {} sec'.format(epoch + 1,
    # generating after the final epoch


train(train_dataset, EPOCHS)

The error I get is as follows,

W0330 19:42:57.366302 4738405824 optimizer_v2.py:928] Gradients does 
not exist for variables ['batch_normalization_v2_54/moving_mean:0', 
'batch_normalization_v2_56/moving_variance:0'] when minimizing the

And I get an image from the generator which looks like this: enter image description here

which is kinda what I would expect without the normalization. Everything would clump to one corner because there are extreme values.


The problem is here:

gradients_of_generator = gen_tape.gradient(gen_loss, generator.variables)

You should only be getting gradients for the trainable variables. So you should change it to

gradients_of_generator = gen_tape.gradient(gen_loss, generator.trainable_variables)

The same goes for the three lines following. The variables field includes stuff like the running averages batch norm uses during inference. Because they are not used during training, there are no sensible gradients defined and trying to compute them will lead to a crash.

  • BN's parameters should be trainable during training unless they are frozen. or the custom dataset thats being used for finetuning intentionally intend on not updating them (they are good enough). am I missing something here?
    – Rika
    Nov 11 '20 at 7:36
  • 1
    "Trainable" means "to be updated via gradient descent". There is a difference between the parameters (beta/gamma which are applied after normalizing to mean 0/stddev 1), which are indeed trainable (and usually trained) in this sense, and the population statistics (used instead of minibatch statistics during inference), which are of course not updated via gradient descent, but rather via an exponentially decaying average, and this is handled separately (via the training=True argument).
    – xdurch0
    Nov 11 '20 at 8:25

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