Overview | Quick install | What does Flax look like? | Documentation
See our full documentation to learn everything you need to know about Flax.
Flax is developed by a group within the Brain Team in Google AI, in close collaboration with the JAX team. Flax is being used by a growing community of hundreds of folks in various Alphabet research departments for their daily work, as well as a growing community of open source projects.
The Flax team's mission is to serve the growing JAX neural network research ecosystem -- both within Alphabet and with the broader , and to explore the use-cases where JAX shines. We use GitHub for almost all of our coordination and planning, as well as where we discuss upcoming design changes. We welcome feedback on any of our discussion, issue and pull request thread. We are in the process of moving some remaining internal design docs and conversation threads to GitHub discussions, issues and pull requests. We hope to increasingly engage with the needs and clarifications of the broader ecosystem. Please let us know how we can help!
NOTE: The new Flax "Linen" module
API
is now stable and we recommend it for all new projects. The old
flax.nn
API will be deprecated.
Please report any feature requests, issues, questions or concerns in our discussion forum, or just let us know what you're working on!
We expect to add some improvements to Flax, but we only expect minor API changes to the core API. We will use Changelog entries and deprecation warnings when possible.
In case you want to reach us directly, we're at flax-dev@google.com.
Flax is a high-performance neural network library and ecosystem for JAX that is designed for flexibility: Try new forms of training by forking an example and by modifying the training loop, not by adding features to a framework.
Flax is being developed in close collaboration with the JAX team and comes with everything you need to start your research, including:
-
Neural network API (
flax.linen
): Dense, Conv, {Batch|Layer|Group} Norm, Attention, Pooling, {LSTM|GRU} Cell, Dropout -
Optimizers (
flax.optim
): SGD, Momentum, Adam, LARS, Adagrad, LAMB, RMSprop -
Utilities and patterns: replicated training, serialization and checkpointing, metrics, prefetching on device
-
Educational examples that work out of the box: MNIST, LSTM seq2seq, Graph Neural Networks, Sequence Tagging
-
Fast, tuned large-scale end-to-end examples: CIFAR10, ResNet on ImageNet, Transformer LM1b
You will need Python 3.6 or later and a working JAX installation (with or without GPU support, see instructions there). For a CPU-only version:
> pip install --upgrade pip # To support manylinux2010 wheels.
> pip install --upgrade jax jaxlib # CPU-only
Then install Flax from PyPi:
> pip install flax
To upgrade to the latest version of Flax, you can use:
> pip install --upgrade git+https://github.com/google/flax.git
We provide three examples using the Flax API: a simple multi-layer perceptron, a CNN and an auto-encoder.
To learn more about the Module
abstraction, please check our docs, our broad intro to the Module abstraction or visit our
patterns page for additional concrete demonstrations of best practices.
class MLP(nn.Module):
features: Sequence[int]
@nn.compact
def __call__(self, x):
for feat in self.features[:-1]:
x = nn.relu(Dense(feat)(x))
x = Dense(self.features[-1])(x)
return x
class CNN(nn.Module):
@nn.compact
def __call__(self, x):
x = nn.Conv(features=32, kernel_size=(3, 3))(x)
x = nn.relu(x)
x = nn.avg_pool(x, window_shape=(2, 2), strides=(2, 2))
x = nn.Conv(features=64, kernel_size=(3, 3))(x)
x = nn.relu(x)
x = nn.avg_pool(x, window_shape=(2, 2), strides=(2, 2))
x = x.reshape((x.shape[0], -1)) # flatten
x = nn.Dense(features=256)(x)
x = nn.relu(x)
x = nn.Dense(features=10)(x)
x = nn.log_softmax(x)
return x
class AutoEncoder(Module):
encoder_widths: Sequence[int]
decoder_widths: Sequence[int]
input_shape: Tuple[int] = None
def setup(self):
self.encoder = MLP(self.encoder_widths)
self.decoder = MLP(self.decoder_widths + (jnp.prod(self.input_shape, ))
def __call__(self, x):
return self.decode(self.encode(x))
def encode(self, x):
assert x.shape[1:] == self.input_shape
return self.encoder(jnp.reshape(x, (x.shape[0], -1)))
def decode(self, z):
z = self.decoder(z)
x = nn.sigmoid(z)
x = jnp.reshape(x, (x.shape[0],) + self.input_shape)
return x
This is not an official Google product.