reax 0.6.4

REAX: A simple training framework for JAX-based projects

REAX

REAX — Scalable, flexible training for JAX, inspired by the simplicity of PyTorch Lightning.

REAX - Scalable Training for JAX

REAX is a minimal and high-performance framework for training JAX models, designed to simplify research workflows. Inspired by PyTorch Lightning, it brings similar high-level abstractions and scalability to JAX users, making it easier to scale models across multiple GPUs with minimal boilerplate. 🚀

A Port of PyTorch Lightning to JAX

Much of REAX is built by porting the best practices and abstractions of PyTorch Lightning to the JAX ecosystem. If you’re familiar with PyTorch Lightning, you’ll recognize concepts like:

• Training loops ⚡

• Multi-GPU training 🖥️

• Logging and checkpointing 💾

However, REAX has been designed with JAX-specific optimizations, ensuring high performance without sacrificing flexibility.

Why REAX? 🌟

• Scalable: Built to leverage JAX’s parallelism and scalability. ⚡

• Minimal Boilerplate: Simplifies the training process with just enough structure. 🧩

• Familiar: For users who have experience with frameworks like PyTorch Lightning, the transition to REAX is seamless. 🔄

Installation 🛠️

To install REAX, run the following command:

pip install reax

REAX example

Define the training workflow. Here’s a toy example:

# main.py
from functools import partial
import jax, optax, reax, flax.linen as linen
from reax.demos import mnist


class Autoencoder(linen.Module):
    def setup(self):
        super().__init__()
        self.encoder = linen.Sequential([linen.Dense(128), linen.relu, linen.Dense(3)])
        self.decoder = linen.Sequential([linen.Dense(128), linen.relu, linen.Dense(28 * 28)])

    def __call__(self, x):
        z = self.encoder(x)
        return self.decoder(z)


# --------------------------------
# Step 1: Define a REAX Module
# --------------------------------
# A ReaxModule (nn.Module subclass) defines a full *system*
# (ie: an LLM, diffusion model, autoencoder, or simple image classifier).
class ReaxAutoEncoder(reax.Module):
    def __init__(self):
        super().__init__()
        self.ae = Autoencoder()

    def configure_model(self, stage: reax.Stage, batch, /):
        if self.parameters() is None:
            x = batch[0].reshape(len(batch[0]), -1)
            params = self.ae.init(self.rngs(), x)
            self.set_parameters(params)

    def __call__(self, *args, **kwargs):
        return self.forward(*args, **kwargs)

    def forward(self, x):
        embedding = jax.jit(self.ae.encoder.apply)(self.parameters()["params"]["encoder"], x)
        return embedding

    def training_step(self, batch, batch_idx):
        x = batch[0].reshape(len(batch[0]), -1)
        loss, grads = jax.value_and_grad(self.loss_fn, argnums=0)(self.parameters(), x, self.ae)
        self.log("train_loss", loss, on_step=True, prog_bar=True)
        return loss, grads

    @staticmethod
    @partial(jax.jit, static_argnums=2)
    def loss_fn(params, x, model):
        predictions = model.apply(params, x)
        return optax.losses.squared_error(predictions, x).mean()

    def configure_optimizers(self):
        opt = optax.adam(learning_rate=1e-3)
        state = opt.init(self.parameters())
        return opt, state


# -------------------
# Step 2: Define data
# -------------------
dataset = mnist.MnistDataset(download=True)
trainer = reax.Trainer()
train, val = reax.data.random_split(trainer.rngs, dataset, [55000, 5000])

# -------------------
# Step 3: Train
# -------------------
autoencoder = ReaxAutoEncoder()
trainer.fit(autoencoder, reax.ReaxDataLoader(train), reax.ReaxDataLoader(val))

Here, we reproduce an example from PyTorch Lightning, so we use torch vision to fetch the data, but for real models there’s no need to use this or pytorch at all.

Disclaimer ⚠️

REAX takes inspiration from PyTorch Lightning, and large portions of its core functionality are directly ported from Lightning. If you are already familiar with Lightning, you’ll feel right at home with REAX, but we’ve tailored it to work seamlessly with JAX’s performance optimizations.