Alternatively, external storage may be used via the [remote read/write APIs](https://prometheus.io/docs/operating/integrations/#remote-endpoints-and-storage). Careful evaluation is required for these systems as they vary greatly in durability, performance, and efficiency.
*`--storage.tsdb.path`: Where Prometheus writes its database. Defaults to `data/`.
*`--storage.tsdb.retention.time`: When to remove old data. Defaults to `15d`. Overrides `storage.tsdb.retention` if this flag is set to anything other than default.
*`--storage.tsdb.retention.size`: The maximum number of bytes of storage blocks to retain. The oldest data will be removed first. Defaults to `0` or disabled. Units supported: B, KB, MB, GB, TB, PB, EB. Ex: "512MB". Only the persistent blocks are deleted to honor this retention although WAL and m-mapped chunks are counted in the total size. So the minimum requirement for the disk is the peak space taken by the `wal` (the WAL and Checkpoint) and `chunks_head` (m-mapped Head chunks) directory combined (peaks every 2 hours).
*`--storage.tsdb.retention`: Deprecated in favor of `storage.tsdb.retention.time`.
*`--storage.tsdb.wal-compression`: Enables compression of the write-ahead log (WAL). Depending on your data, you can expect the WAL size to be halved with little extra cpu load. This flag was introduced in 2.11.0 and enabled by default in 2.20.0. Note that once enabled, downgrading Prometheus to a version below 2.11.0 will require deleting the WAL.
To lower the rate of ingested samples, you can either reduce the number of time series you scrape (fewer targets or fewer series per target), or you can increase the scrape interval. However, reducing the number of series is likely more effective, due to compression of samples within a series.
CAUTION: Non-POSIX compliant filesystems are not supported for Prometheus' local storage as unrecoverable corruptions may happen. NFS filesystems (including AWS's EFS) are not supported. NFS could be POSIX-compliant, but most implementations are not. It is strongly recommended to use a local filesystem for reliability.
Expired block cleanup happens in the background. It may take up to two hours to remove expired blocks. Blocks must be fully expired before they are removed.
The read and write protocols both use a snappy-compressed protocol buffer encoding over HTTP. The protocols are not considered as stable APIs yet and may change to use gRPC over HTTP/2 in the future, when all hops between Prometheus and the remote storage can safely be assumed to support HTTP/2.
For details on configuring remote storage integrations in Prometheus, see the [remote write](configuration/configuration.md#remote_write) and [remote read](configuration/configuration.md#remote_read) sections of the Prometheus configuration documentation.
The built-in remote write receiver can be enabled by setting the `--web.enable-remote-write-receiver` command line flag. When enabled, the remote write receiver endpoint is `/api/v1/write`.
For details on the request and response messages, see the [remote storage protocol buffer definitions](https://github.com/prometheus/prometheus/blob/main/prompb/remote.proto).
Note that on the read path, Prometheus only fetches raw series data for a set of label selectors and time ranges from the remote end. All PromQL evaluation on the raw data still happens in Prometheus itself. This means that remote read queries have some scalability limit, since all necessary data needs to be loaded into the querying Prometheus server first and then processed there. However, supporting fully distributed evaluation of PromQL was deemed infeasible for the time being.
### Existing integrations
To learn more about existing integrations with remote storage systems, see the [Integrations documentation](https://prometheus.io/docs/operating/integrations/#remote-endpoints-and-storage).
If a user wants to create blocks into the TSDB from data that is in [OpenMetrics](https://openmetrics.io/) format, they can do so using backfilling. However, they should be careful and note that it is not safe to backfill data from the last 3 hours (the current head block) as this time range may overlap with the current head block Prometheus is still mutating. Backfilling will create new TSDB blocks, each containing two hours of metrics data. This limits the memory requirements of block creation. Compacting the two hour blocks into larger blocks is later done by the Prometheus server itself.
A typical use case is to migrate metrics data from a different monitoring system or time-series database to Prometheus. To do so, the user must first convert the source data into [OpenMetrics](https://openmetrics.io/) format, which is the input format for the backfilling as described below.
Backfilling can be used via the Promtool command line. Promtool will write the blocks to a directory. By default this output directory is ./data/, you can change it by using the name of the desired output directory as an optional argument in the sub-command.
After the creation of the blocks, move it to the data directory of Prometheus. If there is an overlap with the existing blocks in Prometheus, the flag `--storage.tsdb.allow-overlapping-blocks` needs to be set. Note that any backfilled data is subject to the retention configured for your Prometheus server (by time or size).
By default, the promtool will use the default block duration (2h) for the blocks; this behavior is the most generally applicable and correct. However, when backfilling data over a long range of times, it may be advantageous to use a larger value for the block duration to backfill faster and prevent additional compactions by TSDB later.
The `--max-block-duration` flag allows the user to configure a maximum duration of blocks. The backfilling tool will pick a suitable block duration no larger than this.
While larger blocks may improve the performance of backfilling large datasets, drawbacks exist as well. Time-based retention policies must keep the entire block around if even one sample of the (potentially large) block is still within the retention policy. Conversely, size-based retention policies will remove the entire block even if the TSDB only goes over the size limit in a minor way.
Therefore, backfilling with few blocks, thereby choosing a larger block duration, must be done with care and is not recommended for any production instances.
When a new recording rule is created, there is no historical data for it. Recording rule data only exists from the creation time on. `promtool` makes it possible to create historical recording rule data.
### Usage
To see all options, use: `$ promtool tsdb create-blocks-from rules --help`.
The recording rule files provided should be a normal [Prometheus rules file](https://prometheus.io/docs/prometheus/latest/configuration/recording_rules/).
The output of `promtool tsdb create-blocks-from rules` command is a directory that contains blocks with the historical rule data for all rules in the recording rule files. By default the output directory is `data/`. In order to make use of this new block data, the blocks must be moved to a running Prometheus instance data dir `storage.tsdb.path` that has the flag `--storage.tsdb.allow-overlapping-blocks` enabled. Once moved, the new blocks will merge with existing blocks when the next compaction runs.
### Limitations
- If you run the rule backfiller multiple times with the overlapping start/end times, blocks containing the same data will be created each time the rule backfiller is run.
- All rules in the recording rule files will be evaluated.
- If the `interval` is set in the recording rule file that will take priority over the `eval-interval` flag in the rule backfill command.
- Alerts are currently ignored if they are in the recording rule file.
- Rules in the same group cannot see the results of previous rules. Meaning that rules that refer to other rules being backfilled is not supported. A workaround is to backfill multiple times and create the dependent data first (and move dependent data to the Prometheus server data dir so that it is accessible from the Prometheus API).
