EinsumDense layer
- Original Link : https://keras.io/api/layers/core_layers/einsum_dense/
- Last Checked at : 2024-11-24
EinsumDense class
keras.layers.EinsumDense(
equation,
output_shape,
activation=None,
bias_axes=None,
kernel_initializer="glorot_uniform",
bias_initializer="zeros",
kernel_regularizer=None,
bias_regularizer=None,
kernel_constraint=None,
bias_constraint=None,
lora_rank=None,
**kwargs
)A layer that uses einsum as the backing computation.
This layer can perform einsum calculations of arbitrary dimensionality.
Arguments
- equation: An equation describing the einsum to perform. This equation must be a valid einsum string of the form
ab,bc->ac,...ab,bc->...ac, orab...,bc->ac...where ‘ab’, ‘bc’, and ‘ac’ can be any valid einsum axis expression sequence. - output_shape: The expected shape of the output tensor (excluding the batch dimension and any dimensions represented by ellipses). You can specify
Nonefor any dimension that is unknown or can be inferred from the input shape. - activation: Activation function to use. If you don’t specify anything, no activation is applied (that is, a “linear” activation:
a(x) = x). - bias_axes: A string containing the output dimension(s) to apply a bias to. Each character in the
bias_axesstring should correspond to a character in the output portion of theequationstring. - kernel_initializer: Initializer for the
kernelweights matrix. - bias_initializer: Initializer for the bias vector.
- kernel_regularizer: Regularizer function applied to the
kernelweights matrix. - bias_regularizer: Regularizer function applied to the bias vector.
- kernel_constraint: Constraint function applied to the
kernelweights matrix. - bias_constraint: Constraint function applied to the bias vector.
- lora_rank: Optional integer. If set, the layer’s forward pass will implement LoRA (Low-Rank Adaptation) with the provided rank. LoRA sets the layer’s kernel to non-trainable and replaces it with a delta over the original kernel, obtained via multiplying two lower-rank trainable matrices (the factorization happens on the last dimension). This can be useful to reduce the computation cost of fine-tuning large dense layers. You can also enable LoRA on an existing
EinsumDenselayer by callinglayer.enable_lora(rank). - **kwargs: Base layer keyword arguments, such as
nameanddtype.
Examples
Biased dense layer with einsums
This example shows how to instantiate a standard Keras dense layer using einsum operations. This example is equivalent to keras.layers.Dense(64, use_bias=True).
>>> layer = keras.layers.EinsumDense("ab,bc->ac",
... output_shape=64,
... bias_axes="c")
>>> input_tensor = keras.Input(shape=[32])
>>> output_tensor = layer(input_tensor)
>>> output_tensor.shape
(None, 64)
Applying a dense layer to a sequence
This example shows how to instantiate a layer that applies the same dense operation to every element in a sequence. Here, the output_shape has two values (since there are two non-batch dimensions in the output); the first dimension in the output_shape is None, because the sequence dimension b has an unknown shape.
>>> layer = keras.layers.EinsumDense("abc,cd->abd",
... output_shape=(None, 64),
... bias_axes="d")
>>> input_tensor = keras.Input(shape=[32, 128])
>>> output_tensor = layer(input_tensor)
>>> output_tensor.shape
(None, 32, 64)
Applying a dense layer to a sequence using ellipses
This example shows how to instantiate a layer that applies the same dense operation to every element in a sequence, but uses the ellipsis notation instead of specifying the batch and sequence dimensions.
Because we are using ellipsis notation and have specified only one axis, the output_shape arg is a single value. When instantiated in this way, the layer can handle any number of sequence dimensions - including the case where no sequence dimension exists.
>>> layer = keras.layers.EinsumDense("...x,xy->...y",
... output_shape=64,
... bias_axes="y")
>>> input_tensor = keras.Input(shape=[32, 128])
>>> output_tensor = layer(input_tensor)
>>> output_tensor.shape
(None, 32, 64)