No, but they are (or can be made to be) not so different either.

## TL;DR

`tf.nn.dynamic_rnn`

replaces elements after the sequence end with 0s. This cannot be replicated with `tf.keras.layers.*`

as far as I know, but you can get a similar behaviour with `RNN(Masking(...)`

approach: it simply stops the computation and carries the last outputs and states forward. You will get the same (non-padding) outputs as those obtained from `tf.nn.dynamic_rnn`

.

## Experiment

Here is a minimal working example demonstrating the differences between `tf.nn.dynamic_rnn`

and `tf.keras.layers.GRU`

with and without the use of `tf.keras.layers.Masking`

layer.

```
import numpy as np
import tensorflow as tf
test_input = np.array([
[1, 2, 1, 0, 0],
[0, 1, 2, 1, 0]
], dtype=int)
seq_length = tf.constant(np.array([3, 4], dtype=int))
emb_weights = (np.ones(shape=(3, 2)) * np.transpose([[0.37, 1, 2]])).astype(np.float32)
emb = tf.keras.layers.Embedding(
*emb_weights.shape,
weights=[emb_weights],
trainable=False
)
mask = tf.keras.layers.Masking(mask_value=0.37)
rnn = tf.keras.layers.GRU(
1,
return_sequences=True,
activation=None,
recurrent_activation=None,
kernel_initializer='ones',
recurrent_initializer='zeros',
use_bias=True,
bias_initializer='ones'
)
def old_rnn(inputs):
rnn_outputs, rnn_states = tf.nn.dynamic_rnn(
rnn.cell,
inputs,
dtype=tf.float32,
sequence_length=seq_length
)
return rnn_outputs
x = tf.keras.layers.Input(shape=test_input.shape[1:])
m0 = tf.keras.Model(inputs=x, outputs=emb(x))
m1 = tf.keras.Model(inputs=x, outputs=rnn(emb(x)))
m2 = tf.keras.Model(inputs=x, outputs=rnn(mask(emb(x))))
print(m0.predict(test_input).squeeze())
print(m1.predict(test_input).squeeze())
print(m2.predict(test_input).squeeze())
sess = tf.keras.backend.get_session()
print(sess.run(old_rnn(mask(emb(x))), feed_dict={x: test_input}).squeeze())
```

The outputs from `m0`

are there to show the result of applying the embedding layer.
Note that there are no zero entries at all:

```
[[[1. 1. ] [[0.37 0.37]
[2. 2. ] [1. 1. ]
[1. 1. ] [2. 2. ]
[0.37 0.37] [1. 1. ]
[0.37 0.37]] [0.37 0.37]]]
```

Now here are the actual outputs from the `m1`

, `m2`

and `old_rnn`

architectures:

```
m1: [[ -6. -50. -156. -272.7276 -475.83362]
[ -1.2876 -9.862801 -69.314 -213.94202 -373.54672 ]]
m2: [[ -6. -50. -156. -156. -156.]
[ 0. -6. -50. -156. -156.]]
old [[ -6. -50. -156. 0. 0.]
[ 0. -6. -50. -156. 0.]]
```

## Summary

- The old
`tf.nn.dynamic_rnn`

used to mask padding elements with zeros.
- The new RNN layers
*without masking* run over the padding elements as if they were data.
- The new
`rnn(mask(...))`

approach simply stops the computation and carries the last outputs and states forward. Note that the (non-padding) outputs that I obtained for this approach are exactly the same as those from `tf.nn.dynamic_rnn`

.

Anyway, I cannot cover all possible edge cases, but I hope that you can use this script to figure things out further.

`keras`

or`tf.keras`

?`seq_lengths`

). From the docs...So it's more for performance than correctness.1more comment