`LSTM`

class```
tf_keras.layers.LSTM(
units,
activation="tanh",
recurrent_activation="sigmoid",
use_bias=True,
kernel_initializer="glorot_uniform",
recurrent_initializer="orthogonal",
bias_initializer="zeros",
unit_forget_bias=True,
kernel_regularizer=None,
recurrent_regularizer=None,
bias_regularizer=None,
activity_regularizer=None,
kernel_constraint=None,
recurrent_constraint=None,
bias_constraint=None,
dropout=0.0,
recurrent_dropout=0.0,
return_sequences=False,
return_state=False,
go_backwards=False,
stateful=False,
time_major=False,
unroll=False,
**kwargs
)
```

Long Short-Term Memory layer - Hochreiter 1997.

See the TF-Keras RNN API guide for details about the usage of RNN API.

Based on available runtime hardware and constraints, this layer will choose different implementations (cuDNN-based or pure-TensorFlow) to maximize the performance. If a GPU is available and all the arguments to the layer meet the requirement of the cuDNN kernel (see below for details), the layer will use a fast cuDNN implementation.

The requirements to use the cuDNN implementation are:

`activation`

==`tanh`

`recurrent_activation`

==`sigmoid`

`recurrent_dropout`

== 0`unroll`

is`False`

`use_bias`

is`True`

- Inputs, if use masking, are strictly right-padded.
- Eager execution is enabled in the outermost context.

For example:

```
>>> inputs = tf.random.normal([32, 10, 8])
>>> lstm = tf.keras.layers.LSTM(4)
>>> output = lstm(inputs)
>>> print(output.shape)
(32, 4)
>>> lstm = tf.keras.layers.LSTM(4, return_sequences=True, return_state=True)
>>> whole_seq_output, final_memory_state, final_carry_state = lstm(inputs)
>>> print(whole_seq_output.shape)
(32, 10, 4)
>>> print(final_memory_state.shape)
(32, 4)
>>> print(final_carry_state.shape)
(32, 4)
```

**Arguments**

**units**: Positive integer, dimensionality of the output space.**activation**: Activation function to use. Default: hyperbolic tangent (`tanh`

). If you pass`None`

, no activation is applied (ie. "linear" activation:`a(x) = x`

).**recurrent_activation**: Activation function to use for the recurrent step. Default: sigmoid (`sigmoid`

). If you pass`None`

, no activation is applied (ie. "linear" activation:`a(x) = x`

).**use_bias**: Boolean (default`True`

), whether the layer uses a bias vector.**kernel_initializer**: Initializer for the`kernel`

weights matrix, used for the linear transformation of the inputs. Default:`glorot_uniform`

.**recurrent_initializer**: Initializer for the`recurrent_kernel`

weights matrix, used for the linear transformation of the recurrent state. Default:`orthogonal`

.**bias_initializer**: Initializer for the bias vector. Default:`zeros`

.**unit_forget_bias**: Boolean (default`True`

). If True, add 1 to the bias of the forget gate at initialization. Setting it to true will also force`bias_initializer="zeros"`

. This is recommended in Jozefowicz et al..**kernel_regularizer**: Regularizer function applied to the`kernel`

weights matrix. Default:`None`

.**recurrent_regularizer**: Regularizer function applied to the`recurrent_kernel`

weights matrix. Default:`None`

.**bias_regularizer**: Regularizer function applied to the bias vector. Default:`None`

.**activity_regularizer**: Regularizer function applied to the output of the layer (its "activation"). Default:`None`

.**kernel_constraint**: Constraint function applied to the`kernel`

weights matrix. Default:`None`

.**recurrent_constraint**: Constraint function applied to the`recurrent_kernel`

weights matrix. Default:`None`

.**bias_constraint**: Constraint function applied to the bias vector. Default:`None`

.**dropout**: Float between 0 and 1. Fraction of the units to drop for the linear transformation of the inputs. Default: 0.**recurrent_dropout**: Float between 0 and 1. Fraction of the units to drop for the linear transformation of the recurrent state. Default: 0.**return_sequences**: Boolean. Whether to return the last output in the output sequence, or the full sequence. Default:`False`

.**return_state**: Boolean. Whether to return the last state in addition to the output. Default:`False`

.**go_backwards**: Boolean (default`False`

). If True, process the input sequence backwards and return the reversed sequence.**stateful**: Boolean (default`False`

). If True, the last state for each sample at index i in a batch will be used as initial state for the sample of index i in the following batch.**time_major**: The shape format of the`inputs`

and`outputs`

tensors. If True, the inputs and outputs will be in shape`[timesteps, batch, feature]`

, whereas in the False case, it will be`[batch, timesteps, feature]`

. Using`time_major = True`

is a bit more efficient because it avoids transposes at the beginning and end of the RNN calculation. However, most TensorFlow data is batch-major, so by default this function accepts input and emits output in batch-major form.**unroll**: Boolean (default`False`

). If True, the network will be unrolled, else a symbolic loop will be used. Unrolling can speed-up a RNN, although it tends to be more memory-intensive. Unrolling is only suitable for short sequences.

**Call arguments**

**inputs**: A 3D tensor with shape`[batch, timesteps, feature]`

.**mask**: Binary tensor of shape`[batch, timesteps]`

indicating whether a given timestep should be masked (optional). An individual`True`

entry indicates that the corresponding timestep should be utilized, while a`False`

entry indicates that the corresponding timestep should be ignored. Defaults to`None`

.**training**: Python boolean indicating whether the layer should behave in training mode or in inference mode. This argument is passed to the cell when calling it. This is only relevant if`dropout`

or`recurrent_dropout`

is used (optional). Defaults to`None`

.**initial_state**: List of initial state tensors to be passed to the first call of the cell (optional,`None`

causes creation of zero-filled initial state tensors). Defaults to`None`

.