Get last output of dynamic_rnn in tensorflow?

Question

I am using dynamic_rnn to process MNIST data:

# LSTM Cell
lstm = rnn_cell.LSTMCell(num_units=200,
                         forget_bias=1.0,
                         initializer=tf.random_normal)

# Initial state
istate = lstm.zero_state(batch_size, "float")

# Get lstm cell output
output, states = rnn.dynamic_rnn(lstm, X, initial_state=istate)

# Output at last time point T
output_at_T = output[:, 27, :]

Full code: http://pastebin.com/bhf9MgMe

The input to the lstm is (batch_size, sequence_length, input_size)

As a result the dimensions of output_at_T is (batch_size, sequence_length, num_units) where num_units=200.

I need to get the last output along the sequence_length dimension. In the code above, this is hardcoded as 27. However, I do not know the sequence_length in advance as it can change from batch to batch in my application.

I tried:

output_at_T = output[:, -1, :]

but it says negative indexing is not implemented yet, and I tried using a placeholder variable as well as a constant (into which I could ideally feed the sequence_length for a particular batch); neither worked.

Any way to implement something like this in tensorflow atm?

Answer 1

Have you noticed that there are two outputs from dynamic_rnn?

1. Output 1, let's call it h, has all outputs at each time steps (i.e. h_1, h_2, etc),
2. Output 2, final_state, has two elements: the cell_state, and the last output for each element of the batch (as long as you input the sequence length to dynamic_rnn).

So from:

h, final_state= tf.dynamic_rnn( ..., sequence_length=[batch_size_vector], ... )

the last state for each element in the batch is:

final_state.h

Note that this includes the case when the length of the sequence is different for each element of the batch, as we are using the sequence_length argument.

Answer 2

This is what gather_nd is for!

def extract_axis_1(data, ind):
    """
    Get specified elements along the first axis of tensor.
    :param data: Tensorflow tensor that will be subsetted.
    :param ind: Indices to take (one for each element along axis 0 of data).
    :return: Subsetted tensor.
    """

    batch_range = tf.range(tf.shape(data)[0])
    indices = tf.stack([batch_range, ind], axis=1)
    res = tf.gather_nd(data, indices)

    return res

In your case (assuming sequence_length is a 1-D tensor with the length of each axis 0 element):

output = extract_axis_1(output, sequence_length - 1)

Now output is a tensor of dimension [batch_size, num_cells].

Answer 3

output[:, -1, :]

works with Tensorflow 1.x now!!

Answer 4

Most answers cover it thoroughly, but this code snip might help understand what's really being returned by the dynamic_rnn layer

=> Tuple of (outputs, final_output_state).

So for an input with max sequence length of T time steps outputs is of the shape [Batch_size, T, num_inputs] (given time_major=False; default value) and it contains the output state at each timestep h1, h2.....hT.

And final_output_state is of the shape [Batch_size,num_inputs] and has the final cell state cT and output state hT of each batch sequence.

But since the dynamic_rnn is being used my guess is your sequence lengths vary for each batch.

    import tensorflow as tf
    import numpy as np
    from tensorflow.contrib import rnn
    tf.reset_default_graph()

    # Create input data
    X = np.random.randn(2, 10, 8)

    # The second example is of length 6 
    X[1,6:] = 0
    X_lengths = [10, 6]

    cell = tf.nn.rnn_cell.LSTMCell(num_units=64, state_is_tuple=True)

    outputs, states  = tf.nn.dynamic_rnn(cell=cell,
                                         dtype=tf.float64,
                                         sequence_length=X_lengths,
                                         inputs=X)

    result = tf.contrib.learn.run_n({"outputs": outputs, "states":states},
                                    n=1,
                                    feed_dict=None)
    assert result[0]["outputs"].shape == (2, 10, 64)
    print result[0]["outputs"].shape
    print result[0]["states"].h.shape
    # the final outputs state and states returned must be equal for each      
    # sequence
    assert(result[0]["outputs"][0][-1]==result[0]["states"].h[0]).all()
    assert(result[0]["outputs"][-1][5]==result[0]["states"].h[-1]).all()
    assert(result[0]["outputs"][-1][-1]==result[0]["states"].h[-1]).all()

The final assertion will fail as the final state for the 2nd sequence is at 6th time step ie. the index 5 and the rest of the outputs from [6:9] are all 0s in the 2nd timestep

Answer 5

I am new to Stackoverflow and cannot comment yet so I am writing this new answer. @VM_AI, the last index is tf.shape(output)[1] - 1. So, reusing your answer:

# Let's first fetch the last index of seq length
# last_index would have a scalar value
last_index = tf.shape(output)[1] - 1
# Then let's reshape the output to [sequence_length,batch_size,num_units]
# for convenience
output_rs = tf.transpose(output,[1,0,2])
# Last state of all batches
last_state = tf.nn.embedding_lookup(output_rs,last_index)

This works for me.

Answer 6

You should be able to access the shape of your output tensor using tf.shape(output). The tf.shape() function will return a 1d tensor containing the sizes of the output tensor. In your example, this would be (batch_size, sequence_length, num_units)

You should then be able to extract the value of output_at_T as output[:, tf.shape(output)[1], :]

Answer 7

There is a function in TensorFlow tf.shape that allows you to get the symbolic interpretation of shape rather than None being returned by output._shape[1]. And after fetching the last index you can lookup by using tf.nn.embedding_lookup, which is recommended especially when the data to be fetched is high as this does parallel lookup 32 by default.

# Let's first fetch the last index of seq length
# last_index would have a scalar value
last_index = tf.shape(output)[1] 
# Then let's reshape the output to [sequence_length,batch_size,num_units]
# for convenience
output_rs = tf.transpose(output,[1,0,2])
# Last state of all batches
last_state = tf.nn.embedding_lookup(output_rs,last_index)

This should work.

Just to clarify what @Benoit Steiner said. His solution would not work as tf.shape would return symbolic interpretation of the shape value, and such cannot be used for slicing tensors i.e., direct indexing