# kube-metrics-adapter [![Build Status](https://travis-ci.org/zalando-incubator/kube-metrics-adapter.svg?branch=master)](https://travis-ci.org/zalando-incubator/kube-metrics-adapter) [![Coverage Status](https://coveralls.io/repos/github/zalando-incubator/kube-metrics-adapter/badge.svg?branch=master)](https://coveralls.io/github/zalando-incubator/kube-metrics-adapter?branch=master) 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](https://prometheus.io/), [SQS queues](https://aws.amazon.com/sqs/) 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](https://github.com/kubernetes-sigs/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`. ```yaml apiVersion: autoscaling/v2 kind: HorizontalPodAutoscaler metadata: name: myapp-hpa annotations: # metric-config.../ 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*. ## Kubernetes compatibility Like the [support policy](https://kubernetes.io/docs/setup/release/version-skew-policy/) offered for Kubernetes, this project aims to support the latest three minor releases of Kubernetes. The default supported API is `autoscaling/v2` (available since `v1.23`). This API MUST be available in the cluster which is the default. ## Building This project uses [Go modules](https://github.com/golang/go/wiki/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](https://github.com/golang/go/wiki/Modules#installing-and-activating-module-support). Assuming Go has been setup with module support it can be built simply by running: ```sh export GO111MODULE=on # needed if the project is checked out in your $GOPATH. $ make ``` ## Install in Kubernetes Clone this repository, and run as below: ```sh $ cd kube-metrics-adapter/docs $ kubectl apply -f . ``` ## Collectors 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. ## Pod collector The pod collector allows collecting metrics from each pod matching the label selector defined in the HPA's `scaleTargetRef`. Currently only `json-path` collection is supported. ### Supported HPA `scaleTargetRef` The Pod Collector utilizes the `scaleTargetRef` specified in an HPA resource to obtain the label selector from the referenced Kubernetes object. This enables the identification and management of pods associated with that object. Currently, the supported Kubernetes objects for this operation are: `Deployment`, `StatefulSet` and [`Rollout`](https://argoproj.github.io/argo-rollouts/features/specification/). ### Supported metrics | Metric | Description | Type | K8s Versions | | ------------ | -------------- | ------- | -- | | *custom* | No predefined metrics. Metrics are generated from user defined queries. | Pods | `>=1.12` | ### Example This is an example of using the pod collector to collect metrics from a json metrics endpoint of each pod matched by the HPA. ```yaml apiVersion: autoscaling/v2 kind: HorizontalPodAutoscaler metadata: name: myapp-hpa annotations: # metric-config.../ 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" metric-config.pods.requests-per-second.json-path/interval: "60s" # optional metric-config.pods.requests-per-second.json-path/min-pod-ready-age: "30s" # optional 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: ```json { "http_server": { "rps": 0.5 } } ``` The json-path query support depends on the [github.com/spyzhov/ajson](https://github.com/spyzhov/ajson) 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 `raw-query` configuration option specifies the query params to send along to the endpoint: ```yaml 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/raw-query: "foo=bar&baz=bop" ``` will create a URL like this: ``` http://:9090/metrics?foo=bar&baz=bop ``` There are also configuration options for custom (connect and request) timeouts when querying pods for metrics: ```yaml metric-config.pods.requests-per-second.json-path/request-timeout: 2s metric-config.pods.requests-per-second.json-path/connect-timeout: 500ms ``` The default for both of the above values is 15 seconds. The `min-pod-ready-age` configuration option instructs the service to start collecting metrics from the pods only if they are "older" (time elapsed after pod reached "Ready" state) than the specified amount of time. This is handy when pods need to warm up before HPAs will start tracking their metrics. The default value is 0 seconds. ## Prometheus collector 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](https://github.com/DirectXMan12/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. ### Supported metrics | 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` | ### Example: External Metric 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.processed-events-per-second.prometheus/query` where `processed-events-per-second` is the query name which will be associated with the result of the query. This allows having multiple prometheus queries associated with a single HPA. ```yaml apiVersion: autoscaling/v2 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.processed-events-per-second.prometheus/prometheus-server: http://prometheus.my-namespace.svc # metric-config.../ metric-config.external.processed-events-per-second.prometheus/query: | scalar(sum(rate(event-service_events_count{application="event-service",processed="true"}[1m]))) metric-config.external.processed-events-per-second.prometheus/interval: "60s" # optional spec: scaleTargetRef: apiVersion: apps/v1 kind: Deployment name: custom-metrics-consumer minReplicas: 1 maxReplicas: 10 metrics: - type: External external: metric: name: processed-events-per-second selector: matchLabels: type: prometheus target: type: AverageValue averageValue: "10" ``` ### Example: Object Metric [DEPRECATED] > _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](https://github.com/kubernetes/kubernetes/pull/64097#event-1696222479)). ```yaml apiVersion: autoscaling/v2beta1 kind: HorizontalPodAutoscaler metadata: name: myapp-hpa annotations: # metric-config.../ 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`. ## Skipper collector The skipper collector is a simple wrapper around the Prometheus collector to make it easy to define an HPA for scaling based on [Ingress][ingress] or [RouteGroup][routegroup] metrics when [skipper](https://github.com/zalando/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. [ingress]: https://kubernetes.io/docs/concepts/services-networking/ingress/ [routegroup]: https://opensource.zalando.com/skipper/kubernetes/routegroups/ ### Supported metrics | Metric | Description | Type | Kind | K8s Versions | | ----------- | -------------- | ------ | ---- | ---- | | `requests-per-second` | Scale based on requests per second for a certain ingress or routegroup. | Object | `Ingress`, `RouteGroup` | `>=1.19` | ### Example #### Ingress This is an example of an HPA that will scale based on `requests-per-second` for an ingress called `myapp`. ```yaml apiVersion: autoscaling/v2 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: networking.k8s.io/v1 kind: Ingress name: myapp metric: name: requests-per-second selector: matchLabels: backend: backend1 # optional backend target: averageValue: "10" type: AverageValue ``` #### RouteGroup This is an example of an HPA that will scale based on `requests-per-second` for a routegroup called `myapp`. ```yaml apiVersion: autoscaling/v2 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: zalando.org/v1 kind: RouteGroup name: myapp metric: name: requests-per-second selector: matchLabels: backend: backend1 # optional backend target: averageValue: "10" type: AverageValue ``` ### Metric weighting based on backend Skipper supports sending traffic to different backends based on annotations present on the `Ingress` object, or weights on the RouteGroup backends. By default the number of replicas will be calculated based on the full traffic served by that ingress/routegroup. If however only the traffic being routed to a specific backend should be used then the backend name can be specified via the `backend` label under `matchLabels` for the metric. The ingress annotation where the backend weights can be obtained can be specified through the flag `--skipper-backends-annotation`. ## External RPS collector The External RPS collector, like Skipper collector, is a simple wrapper around the Prometheus collector to make it easy to define an HPA for scaling based on the RPS measured for a given hostname. When [skipper](https://github.com/zalando/skipper) is used as the ingress implementation in your cluster everything should work automatically, in case another reverse proxy is used as ingress, like [Nginx](https://github.com/kubernetes/ingress-nginx) for example, its necessary to configure which prometheus metric should be used through `--external-rps-metric-name ` flag. Assuming `skipper-ingress` is being used or the appropriate metric name is passed using the flag mentioned previously this collector provides the correct Prometheus queries out of the box so users don't have to define those manually. ### Supported metrics | Metric | Description | Type | Kind | K8s Versions | | ------------ | -------------- | ------- | -- | -- | | `requests-per-second` | Scale based on requests per second for a certain hostname. | External | | `>=1.12` | ### Example: External Metric This is an example of an HPA that will scale based on `requests-per-second` for the RPS measured in the hostnames called: `www.example1.com` and `www.example2.com`; and weighted by 42%. ```yaml apiVersion: autoscaling/v2 kind: HorizontalPodAutoscaler metadata: name: myapp-hpa annotations: metric-config.external.example-rps.requests-per-second/hostnames: www.example1.com,www.example2.com metric-config.external.example-rps.requests-per-second/weight: "42" spec: scaleTargetRef: apiVersion: apps/v1 kind: Deployment name: custom-metrics-consumer minReplicas: 1 maxReplicas: 10 metrics: - type: External external: metric: name: example-rps selector: matchLabels: type: requests-per-second target: type: AverageValue averageValue: "42" ``` ### Multiple hostnames per metric This metric supports a relation of n:1 between hostnames and metrics. The way it works is the measured RPS is the sum of the RPS rate of each of the specified hostnames. This value is further modified by the weight parameter explained below. ### Metric weighting based on backend There are ingress-controllers, like skipper-ingress, that supports sending traffic to different backends based on some kind of configuration, in case of skipper annotations present on the `Ingress` object, or weights on the RouteGroup backends. By default the number of replicas will be calculated based on the full traffic served by these components. If however only the traffic being routed to a specific hostname should be used then the weight for the configured hostname(s) might be specified via the `weight` annotation `metric-config.external..request-per-second/weight` for the metric being configured. ## InfluxDB collector The InfluxDB collector maps [Flux](https://github.com/influxdata/flux) queries to metrics that can be used for scaling. Note that the collector targets an [InfluxDB v2](https://v2.docs.influxdata.com/v2.0/get-started/) instance, that's why we only support Flux instead of InfluxQL. ### Supported metrics | Metric | Description | Type | Kind | K8s Versions | | ------------ | -------------- | ------- | -- | -- | | `flux-query` | Generic metric which requires a user defined query. | External | | `>=1.10` | ### Example: External Metric 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..influxdb/query` where `` is the query name which will be associated with the result of the query. This allows having multiple flux queries associated with a single HPA. ```yaml apiVersion: autoscaling/v2 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.queue-depth.influxdb/address: "http://influxdbv2.my-namespace.svc" metric-config.external.queue-depth.influxdb/token: "secret-token" # This could be either the organization name or the ID. metric-config.external.queue-depth.influxdb/org: "deadbeef" # metric-config.../ # == query-name metric-config.external.queue-depth.influxdb/query: | 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"]) metric-config.external.queue-depth.influxdb/interval: "60s" # optional spec: scaleTargetRef: apiVersion: apps/v1 kind: Deployment name: queryd-v1 minReplicas: 1 maxReplicas: 4 metrics: - type: External external: metric: name: queue-depth selector: matchLabels: type: influxdb target: type: Value value: "1" ``` ## AWS collector The AWS collector allows scaling based on external metrics exposed by AWS services e.g. SQS queue lengths. ### AWS IAM role 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: ```yaml 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 ``` ### Supported metrics | Metric | Description | Type | K8s Versions | | ------------ | ------- | -- | -- | | `sqs-queue-length` | Scale based on SQS queue length | External | `>=1.12` | ### Example This is an example of an HPA that will scale based on the length of an SQS queue. ```yaml apiVersion: autoscaling/v2 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: my-sqs selector: matchLabels: type: sqs-queue-length 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. ## ZMON collector The ZMON collector allows scaling based on external metrics exposed by [ZMON](https://github.com/zalando/zmon) checks. ### Supported metrics | Metric | Description | Type | K8s Versions | | ------------ | ------- | -- | -- | | `zmon-check` | Scale based on any ZMON check results | External | `>=1.12` | ### Example This is an example of an HPA that will scale based on the specified value exposed by a ZMON check with id `1234`. ```yaml apiVersion: autoscaling/v2 kind: HorizontalPodAutoscaler metadata: name: myapp-hpa annotations: # metric-config.../ metric-config.external.my-zmon-check.zmon/key: "custom.*" metric-config.external.my-zmon-check.zmon/tag-application: "my-custom-app-*" metric-config.external.my-zmon-check.zmon/interval: "60s" # optional spec: scaleTargetRef: apiVersion: apps/v1 kind: Deployment name: custom-metrics-consumer minReplicas: 1 maxReplicas: 10 metrics: - type: External external: metric: name: my-zmon-check selector: matchLabels: type: zmon 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: ```json { "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-` 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`, `count`, `last`, `max`, `min`, `sum`, `diff`. See the [KariosDB docs](https://kairosdb.github.io/docs/build/html/restapi/Aggregators.html) 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.my-zmon-check.zmon/key` and `metric-config.external.my-zmon-check.zmon/tag-` 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. ## Nakadi collector The Nakadi collector allows scaling based on [Nakadi](https://nakadi.io/) Subscription API stats metrics `consumer_lag_seconds` or `unconsumed_events`. ### Supported metrics | Metric Type | Description | Type | K8s Versions | |------------------------|-----------------------------------------------------------------------------|----------|--------------| | `unconsumed-events` | Scale based on number of unconsumed events for a Nakadi subscription | External | `>=1.24` | | `consumer-lag-seconds` | Scale based on number of max consumer lag seconds for a Nakadi subscription | External | `>=1.24` | ```yaml apiVersion: autoscaling/v2 kind: HorizontalPodAutoscaler metadata: name: myapp-hpa annotations: # metric-config.../ metric-config.external.my-nakadi-consumer.nakadi/interval: "60s" # optional spec: scaleTargetRef: apiVersion: apps/v1 kind: Deployment name: custom-metrics-consumer minReplicas: 0 maxReplicas: 8 # should match number of partitions for the event type metrics: - type: External external: metric: name: my-nakadi-consumer selector: matchLabels: type: nakadi subscription-id: "708095f6-cece-4d02-840e-ee488d710b29" metric-type: "consumer-lag-seconds|unconsumed-events" target: # value is compatible with the consumer-lag-seconds metric type. # It describes the amount of consumer lag in seconds before scaling # additionally up. # if an event-type has multiple partitions the value of # consumer-lag-seconds is the max of all the partitions. value: "600" # 10m type: Value # averageValue is compatible with unconsumed-events metric type. # This means for every 30 unconsumed events a pod is added. # unconsumed-events is the sum of of unconsumed_events over all # partitions. averageValue: "30" type: AverageValue ``` The `subscription-id` is the Subscription ID of the relevant consumer. The `metric-type` indicates whether to scale on `consumer-lag-seconds` or `unconsumed-events` as outlined below. `unconsumed-events` - is the total number of unconsumed events over all partitions. When using this `metric-type` you should also use the target `averageValue` which indicates the number of events which can be handled per pod. To best estimate the number of events per pods, you need to understand the average time for processing an event as well as the rate of events. *Example*: You have an event type producing 100 events per second between 00:00 and 08:00. Between 08:01 to 23:59 it produces 400 events per second. Let's assume that on average a single pod can consume 100 events per second, then we can define 100 as `averageValue` and the HPA would scale to 1 between 00:00 and 08:00, and scale to 4 between 08:01 and 23:59. If there for some reason is a short spike of 800 events per second, then it would scale to 8 pods to process those events until the rate goes down again. `consumer-lag-seconds` - describes the age of the oldest unconsumed event for a subscription. If the event type has multiple partitions the lag is defined as the max age over all partitions. When using this `metric-type` you should use the target `value` to indicate the max lag (in seconds) before the HPA should scale. *Example*: You have a subscription with a defined SLO of "99.99 of events are consumed within 30 min.". In this case you can define a target `value` of e.g. 20 min. (1200s) (to include a safety buffer) such that the HPA only scales up from 1 to 2 if the target of 20 min. is breached and it needs to work faster with more consumers. For this case you should also account for the average time for processing an event when defining the target. ## HTTP Collector The http collector allows collecting metrics from an external endpoint specified in the HPA. Currently only `json-path` collection is supported. ### Supported metrics | Metric | Description | Type | K8s Versions | | ------------ | -------------- | ------- | -- | | *custom* | No predefined metrics. Metrics are generated from user defined queries. | Pods | `>=1.12` | ### Example This is an example of using the HTTP collector to collect metrics from a json metrics endpoint specified in the annotations. ```yaml apiVersion: autoscaling/v2 kind: HorizontalPodAutoscaler metadata: name: myapp-hpa annotations: # metric-config.../ metric-config.external.unique-metric-name.json-path/json-key: "$.some-metric.value" metric-config.external.unique-metric-name.json-path/endpoint: "http://metric-source.app-namespace:8080/metrics" metric-config.external.unique-metric-name.json-path/aggregator: "max" metric-config.external.unique-metric-name.json-path/interval: "60s" # optional spec: scaleTargetRef: apiVersion: apps/v1 kind: Deployment name: myapp minReplicas: 1 maxReplicas: 10 metrics: - type: External external: metric: name: unique-metric-name selector: matchLabels: type: json-path target: averageValue: 1 type: AverageValue ``` The HTTP collector similar to the Pod Metrics collector. The following configuration values are supported: - `json-key` to specify the JSON path of the metric to be queried - `endpoint` the fully formed path to query for the metric. In the above example a Kubernetes _Service_ in the namespace `app-namespace` is called. - `aggregator` is only required if the metric is an array of values and specifies how the values are aggregated. Currently this option can support the values: `sum`, `max`, `min`, `avg`. ### Scrape Interval It's possible to configure the scrape interval for each of the metric types via an annotation: ```yaml metric-config.../interval: "30s" ``` The default is `60s` but can be reduced to let the adapter collect metrics more often. ## ScalingSchedule Collectors The `ScalingSchedule` and `ClusterScalingSchedule` collectors allow collecting time-based metrics from the respective CRD objects specified in the HPA. These collectors are disabled by default, you have to start the server with the `--scaling-schedule` flag to enable it. Remember to deploy the CRDs `ScalingSchedule` and `ClusterScalingSchedule` and allow the service account used by the server to read, watch and list them. ### Supported metrics | Metric | Description | Type | K8s Versions | | ---------- | -------------- | ------- | -- | | ObjectName | The metric is calculated and stored for each `ScalingSchedule` and `ClusterScalingSchedule` referenced in the HPAs | `ScalingSchedule` and `ClusterScalingSchedule` | `>=1.16` | ### Ramp-up and ramp-down feature To avoid abrupt scaling due to time based metrics,the `SchalingSchedule` collector has a feature of ramp-up and ramp-down the metric over a specific period of time. The duration of the scaling window can be configured individually in the `[Cluster]ScalingSchedule` object, via the option `scalingWindowDurationMinutes` or globally for all scheduled events, and defaults to a globally configured value if not specified. The default for the latter is set to 10 minutes, but can be changed using the `--scaling-schedule-default-scaling-window` flag. This spreads the scale events around, creating less load on the other components, and helping the rest of the metrics (like the CPU ones) to adjust as well. The [HPA algorithm][algo-details] does not make changes if the metric change is less than the specified by the `horizontal-pod-autoscaler-tolerance` flag: > We'll skip scaling if the ratio is sufficiently close to 1.0 (within a > globally-configurable tolerance, from the > `--horizontal-pod-autoscaler-tolerance` flag, which defaults to 0.1. With that in mind, the ramp-up and ramp-down feature divides the scaling over the specified period of time in buckets, trying to achieve changes bigger than the configured tolerance. The number of buckets defaults to 10 and can be configured by the `--scaling-schedule-ramp-steps` flag. **Important**: note that the ramp-up and ramp-down feature can lead to deployments achieving less than the specified number of pods, due to the HPA 10% change rule and the ceiling function applied to the desired number of the pods (check the [algorithm details][algo-details]). It varies with the configured metric for `ScalingSchedule` events, the number of pods and the configured `horizontal-pod-autoscaler-tolerance` flag of your kubernetes installation. [This gist][gist] contains the code to simulate the situations a deployment with different number of pods, with a metric of 10000 can face with 10 buckets (max of 90% of the metric returned) and 5 buckets (max of 80% of the metric returned). The ramp-up and ramp-down feature can be disabled by setting `--scaling-schedule-default-scaling-window` to 0 and abrupt scalings can be handled via [scaling policies][policies]. [algo-details]: https://kubernetes.io/docs/tasks/run-application/horizontal-pod-autoscale/#algorithm-details [gist]: https://gist.github.com/jonathanbeber/37f1f918ab7ef6101c6ce56cc2cef3a2 [policies]: https://kubernetes.io/docs/tasks/run-application/horizontal-pod-autoscale/#scaling-policies ### Example This is an example of using the ScalingSchedule collectors to collect metrics from a deployed kind of the CRD. First, the schedule object: ```yaml apiVersion: zalando.org/v1 kind: ClusterScalingSchedule metadata: name: "scheduling-event" spec: schedules: - type: OneTime date: "2021-10-02T08:08:08+02:00" durationMinutes: 30 value: 100 - type: Repeating durationMinutes: 10 value: 120 period: startTime: "15:45" timezone: "Europe/Berlin" days: - Mon - Wed - Fri ``` This resource defines a scheduling event named `scheduling-event` with two schedules of the kind `ClusterScalingSchedule`. `ClusterScalingSchedule` objects aren't namespaced, what means it can be referenced by any HPA in any namespace in the cluster. `ScalingSchedule` have the exact same fields and behavior, but can be referenced just by HPAs in the same namespace. The schedules can have the type `Repeating` or `OneTime`. This example configuration will generate the following result: at `2021-10-02T08:08:08+02:00` for 30 minutes a metric with the value of 100 will be returned. Every Monday, Wednesday and Friday, starting at 15 hours and 45 minutes (Berlin time), a metric with the value of 120 will be returned for 10 minutes. It's not the case of this example, but if multiple schedules collide in time, the biggest value is returned. Check the CRDs definitions ([ScalingSchedule](./docs/scaling_schedules_crd.yaml), [ClusterScalingSchedule](./docs/cluster_scaling_schedules_crd.yaml)) for a better understanding of the possible fields and their behavior. An HPA can reference the deployed `ClusterScalingSchedule` object as this example: ```yaml apiVersion: autoscaling/v2 kind: HorizontalPodAutoscaler metadata: name: "myapp-hpa" spec: scaleTargetRef: apiVersion: apps/v1 kind: Deployment name: myapp minReplicas: 1 maxReplicas: 15 metrics: - type: Object object: describedObject: apiVersion: zalando.org/v1 kind: ClusterScalingSchedule name: "scheduling-event" metric: name: "scheduling-event" target: type: AverageValue averageValue: "10" ``` The name of the metric is equal to the name of the referenced object. The `target.averageValue` in this example is set to 10. This value will be used by the HPA controller to define the desired number of pods, based on the metric obtained (check the [HPA algorithm details](https://kubernetes.io/docs/tasks/run-application/horizontal-pod-autoscale/#algorithm-details) for more context). This HPA configuration explicitly says that each pod of this application supports 10 units of the `ClusterScalingSchedule` metric. Multiple applications can share the same `ClusterScalingSchedule` or `ScalingSchedule` event and have a different number of pods based on its `target.averageValue` configuration. In our specific example at `2021-10-02T08:08:08+02:00` as the metric has the value 100, this application will scale to 10 pods (100/10). Every Monday, Wednesday and Friday, starting at 15 hours and 45 minutes (Berlin time) the application will scale to 12 pods (120/10). Both scaling up will last at least the configured duration times of the schedules. After that, regular HPA scale down behavior applies. Note that these number of pods are just considering these custom metrics, the normal HPA behavior still applies, such as: in case of multiple metrics the biggest number of pods is the utilized one, HPA max and min replica configuration, autoscaling policies, etc.