One way to partition is to load data into separate datasources. This is a perfectly viable approach that works very well when the number of datasources does not lead to excessive per-datasource overheads.
This topic describes how to set up partitions within a single datasource. It does not cover how to use multiple datasources. See [Multitenancy considerations](../querying/multitenancy.md) for more details on splitting data into separate datasources and potential operational considerations.
## Time chunk partitioning
Druid always partitions datasources by time into _time chunks_. Each time chunk contains one or more segments. This partitioning happens for all ingestion methods based on the `segmentGranularity` parameter in your ingestion spec `dataSchema` object.
Druid can partition segments within a particular time chunk further depending upon options that vary based on the ingestion type you have chosen. In general, secondary partitioning on a particular dimension improves locality. This means that rows with the same value for that dimension are stored together, decreasing access time.
To achieve the best performance and smallest overall footprint, partition your data on a "natural"
dimension that you often use as a filter when possible. Such partitioning often improves compression and query performance. For example, some cases have yielded threefold storage size decreases.
## Partitioning and sorting
Partitioning and sorting work well together. If you do have a "natural" partitioning dimension, consider placing it first in the `dimensions` list of your `dimensionsSpec`. This way Druid sorts rows within each segment by that column. This sorting configuration frequently improves compression more than using partitioning alone.
Note that Druid always sorts rows within a segment by timestamp first, even before the first dimension listed in your `dimensionsSpec`. This sorting can preclude the efficacy of dimension sorting. To work around this limitation if necessary, set your `queryGranularity` equal to `segmentGranularity` in your [`granularitySpec`](./ingestion-spec.md#granularityspec). Druid will set all timestamps within the segment to the same value, letting you identify a [secondary timestamp](schema-design.md#secondary-timestamps) as the "real" timestamp.
Not all ingestion methods support an explicit partitioning configuration, and not all have equivalent levels of flexibility. If you are doing initial ingestion through a less-flexible method like
Kafka), you can use [reindexing](../data-management/update.md#reindex) or [compaction](../data-management/compaction.md) to repartition your data after initial ingestion. This is a powerful technique you can use to optimally partition any data older than a certain time threshold while you continuously add new data from a stream.
|[SQL](../multi-stage-query/index.md)|Configured using [`PARTITIONED BY`](../multi-stage-query/concepts.md#partitioning) and [`CLUSTERED BY`](../multi-stage-query/concepts.md#clustering).|
|[Kafka indexing service](../development/extensions-core/kafka-ingestion.md)|Kafka topic partitioning defines how Druid partitions the datasource. You can also [reindex](../data-management/update.md#reindex) or [compact](../data-management/compaction.md) to repartition after initial ingestion.|
|[Kinesis indexing service](../development/extensions-core/kinesis-ingestion.md)|Kinesis stream sharding defines how Druid partitions the datasource. You can also [reindex](../data-management/update.md#reindex) or [compact](../data-management/compaction.md) to repartition after initial ingestion.|
* [Reindexing](../data-management/update.md#reindex) and [Compaction](../data-management/compaction.md) for information on how to repartition existing data in Druid.