- Automated ML Introduction
- Setup using Compute Instances
- Setup using a Local Conda environment
- Setup using Azure Databricks
- Automated ML SDK Sample Notebooks
- Documentation
- Running using python command
- Troubleshooting
Automated machine learning (automated ML) builds high quality machine learning models for you by automating model and hyperparameter selection. Bring a labelled dataset that you want to build a model for, automated ML will give you a high quality machine learning model that you can use for predictions.
If you are new to Data Science, automated ML will help you get jumpstarted by simplifying machine learning model building. It abstracts you from needing to perform model selection, hyperparameter selection and in one step creates a high quality trained model for you to use.
If you are an experienced data scientist, automated ML will help increase your productivity by intelligently performing the model and hyperparameter selection for your training and generates high quality models much quicker than manually specifying several combinations of the parameters and running training jobs. Automated ML provides visibility and access to all the training jobs and the performance characteristics of the models to help you further tune the pipeline if you desire.
Below are the three execution environments supported by automated ML.
- Open the ML Azure portal
- Select Compute
- Select Compute Instances
- Click New
- Type a Compute Name, select a Virtual Machine type and select a Virtual Machine size
- Click Create
To run these notebook on your own notebook server, use these installation instructions. The instructions below will install everything you need and then start a Jupyter notebook.
1. Install mini-conda from here, choose 64-bit Python 3.7 or higher.
- Note: if you already have conda installed, you can keep using it but it should be version 4.4.10 or later (as shown by: conda -V). If you have a previous version installed, you can update it using the command: conda update conda. There's no need to install mini-conda specifically.
- Download the sample notebooks from GitHub as zip and extract the contents to a local directory. The automated ML sample notebooks are in the "automated-machine-learning" folder.
The automl_setup script creates a new conda environment, installs the necessary packages, configures the widget and starts a jupyter notebook. It takes the conda environment name as an optional parameter. The default conda environment name is azure_automl. The exact command depends on the operating system. See the specific sections below for Windows, Mac and Linux. It can take about 10 minutes to execute.
Packages installed by the automl_setup script:
- python
- nb_conda
- matplotlib
- numpy
- cython
- urllib3
- scipy
- scikit-learn
- pandas
- tensorflow
- py-xgboost
- azureml-sdk
- azureml-widgets
- pandas-ml
For more details refer to the automl_env.yml
Start an Anaconda Prompt window, cd to the how-to-use-azureml/automated-machine-learning folder where the sample notebooks were extracted and then run:
automl_setup
Install "Command line developer tools" if it is not already installed (you can use the command: xcode-select --install
).
Start a Terminal windows, cd to the how-to-use-azureml/automated-machine-learning folder where the sample notebooks were extracted and then run:
bash automl_setup_mac.sh
cd to the how-to-use-azureml/automated-machine-learning folder where the sample notebooks were extracted and then run:
bash automl_setup_linux.sh
- Before running any samples you next need to run the configuration notebook. Click on configuration notebook
- Execute the cells in the notebook to Register Machine Learning Services Resource Provider and create a workspace. (instructions in notebook)
- Please make sure you use the Python [conda env:azure_automl] kernel when trying the sample Notebooks.
- Follow the instructions in the individual notebooks to explore various features in automated ML.
To start your Jupyter notebook manually, use:
conda activate azure_automl
jupyter notebook
or on Mac or Linux:
source activate azure_automl
jupyter notebook
NOTE: Please create your Azure Databricks cluster as v6.0 (high concurrency preferred) with Python 3 (dropdown). NOTE: You should at least have contributor access to your Azure subcription to run the notebook.
- Please remove the previous SDK version if there is any and install the latest SDK by installing azureml-sdk[automl] as a PyPi library in Azure Databricks workspace.
- You can find the detail Readme instructions at GitHub.
- Download the sample notebook automl-databricks-local-01.ipynb from GitHub and import into the Azure databricks workspace.
- Attach the notebook to the cluster.
-
auto-ml-classification-credit-card-fraud.ipynb
- Dataset: Kaggle's credit card fraud detection dataset
- Simple example of using automated ML for classification to fraudulent credit card transactions
- Uses azure compute for training
-
- Dataset: Hardware Performance Dataset
- Simple example of using automated ML for regression
- Uses azure compute for training
-
auto-ml-regression-explanation-featurization.ipynb
- Dataset: Hardware Performance Dataset
- Shows featurization and excplanation
- Uses azure compute for training
-
auto-ml-forecasting-energy-demand.ipynb
- Dataset: NYC energy demand data
- Example of using automated ML for training a forecasting model
-
auto-ml-classification-credit-card-fraud-local.ipynb
- Dataset: Kaggle's credit card fraud detection dataset
- Simple example of using automated ML for classification to fraudulent credit card transactions
- Uses local compute for training
-
auto-ml-classification-bank-marketing-all-features.ipynb
- Dataset: UCI's bank marketing dataset
- Simple example of using automated ML for classification to predict term deposit subscriptions for a bank
- Uses azure compute for training
-
auto-ml-forecasting-orange-juice-sales.ipynb
- Dataset: Dominick's grocery sales of orange juice
- Example of training an automated ML forecasting model on multiple time-series
-
auto-ml-forecasting-bike-share.ipynb
- Dataset: forecasting for a bike-sharing
- Example of training an automated ML forecasting model on multiple time-series
-
auto-ml-forecasting-function.ipynb
- Example of training an automated ML forecasting model on multiple time-series
-
auto-ml-forecasting-beer-remote.ipynb
- Example of training an automated ML forecasting model on multiple time-series
- Beer Production Forecasting
-
auto-ml-continuous-retraining.ipynb
- Continuous retraining using Pipelines and Time-Series TabularDataset
-
auto-ml-classification-text-dnn.ipynb
- Classification with text data using deep learning in AutoML
- AutoML highlights here include using deep neural networks (DNNs) to create embedded features from text data.
- Depending on the compute cluster the user provides, AutoML tried out Bidirectional Encoder Representations from Transformers (BERT) when a GPU compute is used.
- Bidirectional Long-Short Term neural network (BiLSTM) when a CPU compute is used, thereby optimizing the choice of DNN for the uesr's setup.
See Configure automated machine learning experiments to learn how more about the the settings and features available for automated machine learning experiments.
Jupyter notebook provides a File / Download as / Python (.py) option for saving the notebook as a Python file. You can then run this file using the python command. However, on Windows the file needs to be modified before it can be run. The following condition must be added to the main code in the file:
if __name__ == "__main__":
The main code of the file must be indented so that it is under this condition.
- On Windows, make sure that you are running automl_setup from an Anconda Prompt window rather than a regular cmd window. You can launch the "Anaconda Prompt" window by hitting the Start button and typing "Anaconda Prompt". If you don't see the application "Anaconda Prompt", you might not have conda or mini conda installed. In that case, you can install it here
- Check that you have conda 64-bit installed rather than 32-bit. You can check this with the command
conda info
. Theplatform
should bewin-64
for Windows orosx-64
for Mac. - Check that you have conda 4.4.10 or later. You can check the version with the command
conda -V
. If you have a previous version installed, you can update it using the command:conda update conda
. - On Linux, if the error is
gcc: error trying to exec 'cc1plus': execvp: No such file or directory
, install build essentials using the commandsudo apt-get install build-essential
. - Pass a new name as the first parameter to automl_setup so that it creates a new conda environment. You can view existing conda environments using
conda env list
and remove them withconda env remove -n <environmentname>
.
If automl_setup_linux.sh fails on Ubuntu Linux with the error: unable to execute 'gcc': No such file or directory
- Make sure that outbound ports 53 and 80 are enabled. On an Azure VM, you can do this from the Azure Portal by selecting the VM and clicking on Networking.
- Run the command:
sudo apt-get update
- Run the command:
sudo apt-get install build-essential --fix-missing
- Run
automl_setup_linux.sh
again.
- For local conda, make sure that you have susccessfully run automl_setup first.
- Check that the subscription_id is correct. You can find the subscription_id in the Azure Portal by selecting All Service and then Subscriptions. The characters "<" and ">" should not be included in the subscription_id value. For example,
subscription_id = "12345678-90ab-1234-5678-1234567890abcd"
has the valid format. - Check that you have Contributor or Owner access to the Subscription.
- Check that the region is one of the supported regions:
eastus2
,eastus
,westcentralus
,southeastasia
,westeurope
,australiaeast
,westus2
,southcentralus
- Check that you have access to the region using the Azure Portal.
There were package changes in automated machine learning version 1.0.76, which require the previous version to be uninstalled before upgrading to the new version.
If you have manually upgraded from a version of automated machine learning before 1.0.76 to 1.0.76 or later, you may get the error:
ImportError: cannot import name 'AutoMLConfig'
This can be resolved by running:
pip uninstall azureml-train-automl
and then
pip install azureml-train-automl
The automl_setup.cmd script does this automatically.
If the call ws = Workspace.from_config()
fails:
- Make sure that you have run the
configuration.ipynb
notebook successfully. - If you are running a notebook from a folder that is not under the folder where you ran
configuration.ipynb
, copy the folder aml_config and the file config.json that it contains to the new folder. Workspace.from_config reads the config.json for the notebook folder or it parent folder. - If you are switching to a new subscription, resource group, workspace or region, make sure that you run the
configuration.ipynb
notebook again. Changing config.json directly will only work if the workspace already exists in the specified resource group under the specified subscription. - If you want to change the region, please change the workspace, resource group or subscription.
Workspace.create
will not create or update a workspace if it already exists, even if the region specified is different.
If a sample notebook fails with an error that property, method or library does not exist:
- Check that you have selected correct kernel in jupyter notebook. The kernel is displayed in the top right of the notebook page. It can be changed using the
Kernel | Change Kernel
menu option. For Azure Notebooks, it should bePython 3.6
. For local conda environments, it should be the conda envioronment name that you specified in automl_setup. The default is azure_automl. Note that the kernel is saved as part of the notebook. So, if you switch to a new conda environment, you will have to select the new kernel in the notebook. - Check that the notebook is for the SDK version that you are using. You can check the SDK version by executing
azureml.core.VERSION
in a jupyter notebook cell. You can download previous version of the sample notebooks from GitHub by clicking theBranch
button, selecting theTags
tab and then selecting the version.
Some Windows environments see an error loading numpy with the latest Python version 3.6.8. If you see this issue, try with Python version 3.6.7.
Check the tensorflow version in the automated ml conda environment. Supported versions are < 1.13. Uninstall tensorflow from the environment if version is >= 1.13 You may check the version of tensorflow and uninstall as follows
- start a command shell, activate conda environment where automated ml packages are installed
- enter
pip freeze
and look fortensorflow
, if found, the version listed should be < 1.13 - If the listed version is a not a supported version,
pip uninstall tensorflow
in the command shell and enter y for confirmation.
There are several reasons why the DsvmCompute.create can fail. The reason is usually in the error message but you have to look at the end of the error message for the detailed reason. Some common reasons are:
Compute name is invalid, it should start with a letter, be between 2 and 16 character, and only include letters (a-zA-Z), numbers (0-9) and \'-\'.
Note that underscore is not allowed in the name.The requested VM size xxxxx is not available in the current region.
You can select a different region or vm_size.
Automated ML uses the SSH protocol to communicate with remote DSVMs. This defaults to port 22. Possible causes for this error are:
- The DSVM is not ready for SSH connections. When DSVM creation completes, the DSVM might still not be ready to acceept SSH connections. The sample notebooks have a one minute delay to allow for this.
- Your Azure Subscription may restrict the IP address ranges that can access the DSVM on port 22. You can check this in the Azure Portal by selecting the Virtual Machine and then clicking Networking. The Virtual Machine name is the name that you provided in the notebook plus 10 alpha numeric characters to make the name unique. The Inbound Port Rules define what can access the VM on specific ports. Note that there is a priority priority order. So, a Deny entry with a low priority number will override a Allow entry with a higher priority number.
This is often an issue with the get_data
method.
- Check that the
get_data
method is valid by running it locally. - Make sure that
get_data
isn't referring to any local files.get_data
is executed on the remote DSVM. So, it doesn't have direct access to local data files. Instead you can store the data files with DataStore. See auto-ml-remote-execution-with-datastore.ipynb - You can get to the error log for the setup iteration by clicking the
Click here to see the run in Azure portal
link, clickBack to Experiment
, click on the highest run number and then click on Logs.
Automated ML creates files under /tmp/azureml_runs for each iteration that it runs. It creates a folder with the iteration id. For example: AutoML_9a038a18-77cc-48f1-80fb-65abdbc33abe_93. Under this, there is a azureml-logs folder, which contains logs. If you run too many iterations on the same DSVM, these files can fill the disk. You can delete the files under /tmp/azureml_runs or just delete the VM and create a new one. If your get_data downloads files, make sure the delete them or they can use disk space as well. When using DataStore, it is good to specify an absolute path for the files so that they are downloaded just once. If you specify a relative path, it will download a file for each iteration.
This can be caused by insufficient memory on the DSVM. Automated ML loads all training data into memory. So, the available memory should be more than the training data size. If you are using a remote DSVM, memory is needed for each concurrent iteration. The max_concurrent_iterations setting specifies the maximum concurrent iterations. For example, if the training data size is 8Gb and max_concurrent_iterations is set to 10, the minimum memory required is at least 80Gb. To resolve this issue, allocate a DSVM with more memory or reduce the value specified for max_concurrent_iterations.
This can be caused by too many concurrent iterations for a remote DSVM. Each concurrent iteration usually takes 100% of a core when it is running. Some iterations can use multiple cores. So, the max_concurrent_iterations setting should always be less than the number of cores of the DSVM. To resolve this issue, try reducing the value specified for the max_concurrent_iterations setting.