• Stars
    star
    1,183
  • Rank 39,544 (Top 0.8 %)
  • Language
    Python
  • Created almost 7 years ago
  • Updated over 1 year ago

Reviews

There are no reviews yet. Be the first to send feedback to the community and the maintainers!

Repository Details

Example project implementing best practices for PySpark ETL jobs and applications.

PySpark Example Project

This document is designed to be read in parallel with the code in the pyspark-template-project repository. Together, these constitute what we consider to be a 'best practices' approach to writing ETL jobs using Apache Spark and its Python ('PySpark') APIs. This project addresses the following topics:

  • how to structure ETL code in such a way that it can be easily tested and debugged;
  • how to pass configuration parameters to a PySpark job;
  • how to handle dependencies on other modules and packages; and,
  • what constitutes a 'meaningful' test for an ETL job.

ETL Project Structure

The basic project structure is as follows:

root/
 |-- configs/
 |   |-- etl_config.json
 |-- dependencies/
 |   |-- logging.py
 |   |-- spark.py
 |-- jobs/
 |   |-- etl_job.py
 |-- tests/
 |   |-- test_data/
 |   |-- | -- employees/
 |   |-- | -- employees_report/
 |   |-- test_etl_job.py
 |   build_dependencies.sh
 |   packages.zip
 |   Pipfile
 |   Pipfile.lock

The main Python module containing the ETL job (which will be sent to the Spark cluster), is jobs/etl_job.py. Any external configuration parameters required by etl_job.py are stored in JSON format in configs/etl_config.json. Additional modules that support this job can be kept in the dependencies folder (more on this later). In the project's root we include build_dependencies.sh, which is a bash script for building these dependencies into a zip-file to be sent to the cluster (packages.zip). Unit test modules are kept in the tests folder and small chunks of representative input and output data, to be used with the tests, are kept in tests/test_data folder.

Structure of an ETL Job

In order to facilitate easy debugging and testing, we recommend that the 'Transformation' step be isolated from the 'Extract' and 'Load' steps, into its own function - taking input data arguments in the form of DataFrames and returning the transformed data as a single DataFrame. Then, the code that surrounds the use of the transformation function in the main() job function, is concerned with Extracting the data, passing it to the transformation function and then Loading (or writing) the results to their ultimate destination. Testing is simplified, as mock or test data can be passed to the transformation function and the results explicitly verified, which would not be possible if all of the ETL code resided in main() and referenced production data sources and destinations.

More generally, transformation functions should be designed to be idempotent. This is a technical way of saying that the repeated application of the transformation function should have no impact on the fundamental state of output data, until the moment the input data changes. One of the key advantages of idempotent ETL jobs, is that they can be set to run repeatedly (e.g. by using cron to trigger the spark-submit command above, on a pre-defined schedule), rather than having to factor-in potential dependencies on other ETL jobs completing successfully.

Passing Configuration Parameters to the ETL Job

Although it is possible to pass arguments to etl_job.py, as you would for any generic Python module running as a 'main' program - by specifying them after the module's filename and then parsing these command line arguments - this can get very complicated, very quickly, especially when there are lot of parameters (e.g. credentials for multiple databases, table names, SQL snippets, etc.). This also makes debugging the code from within a Python interpreter extremely awkward, as you don't have access to the command line arguments that would ordinarily be passed to the code, when calling it from the command line.

A much more effective solution is to send Spark a separate file - e.g. using the --files configs/etl_config.json flag with spark-submit - containing the configuration in JSON format, which can be parsed into a Python dictionary in one line of code with json.loads(config_file_contents). Testing the code from within a Python interactive console session is also greatly simplified, as all one has to do to access configuration parameters for testing, is to copy and paste the contents of the file - e.g.,

import json

config = json.loads("""{"field": "value"}""")

For the exact details of how the configuration file is located, opened and parsed, please see the start_spark() function in dependencies/spark.py (also discussed further below), which in addition to parsing the configuration file sent to Spark (and returning it as a Python dictionary), also launches the Spark driver program (the application) on the cluster and retrieves the Spark logger at the same time.

Packaging ETL Job Dependencies

In this project, functions that can be used across different ETL jobs are kept in a module called dependencies and referenced in specific job modules using, for example,

from dependencies.spark import start_spark

This package, together with any additional dependencies referenced within it, must be copied to each Spark node for all jobs that use dependencies to run. This can be achieved in one of several ways:

  1. send all dependencies as a zip archive together with the job, using --py-files with Spark submit;
  2. formally package and upload dependencies to somewhere like the PyPI archive (or a private version) and then run pip3 install dependencies on each node; or,
  3. a combination of manually copying new modules (e.g. dependencies) to the Python path of each node and using pip3 install for additional dependencies (e.g. for requests).

Option (1) is by far the easiest and most flexible approach, so we will make use of this for now. To make this task easier, especially when modules such as dependencies have additional dependencies (e.g. the requests package), we have provided the build_dependencies.sh bash script for automating the production of packages.zip, given a list of dependencies documented in Pipfile and managed by the pipenv python application (discussed below).

Running the ETL job

Assuming that the $SPARK_HOME environment variable points to your local Spark installation folder, then the ETL job can be run from the project's root directory using the following command from the terminal,

$SPARK_HOME/bin/spark-submit \
--master local[*] \
--packages 'com.somesparkjar.dependency:1.0.0' \
--py-files packages.zip \
--files configs/etl_config.json \
jobs/etl_job.py

Briefly, the options supplied serve the following purposes:

  • --master local[*] - the address of the Spark cluster to start the job on. If you have a Spark cluster in operation (either in single-executor mode locally, or something larger in the cloud) and want to send the job there, then modify this with the appropriate Spark IP - e.g. spark://the-clusters-ip-address:7077;
  • --packages 'com.somesparkjar.dependency:1.0.0,...' - Maven coordinates for any JAR dependencies required by the job (e.g. JDBC driver for connecting to a relational database);
  • --files configs/etl_config.json - the (optional) path to any config file that may be required by the ETL job;
  • --py-files packages.zip - archive containing Python dependencies (modules) referenced by the job; and,
  • jobs/etl_job.py - the Python module file containing the ETL job to execute.

Full details of all possible options can be found here. Note, that we have left some options to be defined within the job (which is actually a Spark application) - e.g. spark.cores.max and spark.executor.memory are defined in the Python script as it is felt that the job should explicitly contain the requests for the required cluster resources.

Debugging Spark Jobs Using start_spark

It is not practical to test and debug Spark jobs by sending them to a cluster using spark-submit and examining stack traces for clues on what went wrong. A more productive workflow is to use an interactive console session (e.g. IPython) or a debugger (e.g. the pdb package in the Python standard library or the Python debugger in Visual Studio Code). In practice, however, it can be hard to test and debug Spark jobs in this way, as they implicitly rely on arguments that are sent to spark-submit, which are not available in a console or debug session.

We wrote the start_spark function - found in dependencies/spark.py - to facilitate the development of Spark jobs that are aware of the context in which they are being executed - i.e. as spark-submit jobs or within an IPython console, etc. The expected location of the Spark and job configuration parameters required by the job, is contingent on which execution context has been detected. The docstring for start_spark gives the precise details,

def start_spark(app_name='my_spark_app', master='local[*]', jar_packages=[],
                files=[], spark_config={}):
    """Start Spark session, get Spark logger and load config files.

    Start a Spark session on the worker node and register the Spark
    application with the cluster. Note, that only the app_name argument
    will apply when this is called from a script sent to spark-submit.
    All other arguments exist solely for testing the script from within
    an interactive Python console.

    This function also looks for a file ending in 'config.json' that
    can be sent with the Spark job. If it is found, it is opened,
    the contents parsed (assuming it contains valid JSON for the ETL job
    configuration) into a dict of ETL job configuration parameters,
    which are returned as the last element in the tuple returned by
    this function. If the file cannot be found then the return tuple
    only contains the Spark session and Spark logger objects and None
    for config.

    The function checks the enclosing environment to see if it is being
    run from inside an interactive console session or from an
    environment which has a `DEBUG` environment variable set (e.g.
    setting `DEBUG=1` as an environment variable as part of a debug
    configuration within an IDE such as Visual Studio Code or PyCharm.
    In this scenario, the function uses all available function arguments
    to start a PySpark driver from the local PySpark package as opposed
    to using the spark-submit and Spark cluster defaults. This will also
    use local module imports, as opposed to those in the zip archive
    sent to spark via the --py-files flag in spark-submit.

    :param app_name: Name of Spark app.
    :param master: Cluster connection details (defaults to local[*]).
    :param jar_packages: List of Spark JAR package names.
    :param files: List of files to send to Spark cluster (master and
        workers).
    :param spark_config: Dictionary of config key-value pairs.
    :return: A tuple of references to the Spark session, logger and
        config dict (only if available).
    """

    # ...

    return spark_sess, spark_logger, config_dict

For example, the following code snippet,

spark, log, config = start_spark(
    app_name='my_etl_job',
    jar_packages=['com.somesparkjar.dependency:1.0.0'],
    files=['configs/etl_config.json'])

Will use the arguments provided to start_spark to setup the Spark job if executed from an interactive console session or debugger, but will look for the same arguments sent via spark-submit if that is how the job has been executed.

Automated Testing

In order to test with Spark, we use the pyspark Python package, which is bundled with the Spark JARs required to programmatically start-up and tear-down a local Spark instance, on a per-test-suite basis (we recommend using the setUp and tearDown methods in unittest.TestCase to do this once per test-suite). Note, that using pyspark to run Spark is an alternative way of developing with Spark as opposed to using the PySpark shell or spark-submit.

Given that we have chosen to structure our ETL jobs in such a way as to isolate the 'Transformation' step into its own function (see 'Structure of an ETL job' above), we are free to feed it a small slice of 'real-world' production data that has been persisted locally - e.g. in tests/test_data or some easily accessible network directory - and check it against known results (e.g. computed manually or interactively within a Python interactive console session).

To execute the example unit test for this project run,

pipenv run python -m unittest tests/test_*.py

If you're wondering what the pipenv command is, then read the next section.

Managing Project Dependencies using Pipenv

We use pipenv for managing project dependencies and Python environments (i.e. virtual environments). All direct packages dependencies (e.g. NumPy may be used in a User Defined Function), as well as all the packages used during development (e.g. PySpark, flake8 for code linting, IPython for interactive console sessions, etc.), are described in the Pipfile. Their precise downstream dependencies are described in Pipfile.lock.

Installing Pipenv

To get started with Pipenv, first of all download it - assuming that there is a global version of Python available on your system and on the PATH, then this can be achieved by running the following command,

pip3 install pipenv

Pipenv is also available to install from many non-Python package managers. For example, on OS X it can be installed using the Homebrew package manager, with the following terminal command,

brew install pipenv

For more information, including advanced configuration options, see the official pipenv documentation.

Installing this Projects' Dependencies

Make sure that you're in the project's root directory (the same one in which the Pipfile resides), and then run,

pipenv install --dev

This will install all of the direct project dependencies as well as the development dependencies (the latter a consequence of the --dev flag).

Running Python and IPython from the Project's Virtual Environment

In order to continue development in a Python environment that precisely mimics the one the project was initially developed with, use Pipenv from the command line as follows,

pipenv run python3

The python3 command could just as well be ipython3, for example,

pipenv run ipython

This will fire-up an IPython console session where the default Python 3 kernel includes all of the direct and development project dependencies - this is our preference.

Pipenv Shells

Prepending pipenv to every command you want to run within the context of your Pipenv-managed virtual environment can get very tedious. This can be avoided by entering into a Pipenv-managed shell,

pipenv shell

This is equivalent to 'activating' the virtual environment; any command will now be executed within the virtual environment. Use exit to leave the shell session.

Automatic Loading of Environment Variables

Pipenv will automatically pick-up and load any environment variables declared in the .env file, located in the package's root directory. For example, adding,

SPARK_HOME=applications/spark-2.3.1/bin
DEBUG=1

Will enable access to these variables within any Python program -e.g. via a call to os.environ['SPARK_HOME']. Note, that if any security credentials are placed here, then this file must be removed from source control - i.e. add .env to the .gitignore file to prevent potential security risks.

More Repositories

1

kubernetes-mlops

MLOps tutorial using Python, Docker and Kubernetes.
Python
311
star
2

pymc-example-project

Example PyMC3 project for performing Bayesian data analysis using a probabilistic programming approach to machine learning.
Jupyter Notebook
98
star
3

py-package-template

Python package template project for kick-starting new Python projects.
Python
76
star
4

pipeliner

Machine learning pipelines for R.
R
65
star
5

ml-workflow-automation

Python Machine Learning (ML) project that demonstrates the archetypal ML workflow within a Jupyter notebook, with automated model deployment as a RESTful service on Kubernetes.
Jupyter Notebook
56
star
6

elasticsearchr

Lightweight Elasticsearch client for R.
R
54
star
7

py-docker-aws-example-project

Automated testing and deployment of a simple Flask-based (RESTful) micro-service to a production-like environment on AWS, using Docker containers and Travis-CI.
Python
39
star
8

pymc-stochastic-process

Demonstrating the benefits of using Bayesian Inference and PYMC3 for estimating the parameters of stochastic processes commonly used in quantitative finance.
Jupyter Notebook
37
star
9

pymc-advi-hmc-demo

Demonstrating HMC and ADVI algorithms for Bayesian data analysis using PYMC3.
Jupyter Notebook
13
star
10

data-science-and-ml-notebook

Data science and ML engineering notebooks and demos
11
star
11

lime-interpretable-ml

An example of how the LIME algorithm can be used to provide real-world insight into the decision processes of a 'black-box' machine learning algorithm - in this case a Radom Forest regressor.
Jupyter Notebook
10
star
12

bodywork-mlops-demo

Demonstrating how Bodywork can be used to deploy a simulation of the lifecycle of a train-and-serve ML pipeline, responding to new data undergoing concept drift.
Jupyter Notebook
9
star
13

pycaret-mlops

Using PyCaret with Bodywork to deploy ML pipelines to Kuberentes
Jupyter Notebook
7
star
14

alexioannides

Python source code for generating my website at alexaioannides.github.io.
CSS
3
star
15

alexioannides.github.io

My GitHub Pages website and blog about all things (data) science and probably a lot more.
HTML
2
star
16

registerit

Have an idea for a Python package? Register the name on PyPI πŸ’‘
Python
1
star