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

Requirement Summary:

Customer credit card data may be exposed

Data is stored in Amazon S3

Developer must identify all exposure risks

Tool to Use:

Amazon Macie is designed to:

Automatically scan S3 for sensitive data

Detect financial information, PII, credentials, etc.

Finding Type Mapping:

Credit card data maps to: SensitiveData:S3Object/Financial

Evaluate Options:

A. Athena + filtering

Athena is a query engine; it doesn’t detect sensitive data automatically

B. Macie + Financial finding type

Correct

Designed for this use case

C. Macie + Personal finding type

Personal maps to names, addresses, etc., not credit cards

D. Athena + Financial

Again, Athena can’t classify data – it only queries structured data

Macie Overview:

Finding Types:

Financial finding type: SensitiveData:S3Object/Financial

To begin using AWS X-Ray, the team must (1) instrument the application to emit trace segments/subsegments and (2) ensure there is a component that can send trace data to the X-Ray service.

Instrumenting code is typically done with the AWS X-Ray SDK (language-specific). This adds tracing to inbound requests and downstream calls, creates segments/subsegments, and attaches annotations/metadata. That corresponds to Option C.

For many compute environments (especially EC2, ECS on EC2, and on-prem servers), the application sends trace data via the X-Ray daemon/agent running locally. The daemon batches segments and forwards them to the X-Ray service endpoint. That corresponds to Option D.

Option B is helpful after traces exist (using the X-Ray console or CloudWatch ServiceLens), but it is not a prerequisite to “begin using” X-Ray.

Option A is unrelated. X-Ray does not require SQS for instrumentation output.

Option E is incorrect because X-Ray stores trace data in its managed backend; you do not create a DynamoDB table for trace logs.

Therefore, the team needs to instrument the code with the X-Ray SDK and install/run the X-Ray agent/daemon on the servers where the application runs.

The workload is a classic “hot key / hot dataset” pattern: many reads repeatedly target a small subset of items. The best way to improve performance and reduce latency is to add a caching layer so the application does not hit DynamoDB for every read.

Option B is purpose-built for DynamoDB read acceleration: DynamoDB Accelerator (DAX) is an in-memory cache that sits in front of DynamoDB and is API-compatible for many DynamoDB operations. DAX can dramatically reduce read latency (often to microseconds) for frequently accessed items and offload read traffic from the table.

Option A can also help: ElastiCache (Redis/Memcached) can be used as an application-managed cache. This is useful when the application wants more control over caching strategy, TTLs, and non-DynamoDB data caching. For ECS applications, ElastiCache is a common high-performance caching choice.

Why not the others:

C (strongly consistent reads) typically increases latency and capacity consumption; it does not improve performance for repeated reads.

D (increase read capacity) can reduce throttling, but it does not reduce latency as effectively as caching and can be more expensive for hot-read patterns.

E (adaptive capacity) helps DynamoDB handle uneven workloads, but it is not a direct performance boost like caching for repeated reads of a small dataset.

Therefore, adding caching via ElastiCache and/or DAX best improves performance. With “select two,” A and B are correct.