Event-driven architectures are an architecture style that can help you boost agility and build reliable, scalable applications. Splitting an application into loosely coupled services can help each service scale independently. A distributed, loosely coupled application depends on events to communicate application change states. Each service consumes events from other services and emits events to notify other services of state changes.
Handling errors becomes even more important when designing distributed applications. A service may fail if it cannot handle an invalid payload, dependent resources may be unavailable, or the service may time out. There may be permission errors which can cause failures. AWS services provide many features to handle error conditions which you can use to improve the resiliency of your applications.
This repository explores three use-cases and design patterns for handling failures
The cdk.json file tells the CDK Toolkit how to execute your app.
This project is set up like a standard Python project. The initialization
process also creates a virtualenv within this project, stored under the .venv
directory. To create the virtualenv it assumes that there is a python3
(or python for Windows) executable in your path with access to the venv
package. If for any reason the automatic creation of the virtualenv fails,
you can create the virtualenv manually.
To manually create a virtualenv on MacOS and Linux:
$ python3 -m venv .venv
After the init process completes and the virtualenv is created, you can use the following step to activate your virtualenv.
$ source .venv/bin/activate
If you are a Windows platform, you would activate the virtualenv like this:
% .venv\Scripts\activate.bat
Once the virtualenv is activated, you can install the required dependencies.
$ pip install -r requirements.txt
At this point you can now synthesize the CloudFormation template for this code.
$ cdk synth
To add additional dependencies, for example other CDK libraries, just add
them to your setup.py file and rerun the pip install -r requirements.txt
command.
When using Lambda with SQS, if Lambda isn’t able to process the message and the message retention period expires, SQS drops the message. Failure to process the message can be due to function processing failures, including time-outs or invalid payloads. Processing failures can also occur when the destination function does not exist, or has incorrect permissions.
You can configure a separate dead-letter queue (DLQ) on the source queue for SQS to retain the dropped message. A DLQ preserves the original message and is useful for analyzing root causes, handling error conditions properly, or sending notifications that require manual interventions. In the poll-based invocation scenario, the Lambda function itself does not maintain a DLQ. It relies on the external DLQ configured in SQS. For more information, see Using Lambda with Amazon SQS.
The following shows the design pattern when you configure Lambda to poll events from a SQS queue and invoke a Lambda function.
Enjoy!