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

Amazon CloudFront field-level encryption is specifically designed to protect sensitive fields in HTTP requests. It allows CloudFront to encrypt specific request fields at the edge using asymmetric encryption , ensuring that only authorized application components that possess the private key can decrypt the data.

This approach ensures that sensitive fields remain encrypted throughout transit and processing, while non-sensitive fields can still be accessed normally. This satisfies the requirement that only specific parts of the application can decrypt the data.

Field-level encryption is a native CloudFront capability and is far more secure and scalable than implementing custom encryption logic in Lambda@Edge or Lambda functions. AWS documentation emphasizes using built-in CloudFront security features to minimize operational overhead and reduce the risk of cryptographic implementation errors.

Options A and B introduce unnecessary complexity and custom cryptographic handling, which AWS generally discourages when managed services are available. Option D only secures transport and access control and does not encrypt individual data fields.

Therefore, CloudFront field-level encryption with asymmetric keys is the AWS-recommended and correct solution.

Requirement Summary:

Lambda function accesses RDS for MySQL

Credentials are currently hardcoded in code (insecure)

Must enable automated credential rotation every 30 days

Option A: Use AWS Secrets Manager + automatic rotation

Best and secure option

Secrets Manager allows:

Secure storage of secrets

Integration with RDS for automatic rotation

Scheduled rotation every X days (e.g., 30 days)

Lambda can fetch credentials via SDK (GetSecretValue)

Option B: Use SSM Parameter Store + rotation

SSM does not support automatic rotation of secrets.

You ' d need to build custom rotation logic = higher operational overhead.

Option C: Encrypted S3 + Object Lambda rotation

Not intended for credential storage.

S3 is not a secrets management system, and Object Lambda does not perform rotation.

Option D: SSM + EventBridge rotation

No native integration between Parameter Store and EventBridge for secret rotation.

You’d need to build custom Lambda functions = higher maintenance.

Secrets Manager rotation for RDS:

Secure retrieval in Lambda:

Integration with RDS MySQL:

This is a cross-account access pattern using STS AssumeRole. Account A owns the DynamoDB table and has created an IAM role (AccessPII) with permissions to access the table. Account A also configured a trust policy that allows principals from Account B to assume the role. That trust policy alone is not enough; the caller in Account B must also be allowed to call sts:AssumeRole.

Therefore, in Account B, the EC2 instance profile role (the role attached to the EC2 instances running the app) must have permission to assume the role in Account A. That is Option A.

Next, the application must actually obtain temporary credentials for the Account A role. The standard way is to call STS AssumeRole in the application logic (or use an SDK credential provider that assumes a role). This yields temporary credentials that have the permissions of the AccessPII role, allowing DynamoDB access in Account A. That is Option D.

Option B is not correct because granting direct DynamoDB table permissions in Account B does not grant access to a table owned by Account A unless Account A also grants access via a resource policy (DynamoDB resource policies exist but the scenario already sets up role assumption; the intended solution is AssumeRole).

Option C is incomplete/wrong: getting temporary credentials from the EC2 role alone gives permissions of the EC2 role in Account B, not the permissions in Account A. You must assume the cross-account role.

Option E is for IAM user MFA session tokens, not cross-account role assumption for an EC2 role.

Therefore, grant sts:AssumeRole to the EC2 role and call AssumeRole in code.