Tensorflow libs: layers, metrics, ops, etc.
Project description
MLable
Tensorflow libs:
Installation
The package is available on pypi:
pip install -U mlable
Layers
Divide
Relative reshaping layers that divides a given axis and multiplies another by the same factor:
import mlable.layers.reshaping
__x = tf.ones(shape=(2, 4, 6, 8))
__l = mlable.layers.reshaping.Divide(
input_axis=2, # relative to the NEW shape / rank
output_axis=-1, # same
factor=3,
insert=False,) # whether to create a new axis
list(__l(__x).shape)
# [2, 4, 2, 24]
Merge
Relative reshaping layers that merges two axes:
import mlable.layers.reshaping
__x = tf.ones(shape=(2, 4, 6, 8))
__l = mlable.layers.reshaping.Merge(
left_axis=1,
right_axis=-1,
left=False,) # whether to merge into the left axis
list(__l(__x).shape)
# [2, 6, 32]
CachedMultiHeadAttention
This layer subclasses the regular MultiHeadAttention and adds a cache.
It has the same parameters:
import mlable.layers.transformer
mlable.layers.transformer.CachedMultiHeadAttention(
num_heads,
key_dim,
value_dim=None,
dropout=0.0,
use_bias=True,
output_shape=None,
attention_axes=None,
kernel_initializer='glorot_uniform',
bias_initializer='zeros',
kernel_regularizer=None,
bias_regularizer=None,
activity_regularizer=None,
kernel_constraint=None,
bias_constraint=None,
**kwargs)
And its call
function has the following arguments:
mlable.layers.transformer.CachedMultiHeadAttention.call(
query,
value,
key=None,
cache=None,
step=None,
training=False,
attention_mask=None,
return_attention_scores=False,
use_causal_mask=True,)
FeedForwardGate
A typical feed-forward layer with GELU activation:
import mlable.layers.transformer
__x = tf.ones(shape=(2, 3, 5), dtype=tf.dtypes.float32)
__l = mlable.layers.transformer.FeedForwardGate(
input_dim=256,
hidden_dim=1024)
__l(__x)
RotaryPositionalEmbedding
Tensorflow implementation of RoPE:
import mlable.layers.embedding
__x = tf.ones(shape=(2, 3, 5))
__l = mlable.layers.embedding.RotaryPositionalEmbedding(
sequence_axis=1, # position along this axis
feature_axis=-1, # output axis
max_wavelength=10_000, # see the paper
scaling_factor=1.) # see the paper
__l(inputs=__x, offset=2) # the offset is typically used to perform iterative decoding during inference
Metrics
CategoricalGroupAccuracy
Hierarchical models should not be scored on individual predictions but on their combination.
For example, tokun is a byte level autoencoder.
It predicts probabilities for each byte of the output, like 0 in the UTF-32-BE encoding of "a" (0, 0, 0, 97)
.
A prediction of (0, 0, 0, 98)
for "a" has 3 correct byte out of 4, but the prediction is actually "b".
In this case the byte accuracy is 75% while the character accuracy is 0%. Having several hierarchies of scoring helps with training and evaluation.
import mlable.metrics
byte_accuracy = mlable.metrics.CategoricalGroupAccuracy(group=1, name='byte_accuracy')
character_accuracy = mlable.metrics.CategoricalGroupAccuracy(group=4, name='character_accuracy')
token_accuracy = mlable.metrics.CategoricalGroupAccuracy(group=64, name='token_accuracy')
Credits
Andrej Karpathy reconnected my ML synapses with micrograd.
License
Licensed under the aGPLv3.
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