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

Requirement Summary:

Lambda function:

Retrieves an item from DynamoDB

Updates its attributes or creates it if it does not exist

Has primary key

Needs minimum required IAM permissions

Analysis of Required Permissions:

To get an item and update it or create it if it doesn ' t exist, the Lambda function must use the **PutItem** or **UpdateItem** API, and read with **GetItem**.

Valid API options:

GetItem: Read the item from the table.

UpdateItem: Update existing item attributes or insert if it doesn ' t exist (with UpdateExpression and ConditionExpression).

When UpdateItem is used without a conditional check for existence, it can create a new item if it does not exist (acts like upsert).

DescribeTable: (Optional) Used if you need table metadata (not strictly required here).

Evaluate the Choices:

Option A:

DeleteItem – Not needed

GetItem –

PutItem – (can create/replace but not partial update)

Close, but PutItem overwrites the full item, not update-in-place. Acceptable, but UpdateItem is better suited.

Option B:

UpdateItem – Required to modify attributes or insert new item

GetItem – Required to check existence or read data

DescribeTable – Optional, but not harmful

BEST FIT – Matches the update-or-create logic.

Option C:

GetRecords – This is used for DynamoDB Streams, not standard GetItem

PutItem –

UpdateTable – Used to change table settings, not data manipulation

Incorrect usage context

Option D:

UpdateItem, GetItem, PutItem – all valid

But UpdateItem alone is sufficient; including PutItem might not be necessary Also, image is faded (possibly invalid), and it ' s redundant

UpdateItem API:

PutItem vs UpdateItem:

IAM actions for DynamoDB:

For this workload, the access pattern is centered on each user’s activity history over time (the company is planning a marketing campaign based on each user’s activity). In DynamoDB, the most effective way to store and query time-ordered events per entity is to use a composite primary key where the entity identifier is the partition key and a time attribute is the sort key . Therefore, using user ID as the partition key groups all events for a given user together, and using timestamp as the sort key allows efficient retrieval in chronological order and supports range queries (for example, “activities in the last 7 days” or “between two dates”).

This design also helps maximize provisioned throughput efficiency and reduce throttling risk because it distributes data across partitions based on the partition key values (user IDs). With many users, writes and reads naturally spread across multiple partition key values rather than concentrating on a small set. The sort key further enables multiple activity records per user without overwriting items and supports precise queries without scanning.

Option B (product ID as partition key) does not align with the stated marketing need (per-user activity). It would cluster all users’ actions for a popular product into the same partition key, increasing the chance of hot partitions and throttling. Option C also risks hot partitions for popular product IDs; auto scaling helps capacity management but does not fix poor key distribution or hot-key access patterns. Option D (monotonic counter as partition key) is particularly problematic: sequential keys can create uneven distribution and a throughput bottleneck pattern, and it does not support user-centric queries efficiently.

Thus, A best matches the data model (user events over time), supports efficient queries, and reduces throttling risk by distributing workload across user IDs.