Amazon Web Services DVA-C02 Exam With Confidence Using Practice Dumps

The requirements call for (1) standardized templates to define serverless infrastructure, (2) the ability to test locally before deployment, and (3) integrating deployment and infrastructure changes into an existing AWS CodePipeline workflow. AWS Serverless Application Model (AWS SAM) is designed specifically for serverless applications and extends CloudFormation with serverless-specific resources (such as AWS::Serverless::Function, APIs, event sources). SAM also provides the SAM CLI , which includes local testing capabilities (for example, sam local invoke and sam local start-api) that emulate Lambda and API Gateway behavior for rapid iteration before deployment.

Option A fits all requirements: create an AWS SAM template as the infrastructure definition and add pipeline stages that execute the necessary SAM CLI commands (commonly sam build and sam deploy, and optionally test commands) as part of the CI/CD process. This makes deployments repeatable and automated, ensures infrastructure changes are deployed in lockstep with application changes, and keeps everything governed by the existing CodePipeline.

Option D uses SAM but relies on a standalone script outside the pipeline, which conflicts with the requirement to incorporate infrastructure changes into the existing pipeline. Option C (plain CloudFormation) can define infrastructure, but it does not inherently provide the same streamlined local testing workflow that SAM CLI provides for serverless event sources and APIs. Option B is unrelated: Step Functions is an orchestration service and its definition language is not a general infrastructure templating and local-testing solution for serverless deployments.

Therefore, A is the correct strategy: use AWS SAM templates and integrate SAM CLI build/deploy steps into CodePipeline to automate deployments and support local testing while managing infrastructure as code.

The correct answer is C because reserved concurrency guarantees that a specific AWS Lambda function has access to a defined number of concurrent executions. In this scenario, the function normally runs correctly but occasionally receives a surge of up to 500 S3 object-created events per minute . Since each invocation runs for about 30 seconds , the function may need substantial concurrency during those bursts. Configuring reserved concurrency ensures that this function has dedicated execution capacity available during peak periods and is not affected by concurrency consumption from other functions in the account.

AWS documentation explains that reserved concurrency both sets the maximum concurrency for a function and reserves that capacity exclusively for the function. This is especially helpful when one function must continue operating reliably under burst traffic. Even though other functions are currently running as expected, reserved concurrency is the direct AWS mechanism to protect the processing function from account-level concurrency contention during spikes.

Option A is incorrect because the function already completes in about 30 seconds; changing timeout does not solve high-volume invocation scaling. Option B is not the best answer because adding a Lambda layer does not guarantee improved throughput or concurrency handling. Option D is incorrect because decreasing memory usually reduces available CPU and can make performance worse, which would increase the chance of delays or failures.

Therefore, the most effective approach is to configure reserved concurrency for the processing function so it can continue to run reliably during high-volume object upload periods.