prometheus/docs/querying/basics.md

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Querying basics Basics 1

Querying Prometheus

Prometheus provides a functional query language called PromQL (Prometheus Query Language) that lets the user select and aggregate time series data in real time.

When you send a query request to Prometheus, it can be an instant query, evaluated at one point in time, or a range query at equally-spaced steps between a start and an end time. PromQL works exactly the same in each cases; the range query is just like an instant query run multiple times at different timestamps.

In the Prometheus UI, the "Table" tab is for instant queries and the "Graph" tab is for range queries.

Other programs can fetch the result of a PromQL expression via the HTTP API.

Examples

This document is a Prometheus basic language reference. For learning, it may be easier to start with a couple of examples.

Expression language data types

In Prometheus's expression language, an expression or sub-expression can evaluate to one of four types:

  • Instant vector - a set of time series containing a single sample for each time series, all sharing the same timestamp
  • Range vector - a set of time series containing a range of data points over time for each time series
  • Scalar - a simple numeric floating point value
  • String - a simple string value; currently unused

Depending on the use-case (e.g. when graphing vs. displaying the output of an expression), only some of these types are legal as the result of a user-specified expression. For example, an expression that returns an instant vector is the only type which can be graphed.

Notes about the experimental native histograms:

  • Ingesting native histograms has to be enabled via a feature flag.
  • Once native histograms have been ingested into the TSDB (and even after disabling the feature flag again), both instant vectors and range vectors may now contain samples that aren't simple floating point numbers (float samples) but complete histograms (histogram samples). A vector may contain a mix of float samples and histogram samples.

Literals

String literals

String literals are designated by single quotes, double quotes or backticks.

PromQL follows the same escaping rules as Go. For string literals in single or double quotes, a backslash begins an escape sequence, which may be followed by a, b, f, n, r, t, v or \. Specific characters can be provided using octal (\nnn) or hexadecimal (\xnn, \unnnn and \Unnnnnnnn) notations.

Conversely, escape characters are not parsed in string literals designated by backticks. It is important to note that, unlike Go, Prometheus does not discard newlines inside backticks.

Example:

"this is a string"
'these are unescaped: \n \\ \t'
`these are not unescaped: \n ' " \t`

Float literals

Scalar float values can be written as literal integer or floating-point numbers in the format (whitespace only included for better readability):

[-+]?(
      [0-9]*\.?[0-9]+([eE][-+]?[0-9]+)?
    | 0[xX][0-9a-fA-F]+
    | [nN][aA][nN]
    | [iI][nN][fF]
)

Examples:

23
-2.43
3.4e-9
0x8f
-Inf
NaN

As of version 2.54, float literals can also be represented using the syntax of time durations, where the time duration is converted into a float value corresponding to the number of seconds the time duration represents. This is an experimental feature and might still change.

Examples:

1s # Equivalent to 1.0
2m # Equivalent to 120.0
1ms # Equivalent to 0.001

Time series selectors

These are the basic building-blocks that instruct PromQL what data to fetch.

Instant vector selectors

Instant vector selectors allow the selection of a set of time series and a single sample value for each at a given timestamp (point in time). In the simplest form, only a metric name is specified, which results in an instant vector containing elements for all time series that have this metric name.

This example selects all time series that have the http_requests_total metric name:

http_requests_total

It is possible to filter these time series further by appending a comma-separated list of label matchers in curly braces ({}).

This example selects only those time series with the http_requests_total metric name that also have the job label set to prometheus and their group label set to canary:

http_requests_total{job="prometheus",group="canary"}

It is also possible to negatively match a label value, or to match label values against regular expressions. The following label matching operators exist:

  • =: Select labels that are exactly equal to the provided string.
  • !=: Select labels that are not equal to the provided string.
  • =~: Select labels that regex-match the provided string.
  • !~: Select labels that do not regex-match the provided string.

Regex matches are fully anchored. A match of env=~"foo" is treated as env=~"^foo$".

For example, this selects all http_requests_total time series for staging, testing, and development environments and HTTP methods other than GET.

http_requests_total{environment=~"staging|testing|development",method!="GET"}

Label matchers that match empty label values also select all time series that do not have the specific label set at all. It is possible to have multiple matchers for the same label name.

For example, given the dataset:

http_requests_total
http_requests_total{replica="rep-a"}
http_requests_total{replica="rep-b"}
http_requests_total{environment="development"}

The query http_requests_total{environment=""} would match and return:

http_requests_total
http_requests_total{replica="rep-a"}
http_requests_total{replica="rep-b"}

and would exclude:

http_requests_total{environment="development"}

Multiple matchers can be used for the same label name; they all must pass for a result to be returned.

The query:

http_requests_total{replica!="rep-a",replica=~"rep.*"}

Would then match:

http_requests_total{replica="rep-b"}

Vector selectors must either specify a name or at least one label matcher that does not match the empty string. The following expression is illegal:

{job=~".*"} # Bad!

In contrast, these expressions are valid as they both have a selector that does not match empty label values.

{job=~".+"}              # Good!
{job=~".*",method="get"} # Good!

Label matchers can also be applied to metric names by matching against the internal __name__ label. For example, the expression http_requests_total is equivalent to {__name__="http_requests_total"}. Matchers other than = (!=, =~, !~) may also be used. The following expression selects all metrics that have a name starting with job::

{__name__=~"job:.*"}

The metric name must not be one of the keywords bool, on, ignoring, group_left and group_right. The following expression is illegal:

on{} # Bad!

A workaround for this restriction is to use the __name__ label:

{__name__="on"} # Good!

All regular expressions in Prometheus use RE2 syntax.

Range Vector Selectors

Range vector literals work like instant vector literals, except that they select a range of samples back from the current instant. Syntactically, a time duration is appended in square brackets ([]) at the end of a vector selector to specify how far back in time values should be fetched for each resulting range vector element. The range is a left-open and right-closed interval, i.e. samples with timestamps coinciding with the left boundary of the range are excluded from the selection, while samples coinciding with the right boundary of the range are included in the selection.

In this example, we select all the values recorded less than 5m ago for all time series that have the metric name http_requests_total and a job label set to prometheus:

http_requests_total{job="prometheus"}[5m]

Time Durations

Time durations are specified as a number, followed immediately by one of the following units:

  • ms - milliseconds
  • s - seconds
  • m - minutes
  • h - hours
  • d - days - assuming a day always has 24h
  • w - weeks - assuming a week always has 7d
  • y - years - assuming a year always has 365d1

1 For days in a year, the leap day is ignored, and conversely, for a minute, a leap second is ignored.

Time durations can be combined by concatenation. Units must be ordered from the longest to the shortest. A given unit must only appear once in a time duration.

Here are some examples of valid time durations:

5h
1h30m
5m
10s

As of version 2.54, time durations can also be represented using the syntax of float literals, implying the number of seconds of the time duration. This is an experimental feature and might still change.

Examples:

1.0 # Equivalent to 1s
0.001 # Equivalent to 1ms
120 # Equivalent to 2m

Offset modifier

The offset modifier allows changing the time offset for individual instant and range vectors in a query.

For example, the following expression returns the value of http_requests_total 5 minutes in the past relative to the current query evaluation time:

http_requests_total offset 5m

Note that the offset modifier always needs to follow the selector immediately, i.e. the following would be correct:

sum(http_requests_total{method="GET"} offset 5m) // GOOD.

While the following would be incorrect:

sum(http_requests_total{method="GET"}) offset 5m // INVALID.

The same works for range vectors. This returns the 5-minute rate that http_requests_total had a week ago:

rate(http_requests_total[5m] offset 1w)

When querying for samples in the past, a negative offset will enable temporal comparisons forward in time:

rate(http_requests_total[5m] offset -1w)

Note that this allows a query to look ahead of its evaluation time.

@ modifier

The @ modifier allows changing the evaluation time for individual instant and range vectors in a query. The time supplied to the @ modifier is a unix timestamp and described with a float literal.

For example, the following expression returns the value of http_requests_total at 2021-01-04T07:40:00+00:00:

http_requests_total @ 1609746000

Note that the @ modifier always needs to follow the selector immediately, i.e. the following would be correct:

sum(http_requests_total{method="GET"} @ 1609746000) // GOOD.

While the following would be incorrect:

sum(http_requests_total{method="GET"}) @ 1609746000 // INVALID.

The same works for range vectors. This returns the 5-minute rate that http_requests_total had at 2021-01-04T07:40:00+00:00:

rate(http_requests_total[5m] @ 1609746000)

The @ modifier supports all representations of numeric literals described above. It works with the offset modifier where the offset is applied relative to the @ modifier time. The results are the same irrespective of the order of the modifiers.

For example, these two queries will produce the same result:

# offset after @
http_requests_total @ 1609746000 offset 5m
# offset before @
http_requests_total offset 5m @ 1609746000

Additionally, start() and end() can also be used as values for the @ modifier as special values.

For a range query, they resolve to the start and end of the range query respectively and remain the same for all steps.

For an instant query, start() and end() both resolve to the evaluation time.

http_requests_total @ start()
rate(http_requests_total[5m] @ end())

Note that the @ modifier allows a query to look ahead of its evaluation time.

Subquery

Subquery allows you to run an instant query for a given range and resolution. The result of a subquery is a range vector.

Syntax: <instant_query> '[' <range> ':' [<resolution>] ']' [ @ <float_literal> ] [ offset <duration> ]

  • <resolution> is optional. Default is the global evaluation interval.

Operators

Prometheus supports many binary and aggregation operators. These are described in detail in the expression language operators page.

Functions

Prometheus supports several functions to operate on data. These are described in detail in the expression language functions page.

Comments

PromQL supports line comments that start with #. Example:

    # This is a comment

Gotchas

Staleness

The timestamps at which to sample data, during a query, are selected independently of the actual present time series data. This is mainly to support cases like aggregation (sum, avg, and so on), where multiple aggregated time series do not precisely align in time. Because of their independence, Prometheus needs to assign a value at those timestamps for each relevant time series. It does so by taking the newest sample that is less than the lookback period ago. The lookback period is 5 minutes by default.

If a target scrape or rule evaluation no longer returns a sample for a time series that was previously present, this time series will be marked as stale. If a target is removed, the previously retrieved time series will be marked as stale soon after removal.

If a query is evaluated at a sampling timestamp after a time series is marked as stale, then no value is returned for that time series. If new samples are subsequently ingested for that time series, they will be returned as expected.

A time series will go stale when it is no longer exported, or the target no longer exists. Such time series will disappear from graphs at the times of their latest collected sample, and they will not be returned in queries after they are marked stale.

Some exporters, which put their own timestamps on samples, get a different behaviour: series that stop being exported take the last value for (by default) 5 minutes before disappearing. The track_timestamps_staleness setting can change this.

Avoiding slow queries and overloads

If a query needs to operate on a substantial amount of data, graphing it might time out or overload the server or browser. Thus, when constructing queries over unknown data, always start building the query in the tabular view of Prometheus's expression browser until the result set seems reasonable (hundreds, not thousands, of time series at most). Only when you have filtered or aggregated your data sufficiently, switch to graph mode. If the expression still takes too long to graph ad-hoc, pre-record it via a recording rule.

This is especially relevant for Prometheus's query language, where a bare metric name selector like api_http_requests_total could expand to thousands of time series with different labels. Also, keep in mind that expressions that aggregate over many time series will generate load on the server even if the output is only a small number of time series. This is similar to how it would be slow to sum all values of a column in a relational database, even if the output value is only a single number.