TensorFlow dynamic RNN not training

Question

Problem statement

---

I am trying to train a dynamic RNN in TensorFlow v1.0.1 on Linux RedHat 7.3 (problem also manifests on Windows 7), and no matter what I try, I get the exact same training and validation error at every epoch, i.e. my weights are not updating.

I appreciate any help you can offer.

Example

---

I tried to reduce this to a minimum example that shows my issue, but the minimum example is still pretty large. I based the network structure largely on this gist.

Network definition

import functools
import numpy as np
import tensorflow as tf

def lazy_property(function):
    attribute = '_' + function.__name__

    @property
    @functools.wraps(function)
    def wrapper(self):
        if not hasattr(self, attribute):
            setattr(self, attribute, function(self))
        return getattr(self, attribute)
    return wrapper

class MyNetwork:
    """
    Class defining an RNN for labeling a time series.
    """

    def __init__(self, data, target, num_hidden=64):
        self.data = data
        self.target = target
        self._num_hidden = num_hidden
        self._num_steps = int(self.target.get_shape()[1])
        self._num_classes = int(self.target.get_shape()[2])
        self._weight_and_bias()  # create weight and bias tensors
        self.prediction
        self.error
        self.optimize

    @lazy_property
    def prediction(self):
        """Defines the recurrent neural network prediction scheme."""

        # Dynamic LSTM.
        network = tf.contrib.rnn.BasicLSTMCell(self._num_hidden)
        output, _ = tf.nn.dynamic_rnn(network, data, dtype=tf.float32)

        # Flatten and apply same weights to all time steps.
        output = tf.reshape(output, [-1, self._num_hidden])
        prediction = tf.nn.softmax(tf.matmul(output, self.weight) + self.bias)
        prediction = tf.reshape(prediction,
                                [-1, self._num_steps, self._num_classes])
        return prediction

    @lazy_property
    def cost(self):
        """Defines the cost function for the network."""

        cross_entropy = -tf.reduce_sum(self.target * tf.log(self.prediction),
                                       axis=[1, 2])
        cross_entropy = tf.reduce_mean(cross_entropy)
        return cross_entropy

    @lazy_property
    def optimize(self):
        """Defines the optimization scheme."""

        learning_rate = 0.003
        optimizer = tf.train.RMSPropOptimizer(learning_rate)
        return optimizer.minimize(self.cost)

    @lazy_property
    def error(self):
        """Defines a measure of prediction error."""

        mistakes = tf.not_equal(tf.argmax(self.target, 2),
                                tf.argmax(self.prediction, 2))
        return tf.reduce_mean(tf.cast(mistakes, tf.float32))

    def _weight_and_bias(self):
        """Returns appropriately sized weight and bias tensors for the output layer."""

        self.weight = tf.Variable(tf.truncated_normal(
                                         [self._num_hidden, self._num_classes],
                                         mean=0.0,
                                         stddev=0.01,
                                         dtype=tf.float32))
        self.bias = tf.Variable(tf.constant(0.1, shape=[self._num_classes]))

Training

Here is my training process. The all_data class just holds my data and labels, and uses a batch generator class to spit out batches for training when I call all_data.train.next() and all_data.train_labels.next(). You can reproduce with any batch generation scheme you like, and I can add the code if you think it is relevant; I felt like this was getting too long as it is.

tf.reset_default_graph()
data = tf.placeholder(tf.float32,
                      [None, all_data.num_steps, all_data.num_features])
target = tf.placeholder(tf.float32,
                        [None, all_data.num_steps, all_data.num_outputs])
model = MyNetwork(data, target, NUM_HIDDEN)
print('Training the model...')
with tf.Session() as sess:
    sess.run(tf.global_variables_initializer())
    print('Initialized.')
    for epoch in range(3):
        print('Epoch {} |'.format(epoch), end='', flush=True)
        for step in range(all_data.train_size // BATCH_SIZE):

            # Generate the next training batch and train.
            d = all_data.train.next()
            t = all_data.train_labels.next()
            sess.run(model.optimize,
                     feed_dict={data: d, target: t})

            # Update the user periodically.
            if step % summary_frequency == 0:
                print('.', end='', flush=True)

        # Show training and validation error at the end of each epoch.
        print('|', flush=True)
        train_error = sess.run(model.error,
                               feed_dict={data: d, target: t})
        valid_error = sess.run(model.error,
                               feed_dict={
                                   data: all_data.valid,
                                   target: all_data.valid_labels
                                   })
        print('Training error: {}%'.format(100 * train_error))
        print('Validation error: {}%'.format(100 * valid_error))

    # Check testing error after everything.
    test_error = sess.run(model.error,
                          feed_dict={
                              data: all_data.test,
                              target: all_data.test_labels
                              })
    print('Testing error after {} epochs: {}%'.format(epoch + 1, 100 * test_error))

For a simple example, I generated random data and labels, where data has shape [num_samples, num_steps, num_features], and each sample has a single label associated with the whole thing:

data = np.random.rand(5000, 1000, 2)
labels = np.random.randint(low=0, high=2, size=[5000])

I then converted my labels to one-hot vectors and tiled them so that the resulting labels tensor was the same size as the data tensor.

Results

No matter what I do, I get results like this:

Training the model...
Initialized.
Epoch  0 |.......................................................|
Training error: 56.25%
Validation error: 53.39999794960022%
Epoch  1 |.......................................................|
Training error: 56.25%
Validation error: 53.39999794960022%
Epoch  2 |.......................................................|
Training error: 56.25%
Validation error: 53.39999794960022%
Testing error after 3 epochs: 49.000000953674316%

Where I have exactly the same error at every epoch. Even if my weights were randomly walking around this should change. For the example shown here, I used random data with random labels, so I do not expect much improvement, but I do expect some change, and I am getting the exact same results every epoch. When I do this with my actual data set, I get the same behavior.

Insight

---

I hesitate to include this in case it proves to be a red herring, but I believe that my optimizer is calculating cost function gradients of None. When I tried a different optimizer and attempted to clip the gradients, I went ahead and used tf.Print to output the gradients as well. The network crashed with an error that tf.Print could not handle None-type values.

Attempted fixes

---

I have tried the following things, and the problem persists in all cases:

• Using different optimizers, e.g. AdamOptimizer with and without modifications to the gradients (clipping).
• Adjusting batch sizes.
• Using many more and many fewer hidden nodes.
• Running for more epochs.
• Initializing my weights with different values assigned to stddev.
• Initializing my biases to zeros (using tf.zeros) and to different constants.
• Using weights and biases that are defined within the prediction method and are not member variables of the class, and a _weight_and_bias method that is defined as a @staticmethod like in this gist.
• Determining logits in the prediction function instead of softmax predictions, i.e. predictions = tf.matmul(output, self.weights) + self.bias, and then using tf.nn.softmax_cross_entropy_with_logits. This requires some reshaping because the method wants its labels and targets given with shape [batch_size, num_classes], so the cost method becomes:

(line added to get code to format...)

@lazy_property
def cost(self):
"""Defines the cost function for the network."""
    targs = tf.reshape(self.target, [-1, self._num_classes])
    logits = tf.reshape(self.predictions, [-1, self._num_classes])
    cross_entropy = tf.nn.softmax_cross_entropy_with_logits(labels=targs, logits=logits)
    cross_entropy = tf.reduce_mean(cross_entropy)
    return cross_entropy

• Changing which size dimension I leave as None when I create my placeholders as suggested in this answer, which requires a bit of rewriting in the network definition. Basically setting size = [all_data.batch_size, -1, all_data.num_features] and size = [all_data.batch_size, -1, all_data.num_classes].
• Using tf.contrib.rnn.DropoutWrapper in my network definition and passing a dropout value set to 0.5 in training and 1.0 in validation and testing.

Answer 1

The problem went away when I used

output = tf.contrib.layers.flatten(output)
logits = tf.contrib.layers.fully_connected(output, some_size, activation_fn=None)

instead of flattening my network output, defining weights, and performing the tf.matmul(output, weight) + bias manually. I then used logits (instead of predictions in the question) in my cost function with

cross_entropy = tf.nn.softmax_cross_entropy_with_logits(labels=target,
                                                        logits=logits)

If you want to get the network prediction, you will still need to do prediction = tf.nn.softmax(logits).

I have no idea why this helped, but the network would not train even on random made-up data until I made these changes.