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

The correct answer is C because for an in-place deployment on Amazon EC2 instances, AWS CodeDeploy automatic rollback works by redeploying the last known good revision when a deployment fails or when a configured monitoring alarm is triggered. AWS documentation explains that when automatic rollback is enabled, CodeDeploy creates a new deployment that uses the most recent successfully deployed application revision. This rollback deployment receives its own new deployment ID , because it is treated as a separate deployment event rather than a simple undo operation.

Option A is incorrect because CodeDeploy does not restore an Amazon S3 snapshot of the previous deployment state for EC2 in-place deployments. It redeploys the last successful revision instead. Option B describes behavior associated with blue/green deployment patterns , not in-place deployments . Route 53 alias switching and blue/green environment replacement are not how CodeDeploy handles failed validation during an EC2 in-place deployment. Option D is incorrect because CodePipeline orchestrates stages in a delivery pipeline, but it is not the service that performs the rollback behavior described here.

This distinction is important in AWS deployment design. In-place deployments update the same EC2 instances already serving the application. If validation fails, CodeDeploy does not roll traffic back through DNS or infrastructure replacement. Instead, it launches a rollback deployment of the previously successful application revision across those same instances. That behavior directly aligns with AWS CodeDeploy automatic rollback functionality for EC2/On-Premises in-place deployments.

Therefore, the correct result is that CodeDeploy redeploys the last known stable version as a new deployment , which makes C the right answer.

The goal is minimal downtime during deployment and fast rollback if problems occur. In Elastic Beanstalk, the approach that best satisfies both is a blue/green deployment.

With blue/green, the developer deploys the new application version to a separate environment (green) while the current production environment (blue) continues serving traffic. Once validation is complete (health checks, smoke tests), the developer performs a controlled CNAME swap (or routing switch) so traffic shifts from blue to green with near-zero downtime. This reduces risk because the existing environment remains intact and can immediately resume traffic if issues are detected.

Rollback time is also minimized because reverting is simply switching traffic back to the original environment (swap back), rather than rolling back changes across the same environment.

Why the other options are weaker:

All-at-once (C) introduces the highest downtime and risk because it replaces all instances at once, potentially taking the application fully offline and making rollback slower.

Rolling (A) reduces downtime compared to all-at-once, but instances are still updated in-place; if issues appear mid-deployment, rollback is more complex and slower than swapping environments.

Rolling with additional batches (B) can further reduce capacity impact by adding extra instances during deployment, but rollback still involves reversing updates in the same environment and is typically slower than blue/green.

Therefore, deploying to a new environment and using blue/green provides the least downtime and the fastest rollback.

Comprehensive and Detailed 250 to 300 words of Explanation From AWS Developer Documents:

The key requirement in this scenario is that the data must be encrypted before it is uploaded to Amazon S3 , and the data is generated outside of AWS . This explicitly points to a client-side encryption requirement.

AWS documentation distinguishes clearly between server-side encryption and client-side encryption . Server-side encryption options for Amazon S3—including enabling default bucket encryption or specifying the x-amz-server-side-encryption request header—encrypt the data after it is received by Amazon S3. Therefore, options B and D do not satisfy the requirement because the plaintext data is transmitted to AWS before encryption occurs.

Option A, using the AWS KMS encrypt command, is not suitable for large binary objects. AWS KMS is designed to encrypt small pieces of data (up to 4 KB). AWS documentation explicitly states that for large payloads, customers should use envelope encryption instead of directly encrypting data with AWS KMS.

The AWS Encryption SDK is specifically designed for client-side encryption of large data objects. It implements envelope encryption , where a data encryption key (DEK) is generated locally to encrypt the data, and the DEK is then encrypted with an AWS KMS key. This approach allows efficient encryption of large binary files while maintaining strong key management and security controls.

AWS documentation recommends the AWS Encryption SDK for applications that need to encrypt data before sending it to AWS services , including Amazon S3. It supports multiple programming languages, handles key management automatically, and ensures data confidentiality even before transmission.

Therefore, using the AWS Encryption SDK for client-side encryption is the only solution that fully satisfies all requirements.