Train TensorFlow models at scale with Azure Machine Learning
In this article, learn how to run your TensorFlow training scripts at scale using Azure Machine Learning.
This example trains and registers a TensorFlow model to classify handwritten digits using a deep neural network (DNN).
Whether you're developing a TensorFlow model from the ground-up or you're bringing an existing model into the cloud, you can use Azure Machine Learning to scale out open-source training jobs to build, deploy, version, and monitor production-grade models.
Run this code on either of these environments:
Azure Machine Learning compute instance - no downloads or installation necessary
- Complete the Quickstart: Get started with Azure Machine Learningto create a dedicated notebook server pre-loaded with the SDK and the sample repository.
- In the samples deep learning folder on the notebook server, find a completed and expanded notebook by navigating to this directory: how-to-use-azureml > ml-frameworks > tensorflow > train-hyperparameter-tune-deploy-with-tensorflow folder.
Your own Jupyter Notebook server
- Install the Azure Machine Learning SDK (>= 1.15.0).
- Create a workspace configuration file.
- Download the sample script files
You can also find a completed Jupyter Notebook version of this guide on the GitHub samples page. The notebook includes expanded sections covering intelligent hyperparameter tuning, model deployment, and notebook widgets.
Set up the experiment
This section sets up the training experiment by loading the required Python packages, initializing a workspace, creating the compute target, and defining the training environment.
First, import the necessary Python libraries.
import os import urllib import shutil import azureml from azureml.core import Experiment from azureml.core import Workspace, Run from azureml.core import Environment from azureml.core.compute import ComputeTarget, AmlCompute from azureml.core.compute_target import ComputeTargetException
Initialize a workspace
The Azure Machine Learning workspace is the top-level resource for the service. It provides you with a centralized place to work with all the artifacts you create. In the Python SDK, you can access the workspace artifacts by creating a
Create a workspace object from the
config.json file created in the prerequisites section.
ws = Workspace.from_config()
Create a file dataset
FileDataset object references one or multiple files in your workspace datastore or public urls. The files can be of any format, and the class provides you with the ability to download or mount the files to your compute. By creating a
FileDataset, you create a reference to the data source location. If you applied any transformations to the data set, they will be stored in the data set as well. The data remains in its existing location, so no extra storage cost is incurred. See the how-to guide on the
Dataset package for more information.
from azureml.core.dataset import Dataset web_paths = [ 'http://yann.lecun.com/exdb/mnist/train-images-idx3-ubyte.gz', 'http://yann.lecun.com/exdb/mnist/train-labels-idx1-ubyte.gz', 'http://yann.lecun.com/exdb/mnist/t10k-images-idx3-ubyte.gz', 'http://yann.lecun.com/exdb/mnist/t10k-labels-idx1-ubyte.gz' ] dataset = Dataset.File.from_files(path=web_paths)
register() method to register the data set to your workspace so they can be shared with others, reused across various experiments, and referred to by name in your training script.
dataset = dataset.register(workspace=ws, name='mnist-dataset', description='training and test dataset', create_new_version=True) # list the files referenced by dataset dataset.to_path()
Create a compute target
Create a compute target for your TensorFlow job to run on. In this example, create a GPU-enabled Azure Machine Learning compute cluster.
cluster_name = "gpu-cluster" try: compute_target = ComputeTarget(workspace=ws, name=cluster_name) print('Found existing compute target') except ComputeTargetException: print('Creating a new compute target...') compute_config = AmlCompute.provisioning_configuration(vm_size='STANDARD_NC6', max_nodes=4) compute_target = ComputeTarget.create(ws, cluster_name, compute_config) compute_target.wait_for_completion(show_output=True, min_node_count=None, timeout_in_minutes=20)
For more information on compute targets, see the what is a compute target article.
Define your environment
To define the Azure ML Environment that encapsulates your training script's dependencies, you can either define a custom environment or use an Azure ML curated environment.
Use a curated environment
Azure ML provides prebuilt, curated environments if you don't want to define your own environment. Azure ML has several CPU and GPU curated environments for TensorFlow corresponding to different versions of TensorFlow. For more info, see here.
If you want to use a curated environment, you can run the following command instead:
curated_env_name = 'AzureML-TensorFlow-2.2-GPU' tf_env = Environment.get(workspace=ws, name=curated_env_name)
To see the packages included in the curated environment, you can write out the conda dependencies to disk:
Make sure the curated environment includes all the dependencies required by your training script. If not, you will have to modify the environment to include the missing dependencies. Note that if the environment is modified, you will have to give it a new name, as the 'AzureML' prefix is reserved for curated environments. If you modified the conda dependencies YAML file, you can create a new environment from it with a new name, e.g.:
tf_env = Environment.from_conda_specification(name='tensorflow-2.2-gpu', file_path='./conda_dependencies.yml')
If you had instead modified the curated environment object directly, you can clone that environment with a new name:
tf_env = tf_env.clone(new_name='tensorflow-2.2-gpu')
Create a custom environment
You can also create your own Azure ML environment that encapsulates your training script's dependencies.
First, define your conda dependencies in a YAML file; in this example the file is named
channels: - conda-forge dependencies: - python=3.6.2 - pip: - azureml-defaults - tensorflow-gpu==2.2.0
Create an Azure ML environment from this conda environment specification. The environment will be packaged into a Docker container at runtime.
By default if no base image is specified, Azure ML will use a CPU image
azureml.core.environment.DEFAULT_CPU_IMAGE as the base image. Since this example runs training on a GPU cluster, you will need to specify a GPU base image that has the necessary GPU drivers and dependencies. Azure ML maintains a set of base images published on Microsoft Container Registry (MCR) that you can use, see the Azure/AzureML-Containers GitHub repo for more information.
tf_env = Environment.from_conda_specification(name='tensorflow-2.2-gpu', file_path='./conda_dependencies.yml') # Specify a GPU base image tf_env.docker.enabled = True tf_env.docker.base_image = 'mcr.microsoft.com/azureml/openmpi3.1.2-cuda10.1-cudnn7-ubuntu18.04'
Optionally, you can just capture all your dependencies directly in a custom Docker image or Dockerfile, and create your environment from that. For more information, see Train with custom image.
For more information on creating and using environments, see Create and use software environments in Azure Machine Learning.
Configure and submit your training run
Create a ScriptRunConfig
Create a ScriptRunConfig object to specify the configuration details of your training job, including your training script, environment to use, and the compute target to run on. Any arguments to your training script will be passed via command line if specified in the
from azureml.core import ScriptRunConfig args = ['--data-folder', dataset.as_mount(), '--batch-size', 64, '--first-layer-neurons', 256, '--second-layer-neurons', 128, '--learning-rate', 0.01] src = ScriptRunConfig(source_directory=script_folder, script='tf_mnist.py', arguments=args, compute_target=compute_target, environment=tf_env)
Azure Machine Learning runs training scripts by copying the entire source directory. If you have sensitive data that you don't want to upload, use a .ignore file or don't include it in the source directory . Instead, access your data using an Azure ML dataset.
For more information on configuring jobs with ScriptRunConfig, see Configure and submit training runs.
If you were previously using the TensorFlow estimator to configure your TensorFlow training jobs, please note that Estimators have been deprecated as of the 1.19.0 SDK release. With Azure ML SDK >= 1.15.0, ScriptRunConfig is the recommended way to configure training jobs, including those using deep learning frameworks. For common migration questions, see the Estimator to ScriptRunConfig migration guide.
Submit a run
The Run object provides the interface to the run history while the job is running and after it has completed.
run = Experiment(workspace=ws, name='Tutorial-TF-Mnist').submit(src) run.wait_for_completion(show_output=True)
What happens during run execution
As the run is executed, it goes through the following stages:
Preparing: A docker image is created according to the environment defined. The image is uploaded to the workspace's container registry and cached for later runs. Logs are also streamed to the run history and can be viewed to monitor progress. If a curated environment is specified instead, the cached image backing that curated environment will be used.
Scaling: The cluster attempts to scale up if the Batch AI cluster requires more nodes to execute the run than are currently available.
Running: All scripts in the script folder are uploaded to the compute target, data stores are mounted or copied, and the
scriptis executed. Outputs from stdout and the ./logs folder are streamed to the run history and can be used to monitor the run.
Post-Processing: The ./outputs folder of the run is copied over to the run history.
Register or download a model
Once you've trained the model, you can register it to your workspace. Model registration lets you store and version your models in your workspace to simplify model management and deployment. Optional: by specifying the parameters
resource_configuration, no-code model deployment becomes available. This allows you to directly deploy your model as a web service from the registered model, and the
ResourceConfiguration object defines the compute resource for the web service.
from azureml.core import Model from azureml.core.resource_configuration import ResourceConfiguration model = run.register_model(model_name='tf-mnist', model_path='outputs/model', model_framework=Model.Framework.TENSORFLOW, model_framework_version='2.0', resource_configuration=ResourceConfiguration(cpu=1, memory_in_gb=0.5))
You can also download a local copy of the model by using the Run object. In the training script
tf_mnist.py, a TensorFlow saver object persists the model to a local folder (local to the compute target). You can use the Run object to download a copy.
# Create a model folder in the current directory os.makedirs('./model', exist_ok=True) run.download_files(prefix='outputs/model', output_directory='./model', append_prefix=False)
Azure Machine Learning also supports multi-node distributed TensorFlow jobs so that you can scale your training workloads. You can easily run distributed TensorFlow jobs and Azure ML will manage the orchestration for you.
Azure ML supports running distributed TensorFlow jobs with both Horovod and TensorFlow's built-in distributed training API.
For more information about distributed training, see the Distributed GPU training guide.
Deploy a TensorFlow model
The deployment how-to contains a section on registering models, but you can skip directly to creating a compute target for deployment, since you already have a registered model.
(Preview) No-code model deployment
Instead of the traditional deployment route, you can also use the no-code deployment feature (preview) for TensorFlow. By registering your model as shown above with the
resource_configuration parameters, you can simply use the
deploy() static function to deploy your model.
service = Model.deploy(ws, "tensorflow-web-service", [model])
The full how-to covers deployment in Azure Machine Learning in greater depth.
In this article, you trained and registered a TensorFlow model, and learned about options for deployment. See these other articles to learn more about Azure Machine Learning.