Kube Metrics Adapter is a general purpose metrics adapter for Kubernetes that can collect and serve custom and external metrics for Horizontal Pod Autoscaling.
It supports scaling based on Prometheus metrics, SQS queues and others out of the box.
It discovers Horizontal Pod Autoscaling resources and starts to collect the requested metrics and stores them in memory. It's implemented using the custom-metrics-apiserver library.
Here's an example of a HorizontalPodAutoscaler
resource configured to get
requests-per-second
metrics from each pod of the deployment myapp
.
apiVersion: autoscaling/v2beta2
kind: HorizontalPodAutoscaler
metadata:
name: myapp-hpa
annotations:
# metric-config.<metricType>.<metricName>.<collectorName>/<configKey>
metric-config.pods.requests-per-second.json-path/json-key: "$.http_server.rps"
metric-config.pods.requests-per-second.json-path/path: /metrics
metric-config.pods.requests-per-second.json-path/port: "9090"
spec:
scaleTargetRef:
apiVersion: apps/v1
kind: Deployment
name: myapp
minReplicas: 1
maxReplicas: 10
metrics:
- type: Pods
pods:
metric:
name: requests-per-second
target:
averageValue: 1k
type: AverageValue
The metric-config.*
annotations are used by the kube-metrics-adapter
to
configure a collector for getting the metrics. In the above example it
configures a json-path pod collector.
Like the support policy offered for Kubernetes, this project aims to support the latest three minor releases of Kubernetes.
The default supported API is autoscaling/v2beta2
(available since v1.12
).
This API MUST be available in the cluster which is the default. However for
GKE, this requires GKE v1.15.7 according to this GKE
Issue.
This project uses Go modules as introduced in Go 1.11 therefore you need Go >=1.11 installed in order to build. If using Go 1.11 you also need to activate Module support.
Assuming Go has been setup with module support it can be built simply by running:
export GO111MODULE=on # needed if the project is checked out in your $GOPATH.
$ make
Collectors are different implementations for getting metrics requested by an
HPA resource. They are configured based on HPA resources and started on-demand by the
kube-metrics-adapter
to only collect the metrics required for scaling the application.
The collectors are configured either simply based on the metrics defined in an HPA resource, or via additional annotations on the HPA resource.
The pod collector allows collecting metrics from each pod matched by the HPA.
Currently only json-path
collection is supported.
Metric | Description | Type | K8s Versions |
---|---|---|---|
custom | No predefined metrics. Metrics are generated from user defined queries. | Pods | >=1.12 |
This is an example of using the pod collector to collect metrics from a json metrics endpoint of each pod matched by the HPA.
apiVersion: autoscaling/v2beta2
kind: HorizontalPodAutoscaler
metadata:
name: myapp-hpa
annotations:
# metric-config.<metricType>.<metricName>.<collectorName>/<configKey>
metric-config.pods.requests-per-second.json-path/json-key: "$.http_server.rps"
metric-config.pods.requests-per-second.json-path/path: /metrics
metric-config.pods.requests-per-second.json-path/port: "9090"
metric-config.pods.requests-per-second.json-path/scheme: "https"
metric-config.pods.requests-per-second.json-path/aggregator: "max"
spec:
scaleTargetRef:
apiVersion: apps/v1
kind: Deployment
name: myapp
minReplicas: 1
maxReplicas: 10
metrics:
- type: Pods
pods:
metric:
name: requests-per-second
target:
averageValue: 1k
type: AverageValue
The pod collector is configured through the annotations which specify the
collector name json-path
and a set of configuration options for the
collector. json-key
defines the json-path query for extracting the right
metric. This assumes the pod is exposing metrics in JSON format. For the above
example the following JSON data would be expected:
{
"http_server": {
"rps": 0.5
}
}
The json-path query support depends on the
github.com/oliveagle/jsonpath library.
See the README for possible queries. It's expected that the metric you query
returns something that can be turned into a float64
.
The other configuration options path
, port
and scheme
specify where the metrics
endpoint is exposed on the pod. The path
and port
options do not have default values
so they must be defined. The scheme
is optional and defaults to http
.
The aggregator
configuration option specifies the aggregation function used to aggregate
values of JSONPath expressions that evaluate to arrays/slices of numbers.
It's optional but when the expression evaluates to an array/slice, it's absence will
produce an error. The supported aggregation functions are avg
, max
, min
and sum
.
The Prometheus collector is a generic collector which can map Prometheus queries to metrics that can be used for scaling. This approach is different from how it's done in the k8s-prometheus-adapter where all available Prometheus metrics are collected and transformed into metrics which the HPA can scale on, and there is no possibility to do custom queries. With the approach implemented here, users can define custom queries and only metrics returned from those queries will be available, reducing the total number of metrics stored.
One downside of this approach is that bad performing queries can slow down/kill Prometheus, so it can be dangerous to allow in a multi tenant cluster. It's also not possible to restrict the available metrics using something like RBAC since any user would be able to create the metrics based on a custom query.
I still believe custom queries are more useful, but it's good to be aware of the trade-offs between the two approaches.
Metric | Description | Type | Kind | K8s Versions |
---|---|---|---|---|
prometheus-query |
Generic metric which requires a user defined query. | External | >=1.12 |
|
custom | No predefined metrics. Metrics are generated from user defined queries. | Object | any | >=1.12 |
This is an example of an HPA configured to get metrics based on a Prometheus
query. The query is defined in the annotation
metric-config.external.prometheus-query.prometheus/processed-events-per-second
where processed-events-per-second
is the query name which will be associated
with the result of the query. A matching query-name
label must be defined in
the matchLabels
of the metric definition. This allows having multiple
prometheus queries associated with a single HPA.
apiVersion: autoscaling/v2beta2
kind: HorizontalPodAutoscaler
metadata:
name: myapp-hpa
annotations:
# This annotation is optional.
# If specified, then this prometheus server is used,
# instead of the prometheus server specified as the CLI argument `--prometheus-server`.
metric-config.external.prometheus-query.prometheus/prometheus-server: http://prometheus.my-namespace.svc
# metric-config.<metricType>.<metricName>.<collectorName>/<configKey>
# <configKey> == query-name
metric-config.external.prometheus-query.prometheus/processed-events-per-second: |
scalar(sum(rate(event-service_events_count{application="event-service",processed="true"}[1m])))
spec:
scaleTargetRef:
apiVersion: apps/v1
kind: Deployment
name: custom-metrics-consumer
minReplicas: 1
maxReplicas: 10
metrics:
- type: External
external:
metric:
name: prometheus-query
selector:
matchLabels:
query-name: processed-events-per-second
target:
type: AverageValue
averageValue: "10"
Note: Prometheus Object metrics are deprecated and will most likely be removed in the future. Use the Prometheus External metrics instead as described above.
This is an example of an HPA configured to get metrics based on a Prometheus
query. The query is defined in the annotation
metric-config.object.processed-events-per-second.prometheus/query
where
processed-events-per-second
is the metric name which will be associated with
the result of the query.
It also specifies an annotation
metric-config.object.processed-events-per-second.prometheus/per-replica
which
instructs the collector to treat the results as an average over all pods
targeted by the HPA. This makes it possible to mimic the behavior of
targetAverageValue
which is not implemented for metric type Object
as of
Kubernetes v1.10. (It will most likely come in v1.12).
apiVersion: autoscaling/v2beta1
kind: HorizontalPodAutoscaler
metadata:
name: myapp-hpa
annotations:
# metric-config.<metricType>.<metricName>.<collectorName>/<configKey>
metric-config.object.processed-events-per-second.prometheus/query: |
scalar(sum(rate(event-service_events_count{application="event-service",processed="true"}[1m])))
metric-config.object.processed-events-per-second.prometheus/per-replica: "true"
spec:
scaleTargetRef:
apiVersion: apps/v1
kind: Deployment
name: custom-metrics-consumer
minReplicas: 1
maxReplicas: 10
metrics:
- type: Object
object:
metricName: processed-events-per-second
target:
apiVersion: v1
kind: Pod
name: dummy-pod
targetValue: 10 # this will be treated as targetAverageValue
Note: The HPA object requires an Object
to be specified. However when a Prometheus metric is used there is no need
for this object. But to satisfy the schema we specify a dummy pod called dummy-pod
.
The skipper collector is a simple wrapper around the Prometheus collector to make it easy to define an HPA for scaling based on ingress metrics when skipper is used as the ingress implementation in your cluster. It assumes you are collecting Prometheus metrics from skipper and it provides the correct Prometheus queries out of the box so users don't have to define those manually.
Metric | Description | Type | Kind | K8s Versions |
---|---|---|---|---|
requests-per-second |
Scale based on requests per second for a certain ingress. | Object | Ingress |
>=1.14 |
This is an example of an HPA that will scale based on requests-per-second
for
an ingress called myapp
.
apiVersion: autoscaling/v2beta2
kind: HorizontalPodAutoscaler
metadata:
name: myapp-hpa
spec:
scaleTargetRef:
apiVersion: apps/v1
kind: Deployment
name: myapp
minReplicas: 1
maxReplicas: 10
metrics:
- type: Object
object:
describedObject:
apiVersion: extensions/v1beta1
kind: Ingress
name: myapp
metric:
name: requests-per-second
target:
averageValue: "10"
type: AverageValue
Skipper supports sending traffic to different backend based on annotations
present on the Ingress
object. When the metric name is specified without a
backend as requests-per-second
then the number of replicas will be calculated
based on the full traffic served by that ingress. If however only the traffic
being routed to a specific backend should be used then the backend name can be
specified as a metric name like requests-per-second,backend1
which would
return the requests-per-second being sent to the backend1
. The ingress
annotation where the backend weights can be obtained can be specified through
the flag --skipper-backends-annotation
.
The InfluxDB collector maps Flux queries to metrics that can be used for scaling.
Note that the collector targets an InfluxDB v2 instance, that's why we only support Flux instead of InfluxQL.
Metric | Description | Type | Kind | K8s Versions |
---|---|---|---|---|
flux-query |
Generic metric which requires a user defined query. | External | >=1.10 |
This is an example of an HPA configured to get metrics based on a Flux query.
The query is defined in the annotation
metric-config.external.flux-query.influxdb/queue_depth
where queue_depth
is the query name which will be associated with the result of the query.
A matching query-name
label must be defined in the matchLabels
of the metric definition.
This allows having multiple flux queries associated with a single HPA.
apiVersion: autoscaling/v2beta2
kind: HorizontalPodAutoscaler
metadata:
name: myapp-hpa
annotations:
# These annotations are optional.
# If specified, then they are used for setting up the InfluxDB client properly,
# instead of using the ones specified via CLI. Respectively:
# - --influxdb-address
# - --influxdb-token
# - --influxdb-org
metric-config.external.flux-query.influxdb/address: "http://influxdbv2.my-namespace.svc"
metric-config.external.flux-query.influxdb/token: "secret-token"
# This could be either the organization name or the ID.
metric-config.external.flux-query.influxdb/org: "deadbeef"
# metric-config.<metricType>.<metricName>.<collectorName>/<configKey>
# <configKey> == query-name
metric-config.external.flux-query.influxdb/queue_depth: |
from(bucket: "apps")
|> range(start: -30s)
|> filter(fn: (r) => r._measurement == "queue_depth")
|> group()
|> max()
// Rename "_value" to "metricvalue" for letting the metrics server properly unmarshal the result.
|> rename(columns: {_value: "metricvalue"})
|> keep(columns: ["metricvalue"])
spec:
scaleTargetRef:
apiVersion: apps/v1
kind: Deployment
name: queryd-v1
minReplicas: 1
maxReplicas: 4
metrics:
- type: External
external:
metric:
name: flux-query
selector:
matchLabels:
query-name: queue_depth
target:
type: Value
value: "1"
The AWS collector allows scaling based on external metrics exposed by AWS services e.g. SQS queue lengths.
To integrate with AWS, the controller needs to run on nodes with access to AWS API. Additionally the controller have to have a role with the following policy to get all required data from AWS:
PolicyDocument:
Statement:
- Action: 'sqs:GetQueueUrl'
Effect: Allow
Resource: '*'
- Action: 'sqs:GetQueueAttributes'
Effect: Allow
Resource: '*'
- Action: 'sqs:ListQueues'
Effect: Allow
Resource: '*'
- Action: 'sqs:ListQueueTags'
Effect: Allow
Resource: '*'
Version: 2012-10-17
Metric | Description | Type | K8s Versions |
---|---|---|---|
sqs-queue-length |
Scale based on SQS queue length | External | >=1.12 |
This is an example of an HPA that will scale based on the length of an SQS queue.
apiVersion: autoscaling/v2beta2
kind: HorizontalPodAutoscaler
metadata:
name: myapp-hpa
spec:
scaleTargetRef:
apiVersion: apps/v1
kind: Deployment
name: custom-metrics-consumer
minReplicas: 1
maxReplicas: 10
metrics:
- type: External
external:
metric:
name: sqs-queue-length
selector:
matchLabels:
queue-name: foobar
region: eu-central-1
target:
averageValue: "30"
type: AverageValue
The matchLabels
are used by kube-metrics-adapter
to configure a collector
that will get the queue length for an SQS queue named foobar
in region
eu-central-1
.
The AWS account of the queue currently depends on how kube-metrics-adapter
is
configured to get AWS credentials. The normal assumption is that you run the
adapter in a cluster running in the AWS account where the queue is defined.
Please open an issue if you would like support for other use cases.
The ZMON collector allows scaling based on external metrics exposed by ZMON checks.
Metric | Description | Type | K8s Versions |
---|---|---|---|
zmon-check |
Scale based on any ZMON check results | External | >=1.12 |
This is an example of an HPA that will scale based on the specified value
exposed by a ZMON check with id 1234
.
apiVersion: autoscaling/v2beta2
kind: HorizontalPodAutoscaler
metadata:
name: myapp-hpa
annotations:
# metric-config.<metricType>.<metricName>.<collectorName>/<configKey>
metric-config.external.zmon-check.zmon/key: "custom.*"
metric-config.external.zmon-check.zmon/tag-application: "my-custom-app-*"
spec:
scaleTargetRef:
apiVersion: apps/v1
kind: Deployment
name: custom-metrics-consumer
minReplicas: 1
maxReplicas: 10
metrics:
- type: External
external:
metric:
name: zmon-check
selector:
matchLabels:
check-id: "1234" # the ZMON check to query for metrics
key: "custom.value"
tag-application: my-custom-app
aggregators: avg # comma separated list of aggregation functions, default: last
duration: 5m # default: 10m
target:
averageValue: "30"
type: AverageValue
The check-id
specifies the ZMON check to query for the metrics. key
specifies the JSON key in the check output to extract the metric value from.
E.g. if you have a check which returns the following data:
{
"custom": {
"value": 1.0
},
"other": {
"value": 3.0
}
}
Then the value 1.0
would be returned when the key is defined as custom.value
.
The tag-<name>
labels defines the tags used for the kariosDB query. In a
normal ZMON setup the following tags will be available:
application
alias
(name of Kubernetes cluster)entity
- full ZMON entity ID.
aggregators
defines the aggregation functions applied to the metrics query.
For instance if you define the entity filter
type=kube_pod,application=my-custom-app
you might get three entities back and
then you might want to get an average over the metrics for those three
entities. This would be possible by using the avg
aggregator. The default
aggregator is last
which returns only the latest metric point from the
query. The supported aggregation functions are avg
, dev
, count
,
first
, last
, max
, min
, sum
, diff
. See the KariosDB docs for
details.
The duration
defines the duration used for the timeseries query. E.g. if you
specify a duration of 5m
then the query will return metric points for the
last 5 minutes and apply the specified aggregation with the same duration .e.g
max(5m)
.
The annotations metric-config.external.zmon-check.zmon/key
and
metric-config.external.zmon-check.zmon/tag-<name>
can be optionally used if
you need to define a key
or other tag
with a "star" query syntax like
values.*
. This hack is in place because it's not allowed to use *
in the
metric label definitions. If both annotations and corresponding label is
defined, then the annotation takes precedence.