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

DynamoDB already supports encryption at rest by default (with AWS owned keys or AWS managed/customer managed KMS keys). However, the requirement here is stronger and explicit: patient data must be encrypted before it is stored in DynamoDB, meaning the encryption must occur client-side / application-side so that the data remains encrypted as it traverses the stack and is still encrypted when written to the table. This is often required for highly sensitive PII/PHI where administrators or downstream systems should not see plaintext.

Option A meets this requirement by encrypting the payload inside the Lambda function before making the PutItem call to DynamoDB, using KMS-backed envelope encryption via the AWS Encryption SDK (the option names it “Database Encryption SDK,” but the intent is client-side encryption). The encrypted fields remain ciphertext in transit to DynamoDB and at rest inside DynamoDB, satisfying both “in transit” and “at rest” with encryption happening prior to storage.

Option B only ensures DynamoDB encryption at rest at the service level, but the data would still be plaintext in the item attributes as seen by the application and anyone with DynamoDB read permissions (even though stored encrypted on disk). It does not guarantee “encrypted before stored.”

Option C encrypting after the write via streams is too late: plaintext would already be stored (and potentially accessed) before post-processing.

Option D adds unnecessary workflow complexity. Encrypting in a queue still requires encryption before DynamoDB, but it does not inherently simplify compared to encrypting directly in the Lambda that writes to DynamoDB.

Therefore, client-side encryption in Lambda using KMS-backed encryption is the correct solution.

To meet the requirement that developers cannot view credit card numbers while the fraud detection account can , the solution must (1) ensure the sensitive data is masked at ingestion/storage in CloudWatch Logs, and (2) allow only an authorized principal to view unmasked values .

First, the developers must attach the data protection policy to the CloudWatch log group that receives the API Gateway HTTP API access logs (and/or the Lambda log group if credit card numbers can appear there). A CloudWatch Logs data protection policy is applied at the log group level and instructs CloudWatch Logs to identify sensitive data using managed data identifiers (for example, CreditCardNumber ) and then apply the configured de-identification action (here, masking). Without attaching the policy to the log group, the masking/redaction behavior will not be enforced for newly ingested log events, and developers could still see raw request parameters.

Second, to permit only the fraud detection account to reveal the masked values when necessary, the IAM role that the fraud detection account assumes must have the specific CloudWatch Logs permission to unmask protected data. Granting logs:Unmask to that role enables authorized access to view the sensitive values while keeping them masked for everyone else who lacks that permission (such as developer accounts assuming other roles).

Options A and E are not required for CloudWatch Logs data protection enforcement; the core controls are log-group policy attachment (to perform masking) and IAM authorization (to permit unmasking only for the fraud role). Therefore, the correct combination is C (apply the policy to the log group that captures the HTTP API logs) and B (grant logs:Unmask to the fraud detection role).

For client-side encryption with AWS KMS, the documented pattern is envelope encryption : you use KMS to generate and protect a data encryption key (DEK) , and you use that DEK locally to encrypt the actual data. This is the correct approach for large payloads (such as 10 MB documents), because the KMS Encrypt API is intended for encrypting small amounts of data (KMS is not designed to directly encrypt multi-megabyte application payloads).

With envelope encryption, the application calls GenerateDataKey on AWS KMS, specifying the KMS key (customer managed key) to use. KMS returns two versions of the DEK in the response:

a plaintext DEK (usable immediately by the application for local cryptographic operations), and

a ciphertext (encrypted) DEK that is encrypted under the specified KMS key.

The application then uses the plaintext DEK to encrypt the 10 MB document on the client side (for example, using an authenticated encryption mode such as AES-GCM via a standard crypto library). After encryption completes, the application must not persist the plaintext DEK; instead, it stores the encrypted document alongside the ciphertext DEK . Later, to decrypt, the application sends the ciphertext DEK to KMS using Decrypt to recover the plaintext DEK, and then decrypts the document locally.

Therefore, option D is correct because it explicitly uses GenerateDataKey and the plaintext DEK to encrypt the data, which is the required envelope-encryption flow. Options A, B, and C do not follow the correct KMS envelope-encryption process for large client-side payloads.