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A small library for managing deep learning models, hyper parameters and datasets

Project description

Zookeeper

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A small library for managing deep learning models, hyper parameters and datasets designed to make training deep learning models easy and reproducible.

Getting Started

Zookeeper allows you to build command line interfaces for training deep learning models with very little boiler plate using click and TensorFlow Datasets. It helps you structure your machine learning projects in a framework agnostic and effective way. Zookeeper is heavily inspired by Tensor2Tensor and Fairseq but is designed to be used as a library making it lightweight and very flexible. Currently zookeeper is limited to image classification tasks but we are working on making it useful for other tasks as well.

Installation

pip install zookeeper
pip install colorama  # optional for colored console output

Registry

Zookeeper keeps track of data preprocessing, models and hyperparameters to allow you to reference them by name from the commandline.

Datasets and Preprocessing

TensorFlow Datasets provides many popular datasets that can be downloaded automatically. In the following we will use MNIST and define a default preprocessing for the images that scales the image to [0, 1]:

import tensorflow as tf

from zookeeper import cli, build_train, HParams, registry

@registry.register_preprocess("mnist")
def default(image, training=False):
    return tf.cast(image, dtype=tf.float32) / 255

Models

Next we will register a model called cnn. We will use the Keras API for this:

@registry.register_model
def cnn(hp, dataset):
    return tf.keras.models.Sequential(
        [
            tf.keras.layers.Conv2D(
                hp.filters[0],
                (3, 3),
                activation=hp.activation,
                input_shape=dataset.input_shape,
            ),
            tf.keras.layers.MaxPooling2D((2, 2)),
            tf.keras.layers.Conv2D(hp.filters[1], (3, 3), activation=hp.activation),
            tf.keras.layers.MaxPooling2D((2, 2)),
            tf.keras.layers.Conv2D(hp.filters[2], (3, 3), activation=hp.activation),
            tf.keras.layers.Flatten(),
            tf.keras.layers.Dense(hp.filters[3], activation=hp.activation),
            tf.keras.layers.Dense(dataset.num_classes, activation="softmax"),
        ]
    )

Hyperparameters

For each model we can register one or more hyperparameters sets that will be passed to the model function when called:

@registry.register_hparams(cnn)
class basic(HParams):
    activation = "relu"
    batch_size = 32
    filters = [64, 64, 64, 64]
    learning_rate = 1e-3

    @property
    def optimizer(self):
        return tf.keras.optimizers.Adam(self.learning_rate)

Training loop

To train the models registered above we will need to write a custom training loop. Zookeeper will then tie everything together:

@cli.command()
@build_train
def train(build_model, dataset, hparams, output_dir, epochs):
    model = build_model(hparams, dataset)
    model.compile(
        optimizer=hparams.optimizer,
        loss="categorical_crossentropy",
        metrics=["categorical_accuracy", "top_k_categorical_accuracy"],
    )

    model.fit(
        dataset.train_data(hparams.batch_size),
        epochs=epochs,
        steps_per_epoch=dataset.train_examples // hparams.batch_size,
        validation_data=dataset.validation_data(hparams.batch_size),
        validation_steps=dataset.validation_examples // hparams.batch_size,
    )

This will register Click command called train which can be executed from the command line.

Command Line Interface

To make the file we just created executable we will add the following lines at the bottom:

if __name__ == "__main__":
    cli()

If you want to register your models in separate files, make sure to import them before calling cli to allow zookeeper to properly register them. To install your CLI as a executable command checkout the setuptools integration of Click.

Usage

Zookeeper already ships with prepare, plot, and tensorboard commands, but now also includes the train command we created above:

python examples/train.py --help
Usage: train.py [OPTIONS] COMMAND [ARGS]...

Options:
  --help  Show this message and exit.

Commands:
  plot
  prepare
  tensorboard
  train

To train the model we just registered run:

python examples/train.py train cnn --dataset mnist --epochs 10 --hparams-set basic --hparams batch_size=64

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