ADR030: Allowed Pod disruptions
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Status: accepted
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Deciders:
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Felix Hennig
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Lars Francke
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Sascha Lautenschläger
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Sebastian Bernauer
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Sönke Liebau
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Date: 2023-09-15
Context and problem statement
Downtime of products is always bad, but sometimes Pods need to be restarted to roll out updates or renew certificates. To prevent services from becoming unavailable we need to make sure that there is always a certain number of Pods still online when restarting Pods. Kubernetes has a concept called PodDisruptionBudget (PDB) to define the number of Pods that need to be kept online or the number of Pods that can safely be taken offline. We want to use this functionary to either prevent services outages entirely or try to keep them to a minimum. PDBs are defined not on a StatefulSet or Deployment, but with a selector over labels, so they can also span Pods from multiple StatefulSets.
Example use-cases
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As a user I want an HDFS and it (or parts) should not be disturbed by planned pod evictions (for example for a certificate renewal). I expect this to be the default behaviour.
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As a user I want to configure maxUnavailable on the role (e.g. datanode) across all rolegroups (e.g. dfs replicas 3 and only a single datanode is allowed to go down - regardless of the number of rolegroups), so that no datanode is a single point of failure. Similarly for ZooKeeper, I want to define PDBs at role level as ZK quorum is independent of role groups.
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As a user I want to override defaults to maybe have less availability but faster rollout times in rolling redeployments; for example a Trino cluster that could take more than 6 hours to rolling redeploy, as the graceful shutdown of Trino workers takes a considerable amount of time - depended on the queries getting executed.
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As a user I want to configure maxUnavailable on rolegroups individually, as I e.g. have some fast datanodes using SSDs and some slow datanodes using HDDs. I want to have always X number of fast datanodes online for performance reasons.
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As a user I want a Superset/NiFi/Kafka and they (or parts) should not be disturbed by planned pod evictions.
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As a user I might want to define PDBs across roles or on other specific Pod selections, in that case I want to be able to disable the Stackable generated PDBs.
We expect the majority of users to either use default PDB settings or define PDBs at a role level. Role group configuration like in use-case 4 has merit but seems like a more niche usage scenario.
Technical considerations
We have the following constraints:
If we use arbitrary workloads and arbitrary selectors (for example when selecting Pods from multiple StatefulSets) we have the following constraints:
* only .spec.minAvailable can be used, not .spec.maxUnavailable.
* only an integer value can be used with .spec.minAvailable, not a percentage.
This means that if we select any Pods that are not part of a StatefulSet or Deployment etc. then we are bound by these constraints. Preliminary testing showed that .spec.maxUnavailable works with multiple StatefulSets.
You can use a selector which selects a subset or superset of the pods belonging to a workload resource. The eviction API will disallow eviction of any pod covered by multiple PDBs, so most users will want to avoid overlapping selectors.
We need to create PDBs in such a way that every Pod is only selected once. This is easiest if a selector is defined per role or for all role groups individually. Excluding certain labels is also possible my using match expressions, but we did not test whether is conflicts with the first constraint about arbitrary selectors. To support the user creating their own custom PDBs we need to support disabling PDB generation to prevent overlapping selectors.
Decision drivers
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Common use-cases should be easy to configure.
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Principle of least surprise: CRD configuration settings and their interactions in case of multiple settings need to be easy to comprehend to prevent user error.
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Extendable design, so that we can later non-breaking add new functionality, such as giving the chance to configure PDBs on roleGroup level as well.
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Simple implementation (far less important)
Considered options
Option 1
Introduce a new roleConfig at role level and put PDBs in there. Only role level PDBs are supported, for role group level the PDBs should be disabled and the user needs to create PDBs manually. The roleConfig is put in place to not put the PDB setting directly in the role.
spec:
nameNodes:
roleConfig: # <<<
podDisruptionBudget: # optional
enabled: true # optional, defaults to true
maxUnavailable: 1 # optional, defaults to our "smart" calculation
roleGroups:
default:
replicas: 2
dataNodes:
# use pdb defaults
roleGroups:
default:
replicas: 2Pros
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simple to understand
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covers the majority of use cases
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still leaves the option to disable and roll your own
Cons
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Yet another "config" (config, clusterConfig and now roleConfig as well)
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That’s kind of the way the real world is: There are some thing you can configure on cluster level (e.g. ldap), role level (pdbs) and role group level (resources). This models this the closest.
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Its not possible to define PDBs on rolegroups without the user deploying it’s own PDBs.
In the discussion the option of having the PDB directly in the role without a roleConfig was briefly discussed but not considered as an option due to being too messy, so it is not listed as an explicit option here.
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Option 2 - PDB in config, but only at role level
Instead of inventing a new roleConfig setting, put the PDB in the config. This might seem better at first, but usually settings in config can also be set at role group level, and in this case, that would not be true.
spec:
nameNodes:
config: # <<<
podDisruptionBudget:
enabled: true
maxUnavailable: 1
roleGroups:
default:
replicas: 2
config: {}
# no such field as podDisruptionBudgetPros
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Everything configurable is below
config, no newroleConfig -
Like Option 1, covers configuration of the most important use cases
Cons
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spec.nameNodes.configis not similar tospec.nameNodes.roleGroups.default.config⇒ Confusing to the user-
thinking more about it, it might be confusing that the setting is not "copied" to all role groups like other settings like resources or affinities.
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Still no option to configure role group level PDBs
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Possibly complicated to implement, due to
configusually being identical at role and role group level
Option 3: PDB in config with elaborate merge mechanism
Similar to Option 2, the PDB setting is located in the config but it is actually possible to use it at both role and role group level.
We develop a semantic merge mechanism that would prevent overlapping PDBs.
CRD Example
apiVersion: hdfs.stackable.tech/v1alpha1
kind: HdfsCluster
metadata:
name: simple-hdfs
spec:
image:
productVersion: 3.3.4
clusterConfig:
zookeeperConfigMapName: simple-hdfs-znode
nameNodes:
config:
podDisruptionBudget:
enabled: true
maxUnavailable: 2
roleGroups:
hdd:
replicas: 16
config:
podDisruptionBudget:
maxUnavailable: 4
ssd:
replicas: 8
config:
podDisruptionBudget:
enabled: false
in-memory:
replicas: 4would end up with something like
apiVersion: policy/v1
kind: PodDisruptionBudget
metadata:
name: simple-hdfs-datanodes-hdds
spec:
maxUnavailable: 4
selector:
matchLabels:
app.kubernetes.io/name: hdfs
app.kubernetes.io/instance: simple-hdfs
app.kubernetes.io/component: datanode
app.kubernetes.io/rolegroup: hdd
---
apiVersion: policy/v1
kind: PodDisruptionBudget
metadata:
name: simple-hdfs-datanodes-not-hdds
spec:
maxUnavailable: 2
selector:
matchLabels:
app.kubernetes.io/name: hdfs
app.kubernetes.io/instance: simple-hdfs
app.kubernetes.io/component: datanode
matchExpressions:
- key: app.kubernetes.io/rolegroup
operator: NotIn
values:
- hdd
- key: app.kubernetes.io/rolegroup
operator: NotIn
values:
- in-memoryOption 4 - PDB in config with normal "shared role group config" behaviour
Again we put the PDB in the config section but simply use the normal "copy" behaviour for this setting.
This would be simple and easy to understand, but does not allow for true role level PDBs.
CRD Example
spec:
dataNodes:
config:
podDisruptionBudget:
maxUnavailable: 2
roleGroups:
hdd:
replicas: 16
ssd:
replicas: 8
in-memory:
replicas: 4would end up with
apiVersion: policy/v1
kind: PodDisruptionBudget
metadata:
name: simple-hdfs-datanodes-hdds
spec:
maxUnavailable: 2
selector:
matchLabels:
app.kubernetes.io/name: hdfs
app.kubernetes.io/instance: simple-hdfs
app.kubernetes.io/component: datanode
app.kubernetes.io/rolegroup: hdd
---
apiVersion: policy/v1
kind: PodDisruptionBudget
metadata:
name: simple-hdfs-datanodes-hdds
spec:
maxUnavailable: 2
selector:
matchLabels:
app.kubernetes.io/name: hdfs
app.kubernetes.io/instance: simple-hdfs
app.kubernetes.io/component: datanode
app.kubernetes.io/rolegroup: ssd
---
apiVersion: policy/v1
kind: PodDisruptionBudget
metadata:
name: simple-hdfs-datanodes-hdds
spec:
maxUnavailable: 2
selector:
matchLabels:
app.kubernetes.io/name: hdfs
app.kubernetes.io/instance: simple-hdfs
app.kubernetes.io/component: datanode
app.kubernetes.io/rolegroup: in-memoryspec:
nameNodes:
config:
podDisruptionBudget:
enabled: true
maxUnavailable: 2
roleGroups:
hdd:
replicas: 16
config:
podDisruptionBudget:
maxUnavailable: 4
ssd:
replicas: 8
config:
podDisruptionBudget:
enabled: false
in-memory:
replicas: 4would end up with
apiVersion: policy/v1
kind: PodDisruptionBudget
metadata:
name: simple-hdfs-datanodes-hdds
spec:
maxUnavailable: 4
selector:
matchLabels:
app.kubernetes.io/name: hdfs
app.kubernetes.io/instance: simple-hdfs
app.kubernetes.io/component: datanode
app.kubernetes.io/rolegroup: hdd
---
apiVersion: policy/v1
kind: PodDisruptionBudget
metadata:
name: simple-hdfs-datanodes-hdds
spec:
maxUnavailable: 2
selector:
matchLabels:
app.kubernetes.io/name: hdfs
app.kubernetes.io/instance: simple-hdfs
app.kubernetes.io/component: datanode
app.kubernetes.io/rolegroup: in-memory