Struct aws_sdk_dynamodb::types::builders::GlobalSecondaryIndexDescriptionBuilder

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#[non_exhaustive]
pub struct GlobalSecondaryIndexDescriptionBuilder { /* private fields */ }
Expand description

A builder for GlobalSecondaryIndexDescription.

Implementations§

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impl GlobalSecondaryIndexDescriptionBuilder

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pub fn index_name(self, input: impl Into<String>) -> Self

The name of the global secondary index.

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pub fn set_index_name(self, input: Option<String>) -> Self

The name of the global secondary index.

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pub fn get_index_name(&self) -> &Option<String>

The name of the global secondary index.

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pub fn key_schema(self, input: KeySchemaElement) -> Self

Appends an item to key_schema.

To override the contents of this collection use set_key_schema.

The complete key schema for a global secondary index, which consists of one or more pairs of attribute names and key types:

  • HASH - partition key

  • RANGE - sort key

The partition key of an item is also known as its hash attribute. The term "hash attribute" derives from DynamoDB's usage of an internal hash function to evenly distribute data items across partitions, based on their partition key values.

The sort key of an item is also known as its range attribute. The term "range attribute" derives from the way DynamoDB stores items with the same partition key physically close together, in sorted order by the sort key value.

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pub fn set_key_schema(self, input: Option<Vec<KeySchemaElement>>) -> Self

The complete key schema for a global secondary index, which consists of one or more pairs of attribute names and key types:

  • HASH - partition key

  • RANGE - sort key

The partition key of an item is also known as its hash attribute. The term "hash attribute" derives from DynamoDB's usage of an internal hash function to evenly distribute data items across partitions, based on their partition key values.

The sort key of an item is also known as its range attribute. The term "range attribute" derives from the way DynamoDB stores items with the same partition key physically close together, in sorted order by the sort key value.

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pub fn get_key_schema(&self) -> &Option<Vec<KeySchemaElement>>

The complete key schema for a global secondary index, which consists of one or more pairs of attribute names and key types:

  • HASH - partition key

  • RANGE - sort key

The partition key of an item is also known as its hash attribute. The term "hash attribute" derives from DynamoDB's usage of an internal hash function to evenly distribute data items across partitions, based on their partition key values.

The sort key of an item is also known as its range attribute. The term "range attribute" derives from the way DynamoDB stores items with the same partition key physically close together, in sorted order by the sort key value.

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pub fn projection(self, input: Projection) -> Self

Represents attributes that are copied (projected) from the table into the global secondary index. These are in addition to the primary key attributes and index key attributes, which are automatically projected.

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pub fn set_projection(self, input: Option<Projection>) -> Self

Represents attributes that are copied (projected) from the table into the global secondary index. These are in addition to the primary key attributes and index key attributes, which are automatically projected.

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pub fn get_projection(&self) -> &Option<Projection>

Represents attributes that are copied (projected) from the table into the global secondary index. These are in addition to the primary key attributes and index key attributes, which are automatically projected.

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pub fn index_status(self, input: IndexStatus) -> Self

The current state of the global secondary index:

  • CREATING - The index is being created.

  • UPDATING - The index is being updated.

  • DELETING - The index is being deleted.

  • ACTIVE - The index is ready for use.

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pub fn set_index_status(self, input: Option<IndexStatus>) -> Self

The current state of the global secondary index:

  • CREATING - The index is being created.

  • UPDATING - The index is being updated.

  • DELETING - The index is being deleted.

  • ACTIVE - The index is ready for use.

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pub fn get_index_status(&self) -> &Option<IndexStatus>

The current state of the global secondary index:

  • CREATING - The index is being created.

  • UPDATING - The index is being updated.

  • DELETING - The index is being deleted.

  • ACTIVE - The index is ready for use.

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pub fn backfilling(self, input: bool) -> Self

Indicates whether the index is currently backfilling. Backfilling is the process of reading items from the table and determining whether they can be added to the index. (Not all items will qualify: For example, a partition key cannot have any duplicate values.) If an item can be added to the index, DynamoDB will do so. After all items have been processed, the backfilling operation is complete and Backfilling is false.

You can delete an index that is being created during the Backfilling phase when IndexStatus is set to CREATING and Backfilling is true. You can't delete the index that is being created when IndexStatus is set to CREATING and Backfilling is false.

For indexes that were created during a CreateTable operation, the Backfilling attribute does not appear in the DescribeTable output.

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pub fn set_backfilling(self, input: Option<bool>) -> Self

Indicates whether the index is currently backfilling. Backfilling is the process of reading items from the table and determining whether they can be added to the index. (Not all items will qualify: For example, a partition key cannot have any duplicate values.) If an item can be added to the index, DynamoDB will do so. After all items have been processed, the backfilling operation is complete and Backfilling is false.

You can delete an index that is being created during the Backfilling phase when IndexStatus is set to CREATING and Backfilling is true. You can't delete the index that is being created when IndexStatus is set to CREATING and Backfilling is false.

For indexes that were created during a CreateTable operation, the Backfilling attribute does not appear in the DescribeTable output.

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pub fn get_backfilling(&self) -> &Option<bool>

Indicates whether the index is currently backfilling. Backfilling is the process of reading items from the table and determining whether they can be added to the index. (Not all items will qualify: For example, a partition key cannot have any duplicate values.) If an item can be added to the index, DynamoDB will do so. After all items have been processed, the backfilling operation is complete and Backfilling is false.

You can delete an index that is being created during the Backfilling phase when IndexStatus is set to CREATING and Backfilling is true. You can't delete the index that is being created when IndexStatus is set to CREATING and Backfilling is false.

For indexes that were created during a CreateTable operation, the Backfilling attribute does not appear in the DescribeTable output.

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pub fn provisioned_throughput( self, input: ProvisionedThroughputDescription, ) -> Self

Represents the provisioned throughput settings for the specified global secondary index.

For current minimum and maximum provisioned throughput values, see Service, Account, and Table Quotas in the Amazon DynamoDB Developer Guide.

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pub fn set_provisioned_throughput( self, input: Option<ProvisionedThroughputDescription>, ) -> Self

Represents the provisioned throughput settings for the specified global secondary index.

For current minimum and maximum provisioned throughput values, see Service, Account, and Table Quotas in the Amazon DynamoDB Developer Guide.

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pub fn get_provisioned_throughput( &self, ) -> &Option<ProvisionedThroughputDescription>

Represents the provisioned throughput settings for the specified global secondary index.

For current minimum and maximum provisioned throughput values, see Service, Account, and Table Quotas in the Amazon DynamoDB Developer Guide.

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pub fn index_size_bytes(self, input: i64) -> Self

The total size of the specified index, in bytes. DynamoDB updates this value approximately every six hours. Recent changes might not be reflected in this value.

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pub fn set_index_size_bytes(self, input: Option<i64>) -> Self

The total size of the specified index, in bytes. DynamoDB updates this value approximately every six hours. Recent changes might not be reflected in this value.

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pub fn get_index_size_bytes(&self) -> &Option<i64>

The total size of the specified index, in bytes. DynamoDB updates this value approximately every six hours. Recent changes might not be reflected in this value.

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pub fn item_count(self, input: i64) -> Self

The number of items in the specified index. DynamoDB updates this value approximately every six hours. Recent changes might not be reflected in this value.

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pub fn set_item_count(self, input: Option<i64>) -> Self

The number of items in the specified index. DynamoDB updates this value approximately every six hours. Recent changes might not be reflected in this value.

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pub fn get_item_count(&self) -> &Option<i64>

The number of items in the specified index. DynamoDB updates this value approximately every six hours. Recent changes might not be reflected in this value.

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pub fn index_arn(self, input: impl Into<String>) -> Self

The Amazon Resource Name (ARN) that uniquely identifies the index.

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pub fn set_index_arn(self, input: Option<String>) -> Self

The Amazon Resource Name (ARN) that uniquely identifies the index.

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pub fn get_index_arn(&self) -> &Option<String>

The Amazon Resource Name (ARN) that uniquely identifies the index.

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pub fn on_demand_throughput(self, input: OnDemandThroughput) -> Self

The maximum number of read and write units for the specified global secondary index. If you use this parameter, you must specify MaxReadRequestUnits, MaxWriteRequestUnits, or both.

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pub fn set_on_demand_throughput(self, input: Option<OnDemandThroughput>) -> Self

The maximum number of read and write units for the specified global secondary index. If you use this parameter, you must specify MaxReadRequestUnits, MaxWriteRequestUnits, or both.

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pub fn get_on_demand_throughput(&self) -> &Option<OnDemandThroughput>

The maximum number of read and write units for the specified global secondary index. If you use this parameter, you must specify MaxReadRequestUnits, MaxWriteRequestUnits, or both.

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pub fn build(self) -> GlobalSecondaryIndexDescription

Consumes the builder and constructs a GlobalSecondaryIndexDescription.

Trait Implementations§

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impl Clone for GlobalSecondaryIndexDescriptionBuilder

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fn clone(&self) -> GlobalSecondaryIndexDescriptionBuilder

Returns a copy of the value. Read more
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fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source. Read more
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impl Debug for GlobalSecondaryIndexDescriptionBuilder

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fn fmt(&self, f: &mut Formatter<'_>) -> Result

Formats the value using the given formatter. Read more
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impl Default for GlobalSecondaryIndexDescriptionBuilder

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fn default() -> GlobalSecondaryIndexDescriptionBuilder

Returns the “default value” for a type. Read more
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impl PartialEq for GlobalSecondaryIndexDescriptionBuilder

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fn eq(&self, other: &GlobalSecondaryIndexDescriptionBuilder) -> bool

This method tests for self and other values to be equal, and is used by ==.
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fn ne(&self, other: &Rhs) -> bool

This method tests for !=. The default implementation is almost always sufficient, and should not be overridden without very good reason.
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impl StructuralPartialEq for GlobalSecondaryIndexDescriptionBuilder

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