How do I add a master nodes to a cloud cluster (single-master to a multi-master)?

See the control-plane-manager module FAQ…

How do I reduce the number of master nodes in a cloud cluster (multi-master to single-master)?

See the control-plane-manager module FAQ…

Static nodes

You can add a static node to the cluster manually (an example) or by using Cluster API Provider Static.

How do I add a static node to a cluster (Cluster API Provider Static)?

To add a static node to a cluster (bare metal server or virtual machine), follow these steps:

  1. Prepare the required resources — servers/virtual machines, install specific OS packages, add mount points, configure the network, etc.
  2. Create the SSHCredentials resource.
  3. Create the StaticInstance resource.
  4. Create the NodeGroup resource with the Static nodeType, specify the desired number of nodes in the group and, if necessary, the filter for StaticInstance.

An example of adding a static node.

How do I add a batch of static nodes to a cluster manually?

Use an existing one or create a new NodeGroup custom resource (example of the NodeGroup called worker). The nodeType parameter for static nodes in the NodeGroup must be Static or CloudStatic.

You can automate the bootstrap process with any automation platform you prefer. The following is an example for Ansible.

  1. Pick up one of Kubernetes API Server endpoints. Note that this IP must be accessible from nodes that are being added to the cluster:

    kubectl -n default get ep kubernetes -o json | jq '.subsets[0].addresses[0].ip + ":" + (.subsets[0].ports[0].port | tostring)' -r
    

    Check the K8s version. If the version >= 1.25, create node-group token:

    kubectl create token node-group --namespace d8-cloud-instance-manager --duration 1h
    

    Save the token you got and add it to the token: field of the Ansible playbook in the next steps.

  2. If the Kubernetes version is smaller than 1.25, get a Kubernetes API token for a special ServiceAccount that Deckhouse manages:

    kubectl -n d8-cloud-instance-manager get $(kubectl -n d8-cloud-instance-manager get secret -o name | grep node-group-token) \
      -o json | jq '.data.token' -r | base64 -d && echo ""
    
  3. Create Ansible playbook with vars replaced with values from previous steps:

    - hosts: all
      become: yes
      gather_facts: no
      vars:
        kube_apiserver: <KUBE_APISERVER>
        token: <TOKEN>
      tasks:
        - name: Check if node is already bootsrapped
          stat:
            path: /var/lib/bashible
          register: bootstrapped
        - name: Get bootstrap secret
          uri:
            url: "https://{{ kube_apiserver }}/api/v1/namespaces/d8-cloud-instance-manager/secrets/manual-bootstrap-for-{{ node_group }}"
            return_content: yes
            method: GET
            status_code: 200
            body_format: json
            headers:
              Authorization: "Bearer {{ token }}"
            validate_certs: no
          register: bootstrap_secret
          when: bootstrapped.stat.exists == False
        - name: Run bootstrap.sh
          shell: "{{ bootstrap_secret.json.data['bootstrap.sh'] | b64decode }}"
          args:
            executable: /bin/bash
          ignore_errors: yes
          when: bootstrapped.stat.exists == False
        - name: wait
          wait_for_connection:
            delay: 30
          when: bootstrapped.stat.exists == False
    
  4. Specify one more node_group variable. This variable must be the same as the name of NodeGroup to which node will belong. Variable can be passed in different ways, for example, by using an inventory file.:

    [system]
    system-0
    system-1
    
    [system:vars]
    node_group=system
    
    [worker]
    worker-0
    worker-1
    
    [worker:vars]
    node_group=worker
    
  5. Run the playbook with the inventory file.

How do I clean up a static node manually?

This method is valid for both manually configured nodes (using the bootstrap script) and nodes configured using CAPS.

To decommission a node from the cluster and clean up the server (VM), run the following command on the node:

bash /var/lib/bashible/cleanup_static_node.sh --yes-i-am-sane-and-i-understand-what-i-am-doing

Can I delete a StaticInstance?

A StaticInstance that is in the Pending state can be deleted with no adverse effects.

To delete a StaticInstance in any state other than Pending (Runnig, Cleaning, Bootstraping), you need to:

  1. Add the label "node.deckhouse.io/allow-bootstrap": "false" to the StaticInstance.
  2. Wait until the StaticInstance status becomes Pending.
  3. Delete the StaticInstance.
  4. Decrease the NodeGroup.spec.staticInstances.count field by 1.

How do I change the IP address of a StaticInstance?

You cannot change the IP address in the StaticInstance resource. If an incorrect address is specified in StaticInstance, you have to delete the StaticInstance and create a new one.

How do I migrate a manually configured static node under CAPS control?

You need to clean up the node, then hand over the node under CAPS control.

How do I change the NodeGroup of a static node?

Note that if a node is under CAPS control, you cannot change the NodeGroup membership of such a node. The only alternative is to delete StaticInstance and create a new one.

To switch an existing manually created static node to another NodeGroup, you need to change its group label:

kubectl label node --overwrite <node_name> node.deckhouse.io/group=<new_node_group_name>
kubectl label node <node_name> node-role.kubernetes.io/<old_node_group_name>-

Applying the changes will take some time.

How to clean up a node for adding to the cluster?

This is only needed if you have to move a static node from one cluster to another. Be aware these operations remove local storage data. If you just need to change a NodeGroup, follow this instruction.

Note! Evict resources from the node and remove the node from LINSTOR/DRBD using the instruction if the node you are cleaning up has LINSTOR/DRBD storage pools.

  1. Delete the node from the Kubernetes cluster:

    kubectl drain <node> --ignore-daemonsets --delete-local-data
    kubectl delete node <node>
    
  2. Run cleanup script on the node:

    bash /var/lib/bashible/cleanup_static_node.sh --yes-i-am-sane-and-i-understand-what-i-am-doing
    
  3. Run the bootstrap.sh script after reboot of the node.

How do I know if something went wrong?

If a node in a nodeGroup is not updated (the value of UPTODATE when executing the kubectl get nodegroup command is less than the value of NODES) or you assume some other problems that may be related to the node-manager module, then you need to look at the logs of the bashible service. The bashible service runs on each node managed by the node-manager module.

To view the logs of the bashible service on a specific node, run the following command:

journalctl -fu bashible

Example of output when the bashible service has performed all necessary actions:

May 25 04:39:16 kube-master-0 systemd[1]: Started Bashible service.
May 25 04:39:16 kube-master-0 bashible.sh[1976339]: Configuration is in sync, nothing to do.
May 25 04:39:16 kube-master-0 systemd[1]: bashible.service: Succeeded.

How do I know what is running on a node while it is being created?

You can analyze cloud-init to find out what’s happening on a node during the bootstrapping process:

  1. Find the node that is currently bootstrapping:

    kubectl get instances | grep Pending
    

    An example:

    $ kubectl get instances | grep Pending
    dev-worker-2a6158ff-6764d-nrtbj   Pending   46s
    
  2. Get information about connection parameters for viewing logs:

    kubectl get instances dev-worker-2a6158ff-6764d-nrtbj -o yaml | grep 'bootstrapStatus' -B0 -A2
    

    An example:

    $ kubectl get instances dev-worker-2a6158ff-6764d-nrtbj -o yaml | grep 'bootstrapStatus' -B0 -A2
    bootstrapStatus:
      description: Use 'nc 192.168.199.178 8000' to get bootstrap logs.
      logsEndpoint: 192.168.199.178:8000
    
  3. Run the command you got (nc 192.168.199.115 8000 according to the example above) to see cloud-init logs and determine the cause of the problem on the node.

The logs of the initial node configuration are located at /var/log/cloud-init-output.log.

How do I update kernel on nodes?

Debian-based distros

Create a Node Group Configuration resource by specifying the desired kernel version in the desired_version variable of the shell script (the resource’s spec.content parameter):

apiVersion: deckhouse.io/v1alpha1
kind: NodeGroupConfiguration
metadata:
  name: install-kernel.sh
spec:
  bundles:
    - '*'
  nodeGroups:
    - '*'
  weight: 32
  content: |
    # Copyright 2022 Flant JSC
    #
    # Licensed under the Apache License, Version 2.0 (the "License");
    # you may not use this file except in compliance with the License.
    # You may obtain a copy of the License at
    #
    #     http://www.apache.org/licenses/LICENSE-2.0
    #
    # Unless required by applicable law or agreed to in writing, software
    # distributed under the License is distributed on an "AS IS" BASIS,
    # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
    # See the License for the specific language governing permissions and
    # limitations under the License.

    desired_version="5.15.0-53-generic"

    bb-event-on 'bb-package-installed' 'post-install'
    post-install() {
      bb-log-info "Setting reboot flag due to kernel was updated"
      bb-flag-set reboot
    }

    version_in_use="$(uname -r)"

    if [[ "$version_in_use" == "$desired_version" ]]; then
      exit 0
    fi

    bb-deckhouse-get-disruptive-update-approval
    bb-apt-install "linux-image-${desired_version}"

CentOS-based distros

Create a Node Group Configuration resource by specifying the desired kernel version in the desired_version variable of the shell script (the resource’s spec.content parameter):

apiVersion: deckhouse.io/v1alpha1
kind: NodeGroupConfiguration
metadata:
  name: install-kernel.sh
spec:
  bundles:
    - '*'
  nodeGroups:
    - '*'
  weight: 32
  content: |
    # Copyright 2022 Flant JSC
    #
    # Licensed under the Apache License, Version 2.0 (the "License");
    # you may not use this file except in compliance with the License.
    # You may obtain a copy of the License at
    #
    #     http://www.apache.org/licenses/LICENSE-2.0
    #
    # Unless required by applicable law or agreed to in writing, software
    # distributed under the License is distributed on an "AS IS" BASIS,
    # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
    # See the License for the specific language governing permissions and
    # limitations under the License.

    desired_version="3.10.0-1160.42.2.el7.x86_64"

    bb-event-on 'bb-package-installed' 'post-install'
    post-install() {
      bb-log-info "Setting reboot flag due to kernel was updated"
      bb-flag-set reboot
    }

    version_in_use="$(uname -r)"

    if [[ "$version_in_use" == "$desired_version" ]]; then
      exit 0
    fi

    bb-deckhouse-get-disruptive-update-approval
    bb-yum-install "kernel-${desired_version}"

NodeGroup parameters and their result

The NodeGroup parameter Disruption update Node provisioning Kubelet restart
chaos - - -
cloudInstances.classReference - + -
cloudInstances.maxSurgePerZone - - -
cri.containerd.maxConcurrentDownloads - - +
cri.type - (NotManaged) / + (other) - -
disruptions - - -
kubelet.maxPods - - +
kubelet.rootDir - - +
kubernetesVersion - - +
nodeTemplate - - -
static - - +
update.maxConcurrent - - -

Refer to the description of the NodeGroup custom resource for more information about the parameters.

Changing the InstanceClass or instancePrefix parameter in the Deckhouse configuration won’t result in a RollingUpdate. Deckhouse will create new MachineDeployments and delete the old ones. The number of machinedeployments ordered at the same time is determined by the cloud Instances.maxSurgePerZone parameter.

During the disruption update, an evict of the pods from the node is performed. If any pod failes to evict, the evict is repeated every 20 seconds until a global timeout of 5 minutes is reached. After that, the pods that failed to evict are removed.

How do I redeploy ephemeral machines in the cloud with a new configuration?

If the Deckhouse configuration is changed (both in the node-manager module and in any of the cloud providers), the VMs will not be redeployed. The redeployment is performed only in response to changing InstanceClass or NodeGroup objects.

To force the redeployment of all Machines, you need to add/modify the manual-rollout-id annotation to the NodeGroup: kubectl annotate NodeGroup name_ng "manual-rollout-id=$(uuidgen)" --overwrite.

How do I allocate nodes to specific loads?

Note! You cannot use the deckhouse.io domain in labels and taints keys of the NodeGroup. It is reserved for Deckhouse components. Please, use the dedicated or dedicated.client.com keys.

There are two ways to solve this problem:

  1. You can set labels to NodeGroup’s spec.nodeTemplate.labels, to use them in the Pod’s spec.nodeSelector or spec.affinity.nodeAffinity parameters. In this case, you select nodes that the scheduler will use for running the target application.
  2. You cat set taints to NodeGroup’s spec.nodeTemplate.taints and then remove them via the Pod’s spec.tolerations parameter. In this case, you disallow running applications on these nodes unless those applications are explicitly allowed.

Deckhouse tolerates the dedicated by default, so we recommend using the dedicated key with any value for taints on your dedicated nodes.️ To use custom keys for taints (e.g., dedicated.client.com), you must add the key’s value to the modules.placement.customTolerationKeys parameters. This way, deckhouse can deploy system components (e.g., cni-flannel) to these dedicated nodes.

How to allocate nodes to system components?

Frontend

For Ingress controllers, use the NodeGroup with the following configuration:

nodeTemplate:
  labels:
    node-role.deckhouse.io/frontend: ""
  taints:
    - effect: NoExecute
      key: dedicated.deckhouse.io
      value: frontend

System components

NodeGroup for components of Deckhouse subsystems will look as follows:

nodeTemplate:
  labels:
    node-role.deckhouse.io/system: ""
  taints:
    - effect: NoExecute
      key: dedicated.deckhouse.io
      value: system

How do I speed up node provisioning on the cloud when scaling applications horizontally?

The most efficient way is to have some extra nodes “ready”. In this case, you can run new application replicas on them almost instantaneously. The obvious disadvantage of this approach is the additional maintenance costs related to these nodes.

Here is how you should configure the target NodeGroup:

  1. Specify the number of “ready” nodes (or a percentage of the maximum number of nodes in the group) using the cloudInstances.standby paramter.
  2. If there are additional service components on nodes that are not handled by Deckhouse (e.g., the filebeat DaemonSet), you can specify the percentage of node resources they can consume via the standbyHolder.overprovisioningRate parameter.
  3. This feature requires that at least one group node is already running in the cluster. In other words, there must be either a single replica of the application, or the cloudInstances.minPerZone parameter must be set to 1.

An example:

cloudInstances:
  maxPerZone: 10
  minPerZone: 1
  standby: 10%
  standbyHolder:
    overprovisioningRate: 30%

How do I disable machine-controller-manager in the case of potentially cluster-damaging changes?

Note! Use this switch only if you know what you are doing and clearly understand the consequences.

Set the mcmEmergencyBrake parameter to true:

mcmEmergencyBrake: true

How do I restore the master node if kubelet cannot load the control plane components?

Such a situation may occur if images of the control plane components on the master were deleted in a cluster that has a single master node (e.g., the directory /var/lib/containerd was deleted). In this case, kubelet cannot pull images of the control plane components when restarted since the master node lacks authorization parameters required for accessing registry.deckhouse.io.

Below is an instruction on how you can restore the master node.

containerd

Execute the following command to restore the master node in any cluster running under Deckhouse:

kubectl -n d8-system get secrets deckhouse-registry -o json |
jq -r '.data.".dockerconfigjson"' | base64 -d |
jq -r '.auths."registry.deckhouse.io".auth'

Copy the command’s output and use it for setting the AUTH variable on the corrupted master. Next, you need to pull images of control plane components to the corrupted master:

for image in $(grep "image:" /etc/kubernetes/manifests/* | awk '{print $3}'); do
  crictl pull --auth $AUTH $image
done

You need to restart kubelet after pulling the images.

How to change CRI for NodeGroup?

Note! CRI can only be switched from Containerd to NotManaged and back (the cri.type parameter).

Set NodeGroup cri.type to Containerd or NotManaged.

NodeGroup YAML example:

apiVersion: deckhouse.io/v1
kind: NodeGroup
metadata:
  name: worker
spec:
  nodeType: Static
  cri:
    type: Containerd

Also, this operation can be done with patch:

  • For Containerd:

    kubectl patch nodegroup <NodeGroup name> --type merge -p '{"spec":{"cri":{"type":"Containerd"}}}'
    
  • For NotManaged:

    kubectl patch nodegroup <NodeGroup name> --type merge -p '{"spec":{"cri":{"type":"NotManaged"}}}'
    

Note! While changing cri.type for NodeGroups, created using dhctl, you must change it in dhctl config edit provider-cluster-configuration and in NodeGroup object.

After setting up a new CRI for NodeGroup, the node-manager module drains nodes one by one and installs a new CRI on them. Node update is accompanied by downtime (disruption). Depending on the disruption setting for NodeGroup, the node-manager module either automatically allows node updates or requires manual confirmation.

How to change CRI for the whole cluster?

Note! CRI can only be switched from Containerd to NotManaged and back (the cri.type parameter).

It is necessary to use the dhctl utility to edit the defaultCRI parameter in the cluster-configuration config.

Also, this operation can be done with the following patch:

  • For Containerd:

    data="$(kubectl -n kube-system get secret d8-cluster-configuration -o json | jq -r '.data."cluster-configuration.yaml"' | base64 -d | sed "s/NotManaged/Containerd/" | base64 -w0)"
    kubectl -n kube-system patch secret d8-cluster-configuration -p "{\"data\":{\"cluster-configuration.yaml\":\"$data\"}}"
    
  • For NotManaged:

    data="$(kubectl -n kube-system get secret d8-cluster-configuration -o json | jq -r '.data."cluster-configuration.yaml"' | base64 -d | sed "s/Containerd/NotManaged/" | base64 -w0)"
    kubectl -n kube-system patch secret d8-cluster-configuration -p "{\"data\":{\"cluster-configuration.yaml\":\"$data\"}}"
    

If it is necessary to leave some NodeGroup on another CRI, then before changing the defaultCRI it is necessary to set CRI for this NodeGroup, as described here.

Note! Changing defaultCRI entails changing CRI on all nodes, including master nodes. If there is only one master node, this operation is dangerous and can lead to a complete failure of the cluster! The preferred option is to make a multi-master and change the CRI type!

When changing the CRI in the cluster, additional steps are required for the master nodes:

  1. Deckhouse updates nodes in master NodeGroup one by one, so you need to discover which node is updating right now:

    kubectl get nodes -l node-role.kubernetes.io/control-plane="" -o json | jq '.items[] | select(.metadata.annotations."update.node.deckhouse.io/approved"=="") | .metadata.name' -r
    
  2. Confirm the disruption of the master node that was discovered in the previous step:

    kubectl annotate node <master node name> update.node.deckhouse.io/disruption-approved=
    
  3. Wait for the updated master node to switch to Ready state. Repeat steps for the next master node.

How to add node configuration step?

Additional node configuration steps are set via the NodeGroupConfiguration custom resource.

How to use containerd with Nvidia GPU support?

Create NodeGroup for GPU-nodes.

apiVersion: deckhouse.io/v1
kind: NodeGroup
metadata:
  name: gpu
spec:
  chaos:
    mode: Disabled
  disruptions:
    approvalMode: Automatic
  nodeType: CloudStatic

Create NodeGroupConfiguration for containerd configuration of NodeGroup gpu:

apiVersion: deckhouse.io/v1alpha1
kind: NodeGroupConfiguration
metadata:
  name: containerd-additional-config.sh
spec:
  bundles:
  - '*'
  content: |
    # Copyright 2023 Flant JSC
    #
    # Licensed under the Apache License, Version 2.0 (the "License");
    # you may not use this file except in compliance with the License.
    # You may obtain a copy of the License at
    #
    #     http://www.apache.org/licenses/LICENSE-2.0
    #
    # Unless required by applicable law or agreed to in writing, software
    # distributed under the License is distributed on an "AS IS" BASIS,
    # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
    # See the License for the specific language governing permissions and
    # limitations under the License.

    mkdir -p /etc/containerd/conf.d
    bb-sync-file /etc/containerd/conf.d/nvidia_gpu.toml - << "EOF"
    [plugins]
      [plugins."io.containerd.grpc.v1.cri"]
        [plugins."io.containerd.grpc.v1.cri".containerd]
          default_runtime_name = "nvidia"
          [plugins."io.containerd.grpc.v1.cri".containerd.runtimes]
            [plugins."io.containerd.grpc.v1.cri".containerd.runtimes.runc]
              [plugins."io.containerd.grpc.v1.cri".containerd.runtimes.nvidia]
                privileged_without_host_devices = false
                runtime_engine = ""
                runtime_root = ""
                runtime_type = "io.containerd.runc.v1"
                [plugins."io.containerd.grpc.v1.cri".containerd.runtimes.nvidia.options]
                  BinaryName = "/usr/bin/nvidia-container-runtime"
                  SystemdCgroup = false
    EOF
  nodeGroups:
  - gpu
  weight: 31

Create NodeGroupConfiguration for Nvidia drivers setup on NodeGroup gpu.

Ubuntu

apiVersion: deckhouse.io/v1alpha1
kind: NodeGroupConfiguration
metadata:
  name: install-cuda.sh
spec:
  bundles:
  - ubuntu-lts
  content: |
    # Copyright 2023 Flant JSC
    #
    # Licensed under the Apache License, Version 2.0 (the "License");
    # you may not use this file except in compliance with the License.
    # You may obtain a copy of the License at
    #
    #     http://www.apache.org/licenses/LICENSE-2.0
    #
    # Unless required by applicable law or agreed to in writing, software
    # distributed under the License is distributed on an "AS IS" BASIS,
    # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
    # See the License for the specific language governing permissions and
    # limitations under the License.

    if [ ! -f "/etc/apt/sources.list.d/nvidia-container-toolkit.list" ]; then
      distribution=$(. /etc/os-release;echo $ID$VERSION_ID)
      curl -s -L https://nvidia.github.io/libnvidia-container/gpgkey | sudo apt-key add -
      curl -s -L https://nvidia.github.io/libnvidia-container/$distribution/libnvidia-container.list | sudo tee /etc/apt/sources.list.d/nvidia-container-toolkit.list
    fi
    bb-apt-install nvidia-container-toolkit nvidia-driver-535-server
  nodeGroups:
  - gpu
  weight: 30

Centos

apiVersion: deckhouse.io/v1alpha1
kind: NodeGroupConfiguration
metadata:
  name: install-cuda.sh
spec:
  bundles:
  - centos
  content: |
    # Copyright 2023 Flant JSC
    #
    # Licensed under the Apache License, Version 2.0 (the "License");
    # you may not use this file except in compliance with the License.
    # You may obtain a copy of the License at
    #
    #     http://www.apache.org/licenses/LICENSE-2.0
    #
    # Unless required by applicable law or agreed to in writing, software
    # distributed under the License is distributed on an "AS IS" BASIS,
    # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
    # See the License for the specific language governing permissions and
    # limitations under the License.

    if [ ! -f "/etc/yum.repos.d/nvidia-container-toolkit.repo" ]; then
      distribution=$(. /etc/os-release;echo $ID$VERSION_ID) \
      curl -s -L https://nvidia.github.io/libnvidia-container/$distribution/libnvidia-container.repo | sudo tee /etc/yum.repos.d/nvidia-container-toolkit.repo
    fi
    bb-yum-install nvidia-container-toolkit nvidia-driver
  nodeGroups:
  - gpu
  weight: 30

Bootstrap and reboot node.

How to check if it was successful?

Deploy the Job:

apiVersion: batch/v1
kind: Job
metadata:
  name: nvidia-cuda-test
  namespace: default
spec:
  completions: 1
  template:
    spec:
      restartPolicy: Never
      nodeSelector:
        node.deckhouse.io/group: gpu
      containers:
        - name: nvidia-cuda-test
          image: nvidia/cuda:11.6.2-base-ubuntu20.04
          imagePullPolicy: "IfNotPresent"
          command:
            - nvidia-smi

And check the logs:

$ kubectl logs job/nvidia-cuda-test
Tue Jan 24 11:36:18 2023
+-----------------------------------------------------------------------------+
| NVIDIA-SMI 525.60.13    Driver Version: 525.60.13    CUDA Version: 12.0     |
|-------------------------------+----------------------+----------------------+
| GPU  Name        Persistence-M| Bus-Id        Disp.A | Volatile Uncorr. ECC |
| Fan  Temp  Perf  Pwr:Usage/Cap|         Memory-Usage | GPU-Util  Compute M. |
|                               |                      |               MIG M. |
|===============================+======================+======================|
|   0  Tesla T4            Off  | 00000000:8B:00.0 Off |                    0 |
| N/A   45C    P0    25W /  70W |      0MiB / 15360MiB |      0%      Default |
|                               |                      |                  N/A |
+-------------------------------+----------------------+----------------------+

+-----------------------------------------------------------------------------+
| Processes:                                                                  |
|  GPU   GI   CI        PID   Type   Process name                  GPU Memory |
|        ID   ID                                                   Usage      |
|=============================================================================|
|  No running processes found                                                 |
+-----------------------------------------------------------------------------+

Deploy the Job:

apiVersion: batch/v1
kind: Job
metadata:
  name: gpu-operator-test
  namespace: default
spec:
  completions: 1
  template:
    spec:
      restartPolicy: Never
      nodeSelector:
        node.deckhouse.io/group: gpu
      containers:
        - name: gpu-operator-test
          image: nvidia/samples:vectoradd-cuda10.2
          imagePullPolicy: "IfNotPresent"

And check the logs:

$ kubectl logs job/gpu-operator-test
[Vector addition of 50000 elements]
Copy input data from the host memory to the CUDA device
CUDA kernel launch with 196 blocks of 256 threads
Copy output data from the CUDA device to the host memory
Test PASSED
Done

How to deploy custom containerd configuration?

Bashible on nodes merges main deckhouse containerd config with configs from /etc/containerd/conf.d/*.toml.

How to add additional registry auth?

Deploy NodeGroupConfiguration script:

---
apiVersion: deckhouse.io/v1alpha1
kind: NodeGroupConfiguration
metadata:
  name: containerd-additional-config.sh
spec:
  bundles:
    - '*'
  content: |
    # Copyright 2023 Flant JSC
    #
    # Licensed under the Apache License, Version 2.0 (the "License");
    # you may not use this file except in compliance with the License.
    # You may obtain a copy of the License at
    #
    #     http://www.apache.org/licenses/LICENSE-2.0
    #
    # Unless required by applicable law or agreed to in writing, software
    # distributed under the License is distributed on an "AS IS" BASIS,
    # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
    # See the License for the specific language governing permissions and
    # limitations under the License.

    mkdir -p /etc/containerd/conf.d
    bb-sync-file /etc/containerd/conf.d/additional_registry.toml - << "EOF"
    [plugins]
      [plugins."io.containerd.grpc.v1.cri"]
        [plugins."io.containerd.grpc.v1.cri".registry]
          [plugins."io.containerd.grpc.v1.cri".registry.mirrors]
            [plugins."io.containerd.grpc.v1.cri".registry.mirrors."docker.io"]
              endpoint = ["https://registry-1.docker.io"]
            [plugins."io.containerd.grpc.v1.cri".registry.mirrors."artifactory.proxy"]
              endpoint = ["https://artifactory.proxy"]
          [plugins."io.containerd.grpc.v1.cri".registry.configs]
            [plugins."io.containerd.grpc.v1.cri".registry.configs."artifactory.proxy".auth]
              auth = "AAAABBBCCCDDD=="
    EOF
  nodeGroups:
    - "*"
  weight: 49

How to use NodeGroup’s priority feature

The priority field of the NodeGroup CustomResource allows you to define the order in which nodes will be provisioned in the cluster. For example, cluster-autoscaler can first provision spot-nodes and switch to regular ones when they run out. Or it can provision larger nodes when there are plenty of resources in the cluster and then switch to smaller nodes once cluster resources run out.

Here is an example of creating two NodeGroups using spot-node nodes:

---
apiVersion: deckhouse.io/v1
kind: NodeGroup
metadata:
  name: worker-spot
spec:
  cloudInstances:
    classReference:
      kind: AWSInstanceClass
      name: worker-spot
    maxPerZone: 5
    minPerZone: 0
    priority: 50
  nodeType: CloudEphemeral
---
apiVersion: deckhouse.io/v1
kind: NodeGroup
metadata:
  name: worker
spec:
  cloudInstances:
    classReference:
      kind: AWSInstanceClass
      name: worker
    maxPerZone: 5
    minPerZone: 0
    priority: 30
  nodeType: CloudEphemeral

In the above example, cluster-autoscaler will first try to provision a spot-node. If it fails to add such a node to the cluster within 15 minutes, the worker-spot NodeGroup will be paused (for 20 minutes), and cluster-autoscaler will start provisioning nodes from the worker NodeGroup. If, after 30 minutes, another node needs to be deployed in the cluster, cluster-autoscaler will first attempt to provision a node from the worker-spot NodeGroup before provisioning one from the worker NodeGroup.

Once the worker-spot NodeGroup reaches its maximum (5 nodes in the example above), the nodes will be provisioned from the worker NodeGroup.

Note that node templates (labels/taints) for worker and worker-spot NodeGroups must be the same (or at least suitable for the load that triggers the cluster scaling process).

How to interpret Node Group states?

Ready — the node group contains the minimum required number of scheduled nodes with the status Ready for all zones.

Example 1. A group of nodes in the Ready state:

apiVersion: deckhouse.io/v1
kind: NodeGroup
metadata:
  name: ng1
spec:
  nodeType: CloudEphemeral
  cloudInstances:
    maxPerZone: 5
    minPerZone: 1
status:
  conditions:
  - status: "True"
    type: Ready
---
apiVersion: v1
kind: Node
metadata:
  name: node1
  labels:
    node.deckhouse.io/group: ng1
status:
  conditions:
  - status: "True"
    type: Ready

Example 2. A group of nodes in the Not Ready state:

apiVersion: deckhouse.io/v1
kind: NodeGroup
metadata:
  name: ng1
spec:
  nodeType: CloudEphemeral
  cloudInstances:
    maxPerZone: 5
    minPerZone: 2
status:
  conditions:
  - status: "False"
    type: Ready
---
apiVersion: v1
kind: Node
metadata:
  name: node1
  labels:
    node.deckhouse.io/group: ng1
status:
  conditions:
  - status: "True"
    type: Ready

Updating — a node group contains at least one node in which there is an annotation with the prefix update.node.deckhouse.io (for example, update.node.deckhouse.io/waiting-for-approval).

WaitingForDisruptiveApproval - a node group contains at least one node that has an annotation update.node.deckhouse.io/disruption-required and there is no annotation update.node.deckhouse.io/disruption-approved.

Scaling — calculated only for node groups with the type CloudEphemeral. The state True can be in two cases:

  1. When the number of nodes is less than the desired number of nodes in the group, i.e. when it is necessary to increase the number of nodes in the group.
  2. When a node is marked for deletion or the number of nodes is greater than the desired number of nodes, i.e. when it is necessary to reduce the number of nodes in the group.

The desired number of nodes is the sum of all replicas in the node group.

Example. The desired number of nodes is 2:

apiVersion: deckhouse.io/v1
kind: NodeGroup
metadata:
  name: ng1
spec:
  nodeType: CloudEphemeral
  cloudInstances:
    maxPerZone: 5
    minPerZone: 2
status:
...
  desired: 2
...

Error — contains the last error that occurred when creating a node in a node group.

How do I make werf ignore the Ready conditions in a node group?

werf checks the Ready status of resources and, if available, waits for the value to become True.

Creating (updating) a nodeGroup resource in a cluster can take a significant amount of time to create the required number of nodes. When deploying such a resource in a cluster using werf (e.g., as part of a CI/CD process), deployment may terminate when resource readiness timeout is exceeded. To make werf ignore the nodeGroup status, the following nodeGroup annotations must be added:

metadata:
  annotations:
    werf.io/fail-mode: IgnoreAndContinueDeployProcess
    werf.io/track-termination-mode: NonBlocking

What is an Instance resource?

An Instance resource contains a description of an implementation-independent ephemeral machine resource. For example, machines created by MachineControllerManager or Cluster API Provider Static will have a corresponding Instance resource.

The object does not contain a specification. The status contains:

  1. A link to the InstanceClass if it exists for this implementation;
  2. A link to the Kubernetes Node object;
  3. Current machine status;
  4. Information on how to view machine creation logs (at the machine creation stage).

When a machine is created/deleted, the Instance object is created/deleted accordingly. You cannot create an Instance resource yourself, but you can delete it. In this case, the machine will be removed from the cluster (the removal process depends on implementation details.

When is a node reboot required?

Node reboots may be required after configuration changes. For example, after changing certain sysctl settings, specifically when modifying the kernel.yama.ptrace_scope parameter (e.g., using astra-ptrace-lock enable/disable in the Astra Linux distribution).