TensorFlow Cloud

The TensorFlow Cloud repository provides APIs that will allow to easily go from debugging, training, tuning your Keras and TensorFlow code in a local environment to distributed training/tuning on Cloud.

Introduction

• TensorFlow Cloud run API

• TensorFlow Cloud Tuner

TensorFlow Cloud run API for GCP training/tuning

Installation

Requirements

• Python >= 3.6

• A Google Cloud project

• An authenticated GCP account

• Google AI platform APIs enabled for your GCP account. We use the AI platform for deploying docker images on GCP.

• Either a functioning version of docker if you want to use a local docker process for your build, or create a cloud storage bucket to use with Google Cloud build for docker image build and publishing.

• Authenticate to your Docker Container Registry

• (optional) nbconvert if you are using a notebook file as entry_point as shown in usage guide #4.

For detailed end to end setup instructions, please see Setup instructions.

Install latest release

pip install -U tensorflow-cloud

Install from source

git clone https://github.com/tensorflow/cloud.git
cd cloud
pip install src/python/.

High level overview

TensorFlow Cloud package provides the run API for training your models on GCP. To start, let's walk through a simple workflow using this API.

1. Let's begin with a Keras model training code such as the following, saved as mnist_example.py.

   import tensorflow as tf
   
   (x_train, y_train), (_, _) = tf.keras.datasets.mnist.load_data()
   
   x_train = x_train.reshape((60000, 28 * 28))
   x_train = x_train.astype('float32') / 255
   
   model = tf.keras.Sequential([
     tf.keras.layers.Dense(512, activation='relu', input_shape=(28 * 28,)),
     tf.keras.layers.Dropout(0.2),
     tf.keras.layers.Dense(10, activation='softmax')
   ])
   
   model.compile(loss='sparse_categorical_crossentropy',
                 optimizer=tf.keras.optimizers.Adam(),
                 metrics=['accuracy'])
   
   model.fit(x_train, y_train, epochs=10, batch_size=128)
   

2. After you have tested this model on your local environment for a few epochs, probably with a small dataset, you can train the model on Google Cloud by writing the following simple script scale_mnist.py.

   import tensorflow_cloud as tfc
   tfc.run(entry_point='mnist_example.py')
   

   Running scale_mnist.py will automatically apply TensorFlow one device strategy and train your model at scale on Google Cloud Platform. Please see the usage guide section for detailed instructions and additional API parameters.

3. You will see an output similar to the following on your console. This information can be used to track the training job status.

   user@desktop$ python scale_mnist.py
   Job submitted successfully.
   Your job ID is:  tf_cloud_train_519ec89c_a876_49a9_b578_4fe300f8865e
   Please access your job logs at the following URL:
   https://console.cloud.google.com/mlengine/jobs/tf_cloud_train_519ec89c_a876_49a9_b578_4fe300f8865e?project=prod-123
   

Setup instructions

End to end instructions to help set up your environment for Tensorflow Cloud. You use one of the following notebooks to setup your project or follow the instructions below.

Run in Colab

View on GitHub

Run in Kaggle

1. Create a new local directory

   mkdir tensorflow_cloud
   cd tensorflow_cloud
   

2. Make sure you have python >= 3.6

   python -V
   

3. Set up virtual environment

   virtualenv tfcloud --python=python3
   source tfcloud/bin/activate
   

4. Set up your Google Cloud project

   Verify that gcloud sdk is installed.

   which gcloud
   

   Set default gcloud project

   export PROJECT_ID=<your-project-id>
   gcloud config set project $PROJECT_ID
   

5. Authenticate your GCP account

   Create a service account.

   export SA_NAME=<your-sa-name>
   gcloud iam service-accounts create $SA_NAME
   gcloud projects add-iam-policy-binding $PROJECT_ID \
       --member serviceAccount:$SA_NAME@$PROJECT_ID.iam.gserviceaccount.com \
       --role 'roles/editor'
   

   Create a key for your service account.

   gcloud iam service-accounts keys create ~/key.json --iam-account $SA_NAME@$PROJECT_ID.iam.gserviceaccount.com
   

   Create the GOOGLE_APPLICATION_CREDENTIALS environment variable.

   export GOOGLE_APPLICATION_CREDENTIALS=~/key.json
   

6. Create a Cloud Storage bucket. Using Google Cloud build is the recommended method for building and publishing docker images, although we optionally allow for local docker daemon process depending on your specific needs.

   BUCKET_NAME="your-bucket-name"
   REGION="us-central1"
   gcloud auth login
   gsutil mb -l $REGION gs://$BUCKET_NAME
   

   (optional for local docker setup) shell sudo dockerd

7. Authenticate access to Google Cloud registry.

   gcloud auth configure-docker
   

8. Install nbconvert if you plan to use a notebook file entry_point as shown in usage guide #4.

   pip install nbconvert
   

9. Install latest release of tensorflow-cloud

   pip install tensorflow-cloud
   

Usage guide

As described in the high level overview, the run API allows you to train your models at scale on GCP. The run API can be used in four different ways. This is defined by where you are running the API (Terminal vs IPython notebook), and your entry_point parameter. entry_point is an optional Python script or notebook file path to the file that contains your TensorFlow Keras training code. This is the most important parameter in the API.

run(entry_point=None,
    requirements_txt=None,
    distribution_strategy='auto',
    docker_config='auto',
    chief_config='auto',
    worker_config='auto',
    worker_count=0,
    entry_point_args=None,
    stream_logs=False,
    job_labels=None,
    **kwargs)

1. Using a python file as entry_point.

   If you have your tf.keras model in a python file (mnist_example.py), then you can write the following simple script (scale_mnist.py) to scale your model on GCP.

   import tensorflow_cloud as tfc
   tfc.run(entry_point='mnist_example.py')
   

   Please note that all the files in the same directory tree as entry_point will be packaged in the docker image created, along with the entry_point file. It's recommended to create a new directory to house each cloud project which includes necessary files and nothing else, to optimize image build times.

2. Using a notebook file as entry_point.

   If you have your tf.keras model in a notebook file (mnist_example.ipynb), then you can write the following simple script (scale_mnist.py) to scale your model on GCP.

   import tensorflow_cloud as tfc
   tfc.run(entry_point='mnist_example.ipynb')
   

   Please note that all the files in the same directory tree as entry_point will be packaged in the docker image created, along with the entry_point file. Like the python script entry_point above, we recommended creating a new directory to house each cloud project which includes necessary files and nothing else, to optimize image build times.

3. Using run within a python script that contains the tf.keras model.

   You can use the run API from within your python file that contains the tf.keras model (mnist_scale.py). In this use case, entry_point should be None. The run API can be called anywhere and the entire file will be executed remotely. The API can be called at the end to run the script locally for debugging purposes (possibly with fewer epochs and other flags).

   import tensorflow_datasets as tfds
   import tensorflow as tf
   import tensorflow_cloud as tfc
   
   tfc.run(
       entry_point=None,
       distribution_strategy='auto',
       requirements_txt='requirements.txt',
       chief_config=tfc.MachineConfig(
               cpu_cores=8,
               memory=30,
               accelerator_type=tfc.AcceleratorType.NVIDIA_TESLA_T4,
               accelerator_count=2),
       worker_count=0)
   
   datasets, info = tfds.load(name='mnist', with_info=True, as_supervised=True)
   mnist_train, mnist_test = datasets['train'], datasets['test']
   
   num_train_examples = info.splits['train'].num_examples
   num_test_examples = info.splits['test'].num_examples
   
   BUFFER_SIZE = 10000
   BATCH_SIZE = 64
   
   def scale(image, label):
       image = tf.cast(image, tf.float32)
       image /= 255
       return image, label
   
   train_dataset = mnist_train.map(scale).cache()
   train_dataset = train_dataset.shuffle(BUFFER_SIZE).batch(BATCH_SIZE)
   
   model = tf.keras.Sequential([
       tf.keras.layers.Conv2D(32, 3, activation='relu', input_shape=(
           28, 28, 1)),
       tf.keras.layers.MaxPooling2D(),
       tf.keras.layers.Flatten(),
       tf.keras.layers.Dense(64, activation='relu'),
       tf.keras.layers.Dense(10, activation='softmax')
   ])
   
   model.compile(loss='sparse_categorical_crossentropy',
                 optimizer=tf.keras.optimizers.Adam(),
                 metrics=['accuracy'])
   model.fit(train_dataset, epochs=12)
   

   Please note that all the files in the same directory tree as the python script will be packaged in the docker image created, along with the python file. It's recommended to create a new directory to house each cloud project which includes necessary files and nothing else, to optimize image build times.

4. Using run within a notebook script that contains the tf.keras model.

   

   In this use case, entry_point should be None and docker_config.image_build_bucket must be specified, to ensure the build can be stored and published.

   Cluster and distribution strategy configuration

   By default, run API takes care of wrapping your model code in a TensorFlow distribution strategy based on the cluster configuration you have provided.

   No distribution

   CPU chief config and no additional workers

   tfc.run(entry_point='mnist_example.py',
           chief_config=tfc.COMMON_MACHINE_CONFIGS['CPU'])
   

   OneDeviceStrategy

   1 GPU on chief (defaults to AcceleratorType.NVIDIA_TESLA_T4) and no additional workers.

   tfc.run(entry_point='mnist_example.py')
   

   MirroredStrategy

   Chief config with multiple GPUS (AcceleratorType.NVIDIA_TESLA_V100).

   tfc.run(entry_point='mnist_example.py',
           chief_config=tfc.COMMON_MACHINE_CONFIGS['V100_4X'])
   

   MultiWorkerMirroredStrategy

   Chief config with 1 GPU and 2 workers each with 8 GPUs (AcceleratorType.NVIDIA_TESLA_V100).

   tfc.run(entry_point='mnist_example.py',
           chief_config=tfc.COMMON_MACHINE_CONFIGS['V100_1X'],
           worker_count=2,
           worker_config=tfc.COMMON_MACHINE_CONFIGS['V100_8X'])
   

   TPUStrategy

   Chief config with 1 CPU and 1 worker with TPU.

   tfc.run(entry_point="mnist_example.py",
           chief_config=tfc.COMMON_MACHINE_CONFIGS["CPU"],
           worker_count=1,
           worker_config=tfc.COMMON_MACHINE_CONFIGS["TPU"])
   

   Please note that TPUStrategy with TensorFlow Cloud works only with TF version 2.1 as this is the latest version supported by AI Platform cloud TPU

   Custom distribution strategy

   If you would like to take care of specifying distribution strategy in your model code and do not want run API to create a strategy, then set distribution_stategy as None. This will be required for example when you are using strategy.experimental_distribute_dataset.

   tfc.run(entry_point='mnist_example.py',
           distribution_strategy=None,
           worker_count=2)
   

What happens when you call run?

The API call will encompass the following:

1. Making code entities such as a Keras script/notebook, cloud and distribution ready.
2. Converting this distribution entity into a docker container with the required dependencies.
3. Deploy this container at scale and train using TensorFlow distribution strategies.
4. Stream logs and monitor them on hosted TensorBoard, manage checkpoint storage.

By default, we will use local docker daemon for building and publishing docker images to Google container registry. Images are published to gcr.io/your-gcp-project-id. If you specify docker_config.image_build_bucket, then we will use Google Cloud build to build and publish docker images.

We use Google AI platform for deploying docker images on GCP.

Please note that, when entry_point argument is specified, all the files in the same directory tree as entry_point will be packaged in the docker image created, along with the entry_point file.

Please see run API documentation for detailed information on the parameters and how you can modify the above processes to suit your needs.

End to end examples

cd src/python/tensorflow_cloud/core
python tests/examples/call_run_on_script_with_keras_fit.py

• Using a python file as entry_point (Keras fit API).
• Using a python file as entry_point (Keras custom training loop).
• Using a python file as entry_point (Keras save and load).
• Using a notebook file as entry_point.
• Using run within a python script that contains the tf.keras model.
• Using cloud build instead of local docker.
• Run AutoKeras with TensorFlow Cloud.

Running unit tests

pytest src/python/tensorflow_cloud/core/tests/unit/

Local vs remote training

Things to keep in mind when running your jobs remotely:

[Coming soon]

Debugging workflow

Here are some tips for fixing unexpected issues.

Operation disallowed within distribution strategy scope

Error like: Creating a generator within a strategy scope is disallowed, because there is ambiguity on how to replicate a generator (e.g. should it be copied so that each replica gets the same random numbers, or 'split' so that each replica gets different random numbers).

Solution: Passing distribution_strategy='auto' to run API wraps all of your script in a TF distribution strategy based on the cluster configuration provided. You will see the above error or something similar to it, if for some reason an operation is not allowed inside distribution strategy scope. To fix the error, please pass None to the distribution_strategy param and create a strategy instance as part of your training code as shown in this example.

Docker image build timeout

Error like: requests.exceptions.ConnectionError: ('Connection aborted.', timeout('The write operation timed out'))

Solution: The directory being used as an entry point likely has too much data for the image to successfully build, and there may be extraneous data included in the build. Reformat your directory structure such that the folder which contains the entry point only includes files necessary for the current project.

Version not supported for TPU training

Error like: There was an error submitting the job.Field: tpu_tf_version Error: The specified runtime version '2.3' is not supported for TPU training. Please specify a different runtime version.

Solution: Please use TF version 2.1. See TPU Strategy in Cluster and distribution strategy configuration section.

TF nightly build.

Warning like: Docker parent image '2.4.0.dev20200720' does not exist. Using the latest TF nightly build.

Solution: If you do not provide docker_config.parent_image param, then by default we use pre-built TF docker images as parent image. If you do not have TF installed on the environment where run is called, then TF docker image for the latest stable release will be used. Otherwise, the version of the docker image will match the locally installed TF version. However, pre-built TF docker images aren't available for TF nightlies except for the latest. So, if your local TF is an older nightly version, we upgrade to the latest nightly automatically and raise this warning.

Mixing distribution strategy objects.

Error like: RuntimeError: Mixing different tf.distribute.Strategy objects.

Solution: Please provide distribution_strategy=None when you already have a distribution strategy defined in your model code. Specifying distribution_strategy'='auto', will wrap your code in a TensorFlow distribution strategy. This will cause the above error, if there is a strategy object already used in your code.

Coming up

• Distributed Keras tuner support.

Contributing

We welcome community contributions, see CONTRIBUTING.md and, for style help, Writing TensorFlow documentation guide.

License

Apache License 2.0

Privacy Notice

This application reports technical and operational details of your usage of Cloud Services in accordance with Google privacy policy, for more information please refer to https://policies.google.com/privacy. If you wish to opt-out, you may do so by running tensorflow_cloud.utils.google_api_client.optout_metrics_reporting().