3.8 KiB
title | nav_title | sort_rank |
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Querying examples | Examples | 4 |
Query examples
Simple time series selection
Return all time series with the metric http_requests_total
:
http_requests_total
Return all time series with the metric http_requests_total
and the given
job
and handler
labels:
http_requests_total{job="apiserver", handler="/api/comments"}
Return a whole range of time (in this case 5 minutes up to the query time) for the same vector, making it a range vector:
http_requests_total{job="apiserver", handler="/api/comments"}[5m]
Note that an expression resulting in a range vector cannot be graphed directly, but viewed in the tabular ("Console") view of the expression browser.
Using regular expressions, you could select time series only for jobs whose
name match a certain pattern, in this case, all jobs that end with server
:
http_requests_total{job=~".*server"}
To select all HTTP status codes except 4xx ones, you could run:
http_requests_total{status!~"4.."}
Subquery
Return the 5-minute rate of the http_requests_total
metric for the past 30 minutes, with a resolution of 1 minute.
rate(http_requests_total[5m])[30m:1m]
This is an example of a nested subquery. The subquery for the deriv
function uses the default resolution. Note that using subqueries unnecessarily is unwise.
max_over_time(deriv(rate(distance_covered_total[5s])[30s:5s])[10m:])
Using functions, operators, etc.
Return the per-second rate for all time series with the http_requests_total
metric name, as measured over the last 5 minutes:
rate(http_requests_total[5m])
Assuming that the http_requests_total
time series all have the labels job
(fanout by job name) and instance
(fanout by instance of the job), we might
want to sum over the rate of all instances, so we get fewer output time series,
but still preserve the job
dimension:
sum by (job) (
rate(http_requests_total[5m])
)
If we have two different metrics with the same dimensional labels, we can apply binary operators to them and elements on both sides with the same label set will get matched and propagated to the output. For example, this expression returns the unused memory in MiB for every instance (on a fictional cluster scheduler exposing these metrics about the instances it runs):
(instance_memory_limit_bytes - instance_memory_usage_bytes) / 1024 / 1024
The same expression, but summed by application, could be written like this:
sum by (app, proc) (
instance_memory_limit_bytes - instance_memory_usage_bytes
) / 1024 / 1024
If the same fictional cluster scheduler exposed CPU usage metrics like the following for every instance:
instance_cpu_time_ns{app="lion", proc="web", rev="34d0f99", env="prod", job="cluster-manager"}
instance_cpu_time_ns{app="elephant", proc="worker", rev="34d0f99", env="prod", job="cluster-manager"}
instance_cpu_time_ns{app="turtle", proc="api", rev="4d3a513", env="prod", job="cluster-manager"}
instance_cpu_time_ns{app="fox", proc="widget", rev="4d3a513", env="prod", job="cluster-manager"}
...
...we could get the top 3 CPU users grouped by application (app
) and process
type (proc
) like this:
topk(3, sum by (app, proc) (rate(instance_cpu_time_ns[5m])))
Assuming this metric contains one time series per running instance, you could count the number of running instances per application like this:
count by (app) (instance_cpu_time_ns)
If we are exploring some metrics for their labels, to e.g. be able to aggregate over some of them, we could use the following:
limitk(10, app_foo_metric_bar)
Alternatively, if we wanted the returned timeseries to be more evenly sampled, we could use the following to get approximately 10% of them:
limit_ratio(0.1, app_foo_metric_bar)