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722f33225c
Signed-off-by: Jan Fajerski <jfajersk@redhat.com>
247 lines
13 KiB
Markdown
247 lines
13 KiB
Markdown
---
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title: Feature flags
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sort_rank: 12
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---
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# Feature flags
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Here is a list of features that are disabled by default since they are breaking changes or are considered experimental.
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Their behaviour can change in future releases which will be communicated via the [release changelog](https://github.com/prometheus/prometheus/blob/main/CHANGELOG.md).
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You can enable them using the `--enable-feature` flag with a comma separated list of features.
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They may be enabled by default in future versions.
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## Expand environment variables in external labels
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`--enable-feature=expand-external-labels`
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Replace `${var}` or `$var` in the [`external_labels`](configuration/configuration.md#configuration-file)
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values according to the values of the current environment variables. References
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to undefined variables are replaced by the empty string.
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The `$` character can be escaped by using `$$`.
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## Exemplars storage
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`--enable-feature=exemplar-storage`
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[OpenMetrics](https://github.com/OpenObservability/OpenMetrics/blob/main/specification/OpenMetrics.md#exemplars) introduces the ability for scrape targets to add exemplars to certain metrics. Exemplars are references to data outside of the MetricSet. A common use case are IDs of program traces.
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Exemplar storage is implemented as a fixed size circular buffer that stores exemplars in memory for all series. Enabling this feature will enable the storage of exemplars scraped by Prometheus. The config file block [storage](configuration/configuration.md#configuration-file)/[exemplars](configuration/configuration.md#exemplars) can be used to control the size of circular buffer by # of exemplars. An exemplar with just a `trace_id=<jaeger-trace-id>` uses roughly 100 bytes of memory via the in-memory exemplar storage. If the exemplar storage is enabled, we will also append the exemplars to WAL for local persistence (for WAL duration).
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## Memory snapshot on shutdown
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`--enable-feature=memory-snapshot-on-shutdown`
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This takes the snapshot of the chunks that are in memory along with the series information when shutting down and stores
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it on disk. This will reduce the startup time since the memory state can be restored with this snapshot and m-mapped
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chunks without the need of WAL replay.
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## Extra scrape metrics
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`--enable-feature=extra-scrape-metrics`
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When enabled, for each instance scrape, Prometheus stores a sample in the following additional time series:
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- `scrape_timeout_seconds`. The configured `scrape_timeout` for a target. This allows you to measure each target to find out how close they are to timing out with `scrape_duration_seconds / scrape_timeout_seconds`.
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- `scrape_sample_limit`. The configured `sample_limit` for a target. This allows you to measure each target
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to find out how close they are to reaching the limit with `scrape_samples_post_metric_relabeling / scrape_sample_limit`. Note that `scrape_sample_limit` can be zero if there is no limit configured, which means that the query above can return `+Inf` for targets with no limit (as we divide by zero). If you want to query only for targets that do have a sample limit use this query: `scrape_samples_post_metric_relabeling / (scrape_sample_limit > 0)`.
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- `scrape_body_size_bytes`. The uncompressed size of the most recent scrape response, if successful. Scrapes failing because `body_size_limit` is exceeded report `-1`, other scrape failures report `0`.
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## Per-step stats
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`--enable-feature=promql-per-step-stats`
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When enabled, passing `stats=all` in a query request returns per-step
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statistics. Currently this is limited to totalQueryableSamples.
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When disabled in either the engine or the query, per-step statistics are not
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computed at all.
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## Auto GOMAXPROCS
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`--enable-feature=auto-gomaxprocs`
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When enabled, GOMAXPROCS variable is automatically set to match Linux container CPU quota.
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## Auto GOMEMLIMIT
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`--enable-feature=auto-gomemlimit`
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When enabled, the GOMEMLIMIT variable is automatically set to match the Linux container memory limit. If there is no container limit, or the process is running outside of containers, the system memory total is used.
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There is also an additional tuning flag, `--auto-gomemlimit.ratio`, which allows controlling how much of the memory is used for Prometheus. The remainder is reserved for memory outside the process. For example, kernel page cache. Page cache is important for Prometheus TSDB query performance. The default is `0.9`, which means 90% of the memory limit will be used for Prometheus.
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## No default scrape port
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`--enable-feature=no-default-scrape-port`
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When enabled, the default ports for HTTP (`:80`) or HTTPS (`:443`) will _not_ be added to
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the address used to scrape a target (the value of the `__address_` label), contrary to the default behavior.
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In addition, if a default HTTP or HTTPS port has already been added either in a static configuration or
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by a service discovery mechanism and the respective scheme is specified (`http` or `https`), that port will be removed.
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## Native Histograms
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`--enable-feature=native-histograms`
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When enabled, Prometheus will ingest native histograms (formerly also known as
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sparse histograms or high-res histograms). Native histograms are still highly
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experimental. Expect breaking changes to happen (including those rendering the
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TSDB unreadable).
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Native histograms are currently only supported in the traditional Prometheus
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protobuf exposition format. This feature flag therefore also enables a new (and
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also experimental) protobuf parser, through which _all_ metrics are ingested
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(i.e. not only native histograms). Prometheus will try to negotiate the
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protobuf format first. The instrumented target needs to support the protobuf
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format, too, _and_ it needs to expose native histograms. The protobuf format
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allows to expose classic and native histograms side by side. With this feature
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flag disabled, Prometheus will continue to parse the classic histogram (albeit
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via the text format). With this flag enabled, Prometheus will still ingest
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those classic histograms that do not come with a corresponding native
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histogram. However, if a native histogram is present, Prometheus will ignore
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the corresponding classic histogram, with the notable exception of exemplars,
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which are always ingested. To keep the classic histograms as well, enable
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`scrape_classic_histograms` in the scrape job.
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_Note about the format of `le` and `quantile` label values:_
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In certain situations, the protobuf parsing changes the number formatting of
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the `le` labels of classic histograms and the `quantile` labels of
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summaries. Typically, this happens if the scraped target is instrumented with
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[client_golang](https://github.com/prometheus/client_golang) provided that
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[promhttp.HandlerOpts.EnableOpenMetrics](https://pkg.go.dev/github.com/prometheus/client_golang/prometheus/promhttp#HandlerOpts)
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is set to `false`. In such a case, integer label values are represented in the
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text format as such, e.g. `quantile="1"` or `le="2"`. However, the protobuf parsing
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changes the representation to float-like (following the OpenMetrics
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specification), so the examples above become `quantile="1.0"` and `le="2.0"` after
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ingestion into Prometheus, which changes the identity of the metric compared to
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what was ingested before via the text format.
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The effect of this change is that alerts, recording rules and dashboards that
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directly reference label values as whole numbers such as `le="1"` will stop
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working.
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Aggregation by the `le` and `quantile` labels for vectors that contain the old and
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new formatting will lead to unexpected results, and range vectors that span the
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transition between the different formatting will contain additional series.
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The most common use case for both is the quantile calculation via
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`histogram_quantile`, e.g.
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`histogram_quantile(0.95, sum by (le) (rate(histogram_bucket[10m])))`.
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The `histogram_quantile` function already tries to mitigate the effects to some
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extent, but there will be inaccuracies, in particular for shorter ranges that
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cover only a few samples.
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Ways to deal with this change either globally or on a per metric basis:
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- Fix references to integer `le`, `quantile` label values, but otherwise do
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nothing and accept that some queries that span the transition time will produce
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inaccurate or unexpected results.
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_This is the recommended solution, to get consistently normalized label values._
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Also Prometheus 3.0 is expected to enforce normalization of these label values.
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- Use `metric_relabel_config` to retain the old labels when scraping targets.
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This should **only** be applied to metrics that currently produce such labels.
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<!-- The following config snippet is unit tested in scrape/scrape_test.go. -->
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```yaml
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metric_relabel_configs:
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- source_labels:
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- quantile
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target_label: quantile
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regex: (\d+)\.0+
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- source_labels:
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- le
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- __name__
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target_label: le
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regex: (\d+)\.0+;.*_bucket
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```
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## OTLP Receiver
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`--enable-feature=otlp-write-receiver`
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The OTLP receiver allows Prometheus to accept [OpenTelemetry](https://opentelemetry.io/) metrics writes.
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Prometheus is best used as a Pull based system, and staleness, `up` metric, and other Pull enabled features
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won't work when you push OTLP metrics.
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## Experimental PromQL functions
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`--enable-feature=promql-experimental-functions`
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Enables PromQL functions that are considered experimental. These functions
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might change their name, syntax, or semantics. They might also get removed
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entirely.
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## Created Timestamps Zero Injection
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`--enable-feature=created-timestamp-zero-ingestion`
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Enables ingestion of created timestamp. Created timestamps are injected as 0 valued samples when appropriate. See [PromCon talk](https://youtu.be/nWf0BfQ5EEA) for details.
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Currently Prometheus supports created timestamps only on the traditional Prometheus Protobuf protocol (WIP for other protocols). As a result, when enabling this feature, the Prometheus protobuf scrape protocol will be prioritized (See `scrape_config.scrape_protocols` settings for more details).
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Besides enabling this feature in Prometheus, created timestamps need to be exposed by the application being scraped.
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## Concurrent evaluation of independent rules
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`--enable-feature=concurrent-rule-eval`
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By default, rule groups execute concurrently, but the rules within a group execute sequentially; this is because rules can use the
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output of a preceding rule as its input. However, if there is no detectable relationship between rules then there is no
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reason to run them sequentially.
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When the `concurrent-rule-eval` feature flag is enabled, rules without any dependency on other rules within a rule group will be evaluated concurrently.
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This has the potential to improve rule group evaluation latency and resource utilization at the expense of adding more concurrent query load.
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The number of concurrent rule evaluations can be configured with `--rules.max-concurrent-rule-evals`, which is set to `4` by default.
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## Serve old Prometheus UI
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Fall back to serving the old (Prometheus 2.x) web UI instead of the new UI. The new UI that was released as part of Prometheus 3.0 is a complete rewrite and aims to be cleaner, less cluttered, and more modern under the hood. However, it is not fully feature complete and battle-tested yet, so some users may still prefer using the old UI.
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`--enable-feature=old-ui`
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## Metadata WAL Records
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`--enable-feature=metadata-wal-records`
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When enabled, Prometheus will store metadata in-memory and keep track of
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metadata changes as WAL records on a per-series basis.
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This must be used if
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you are also using remote write 2.0 as it will only gather metadata from the WAL.
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## Delay compaction start time
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`--enable-feature=delayed-compaction`
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A random offset, up to `10%` of the chunk range, is added to the Head compaction start time. This assists Prometheus instances in avoiding simultaneous compactions and reduces the load on shared resources.
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Only auto Head compactions and the operations directly resulting from them are subject to this delay.
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In the event of multiple consecutive Head compactions being possible, only the first compaction experiences this delay.
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Note that during this delay, the Head continues its usual operations, which include serving and appending series.
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Despite the delay in compaction, the blocks produced are time-aligned in the same manner as they would be if the delay was not in place.
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## Delay __name__ label removal for PromQL engine
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`--enable-feature=promql-delayed-name-removal`
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When enabled, Prometheus will change the way in which the `__name__` label is removed from PromQL query results (for functions and expressions for which this is necessary). Specifically, it will delay the removal to the last step of the query evaluation, instead of every time an expression or function creating derived metrics is evaluated.
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This allows optionally preserving the `__name__` label via the `label_replace` and `label_join` functions, and helps prevent the "vector cannot contain metrics with the same labelset" error, which can happen when applying a regex-matcher to the `__name__` label.
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## Auto Reload Config
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`--enable-feature=auto-reload-config`
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When enabled, Prometheus will automatically reload its configuration file at a
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specified interval. The interval is defined by the
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`--config.auto-reload-interval` flag, which defaults to `30s`.
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Configuration reloads are triggered by detecting changes in the checksum of the
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main configuration file or any referenced files, such as rule and scrape
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configurations. To ensure consistency and avoid issues during reloads, it's
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recommended to update these files atomically.
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