Python-lambda is a toolset for developing and deploying serverless Python code in AWS Lambda.
With python-lambda and pytube both continuing to gain momentum, I'm calling for contributors to help build out new features, review pull requests, fix bugs, and maintain overall code quality. If you're interested, please email me at nficano[at]gmail.com.
AWS Lambda is a service that allows you to write Python, Java, Node.js, C# or Go code that gets executed in response to events like http requests or files uploaded to S3.
Working with Lambda is relatively easy, but the process of bundling and deploying your code is not as simple as it could be.
The Python-Lambda library takes away the guess work of developing your Python-Lambda services by providing you a toolset to streamline the annoying parts.
- Python 2.7 & 3.6 (At the time of writing this, AWS Lambda only supports Python 2.7/3.6).
- Pip (~8.1.1)
- Virtualenv (~15.0.0)
- Virtualenvwrapper (~4.7.1)
First, you must create an IAM Role on your AWS account called lambda_basic_execution with the LambdaBasicExecution policy attached.
On your computer, create a new virtualenv and project folder.
$ mkvirtualenv pylambda
(pylambda) $ mkdir pylambda
Next, download Python-Lambda using pip via pypi.
(pylambda) $ pip install python-lambda
From your pylambda
directory, run the following to bootstrap your project.
(pylambda) $ lambda init
This will create the following files: event.json
, __init__.py
, service.py
, and config.yaml
.
Let's begin by opening config.yaml
in the text editor of your choice. For the purpose of this tutorial, the only required information is aws_access_key_id
and aws_secret_access_key
. You can find these by logging into the AWS management console.
Next let's open service.py
, in here you'll find the following function:
def handler(event, context):
# Your code goes here!
e = event.get('e')
pi = event.get('pi')
return e + pi
This is the handler function; this is the function AWS Lambda will invoke in response to an event. You will notice that in the sample code e
and pi
are values in a dict
. AWS Lambda uses the event
parameter to pass in event data to the handler.
So if, for example, your function is responding to an http request, event
will be the POST
JSON data and if your function returns something, the contents will be in your http response payload.
Next let's open the event.json
file:
{
"pi": 3.14,
"e": 2.718
}
Here you'll find the values of e
and pi
that are being referenced in the sample code.
If you now try and run:
(pylambda) $ lambda invoke -v
You will get:
# 5.858
# execution time: 0.00000310s
# function execution timeout: 15s
As you probably put together, the lambda invoke
command grabs the values stored in the event.json
file and passes them to your function.
The event.json
file should help you develop your Lambda service locally. You can specify an alternate event.json
file by passing the --event-file=<filename>.json
argument to lambda invoke
.
When you're ready to deploy your code to Lambda simply run:
(pylambda) $ lambda deploy
The deploy script will evaluate your virtualenv and identify your project dependencies. It will package these up along with your handler function to a zip file that it then uploads to AWS Lambda.
You can now log into the AWS Lambda management console to verify the code deployed successfully.
If you're looking to develop a simple microservice you can easily wire your function up to an http endpoint.
Begin by navigating to your AWS Lambda management console and clicking on your function. Click the API Endpoints tab and click "Add API endpoint".
Under API endpoint type select "API Gateway".
Next change Method to POST
and Security to "Open" and click submit (NOTE: you should secure this for use in production, open security is used for demo purposes).
At last you need to change the return value of the function to comply with the standard defined for the API Gateway endpoint, the function should now look like this:
def handler(event, context):
# Your code goes here!
e = event.get('e')
pi = event.get('pi')
return {
"statusCode": 200,
"headers": { "Content-Type": "application/json"},
"body": e + pi
}
Now try and run:
$ curl --header "Content-Type:application/json" \
--request POST \
--data '{"pi": 3.14, "e": 2.718}' \
https://<API endpoint URL>
# 5.8580000000000005
Lambda functions support environment variables. In order to set environment variables for your deployed code to use, you can configure them in config.yaml
. To load the
value for the environment variable at the time of deployment (instead of hard coding them in your configuration file), you can use local environment values (see 'env3' in example code below).
environment_variables:
env1: foo
env2: baz
env3: ${LOCAL_ENVIRONMENT_VARIABLE_NAME}
This would create environment variables in the lambda instance upon deploy. If your functions don't need environment variables, simply leave this section out of your config.
You may find that you do not need the toolkit to fully deploy your Lambda or that your code bundle is too large to upload via the API. You can use the upload
command to send the bundle to an S3 bucket of your choosing.
Before doing this, you will need to set the following variables in config.yaml
:
role: basic_s3_upload
bucket_name: 'example-bucket'
s3_key_prefix: 'path/to/file/'
Your role must have s3:PutObject
permission on the bucket/key that you specify for the upload to work properly. Once you have that set, you can execute lambda upload
to initiate the transfer.
You can also choose to use S3 as your source for Lambda deployments. This can be done by issuing lambda deploy_s3
with the same variables/AWS permissions you'd set for executing the upload
command.
Development of "python-lambda" is facilitated exclusively on GitHub. Contributions in the form of patches, tests and feature creation and/or requests are very welcome and highly encouraged. Please open an issue if this tool does not function as you'd expect.
If this is the first time you're releasing to pypi, you'll need to run: pip install -r tests/dev_requirements.txt
.
Once complete, execute the following commands:
git checkout master
# Increment the version number and tag the release.
bumpversion [major|minor|patch]
# Upload the distribution to PyPi
python setup.py sdist bdist_wheel upload
# Since master often contains work-in-progress changes, increment the version
# to a patch release to prevent inaccurate attribution.
bumpversion --no-tag patch
git push origin master --tags