Download as PDF, PPTX
![FROM golang:1.8
WORKDIR /go/src/app
COPY . .
RUN go-wrapper download
RUN go-wrapper build
EXPOSE 8080
ENTRYPOINT ["/hello-world"]](https://image.slidesharecdn.com/k8s-4-devops-180403151756/85/A-DevOps-guide-to-Kubernetes-16-320.jpg)
![Popularized Linux Containers
Originated in 2013 by a small PaaS company called DotCloud.
Provided an easy to use interface to the [already existing] Linux Containers
Linux containers are like lightweight VMs that use the built in Linux features instead of virtualizing the
hardware.
Most linux containers contain a single application rather than a whole operating system.
100s of Containers per server vs a handful of VMs.
Easy to share artifacts called Images.
Friendly to Developer and Operator workflows alike.](https://image.slidesharecdn.com/k8s-4-devops-180403151756/85/A-DevOps-guide-to-Kubernetes-33-320.jpg)
![Is [effectively] a Directory, possibly with data in it, available to all containers in a Pod.
Usually Shares lifecycle of a Pod (Created when Pod is created, destroyed when Pod is
destroyed).
Can be mounted from local disk, or from a network storage device such as a EBS volume,
iscsi, NFS, etc.](https://image.slidesharecdn.com/k8s-4-devops-180403151756/85/A-DevOps-guide-to-Kubernetes-53-320.jpg)
![Provides key-value pairs to be injected into a pod much like user-data is injected into a Virtual
Machine in the cloud.
Allows you to do last minute configuration of applications running on Kubernetes such as
setting a database host, or a admin password.
ConfigMaps store values as strings, Secrets store them as byte arrays (serialized as base64
encoded strings).
Secrets are [currently] not encrypted by default. This is likely to change.
Can be injected as files in a Volume, or as Environment Variables.](https://image.slidesharecdn.com/k8s-4-devops-180403151756/85/A-DevOps-guide-to-Kubernetes-54-320.jpg)
![FROM golang:1.8
WORKDIR /go/src/app
COPY . .
RUN go-wrapper download
RUN go-wrapper build
EXPOSE 8080
ENTRYPOINT ["/hello-world"]](https://image.slidesharecdn.com/k8s-4-devops-180403151756/75/A-DevOps-guide-to-Kubernetes-16-2048.jpg)
![Popularized Linux Containers
Originated in 2013 by a small PaaS company called DotCloud.
Provided an easy to use interface to the [already existing] Linux Containers
Linux containers are like lightweight VMs that use the built in Linux features instead of virtualizing the
hardware.
Most linux containers contain a single application rather than a whole operating system.
100s of Containers per server vs a handful of VMs.
Easy to share artifacts called Images.
Friendly to Developer and Operator workflows alike.](https://image.slidesharecdn.com/k8s-4-devops-180403151756/75/A-DevOps-guide-to-Kubernetes-33-2048.jpg)
![Is [effectively] a Directory, possibly with data in it, available to all containers in a Pod.
Usually Shares lifecycle of a Pod (Created when Pod is created, destroyed when Pod is
destroyed).
Can be mounted from local disk, or from a network storage device such as a EBS volume,
iscsi, NFS, etc.](https://image.slidesharecdn.com/k8s-4-devops-180403151756/75/A-DevOps-guide-to-Kubernetes-53-2048.jpg)
![Provides key-value pairs to be injected into a pod much like user-data is injected into a Virtual
Machine in the cloud.
Allows you to do last minute configuration of applications running on Kubernetes such as
setting a database host, or a admin password.
ConfigMaps store values as strings, Secrets store them as byte arrays (serialized as base64
encoded strings).
Secrets are [currently] not encrypted by default. This is likely to change.
Can be injected as files in a Volume, or as Environment Variables.](https://image.slidesharecdn.com/k8s-4-devops-180403151756/75/A-DevOps-guide-to-Kubernetes-54-2048.jpg)
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Similar to A DevOps guide to Kubernetes
A DevOps guide to Kubernetes
- 1.
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- 3. © Copyright 2017Pivotal Software, Inc. All rights Reserved. A DevOps Guide to Kubernetes Paul Czarkowski @pczarkowski
- 4. Paul Czarkowski DeveloperAdvocate at Pivotal Software ● Systems Administrator ● DevOps Practitioner ● Open Source Contributor
- 7. package main ... ... func main(){ fmt.Println("starting hello world app") healthHandler := health.NewHandler() http.Handle("/health/", healthHandler) http.HandleFunc("/", serve) http.ListenAndServe(":8080", nil) } ... ...
- 9. - name: installntp package: name: ntp - name: configure ntp template: src: ntp.conf dest: /etc/ntp.conf notify: restart ntp - name: start ntp service: name: ntp state: started
- 10. # -*- mode:ruby -*- # vi: set ft=ruby : # Vagrantfile API/syntax version. Don't touch unless you know what you're doing! VAGRANTFILE_API_VERSION = "2" Vagrant.configure(VAGRANTFILE_API_VERSION) do |config| # https://vagrantcloud.com/ubuntu config.vm.box = "ubuntu/xenial64" config.vm.network "private_network", type: "dhcp" # Forward ports config.vm.network "forwarded_port", guest: 8080, host: 8080 # hello world config.vm.provider "virtualbox" do |v| v.memory = 4096 v.cpus = 2 end
- 11. variable "region" { default= "europe-west1-d" // We're going to need it in several places in this config } provider "google" { credentials = "${file("account.json")}" project = "my-project" region = "${var.region}" } resource "google_compute_instance" "test" { count = 1 // Adjust as desired name = "test${count.index + 1}" // yields "test1", "test2", etc. It's also the machine's name and hostname machine_type = "f1-micro" // smallest (CPU & RAM) available instance zone = "${var.region}" // yields "europe-west1-d" as setup previously. Places your VM in Europe disk { image = "debian-7-wheezy-v20160301" // the operative system (and Linux flavour) that your machine will run } network_interface { network = "default" access_config { // Ephemeral IP - leaving this block empty will generate a new external IP and assign it to the machine } } }
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- 15. package main ... ... func main(){ fmt.Println("starting hello world app") healthHandler := health.NewHandler() http.Handle("/health/", healthHandler) http.HandleFunc("/", serve) http.ListenAndServe(":8080", nil) } ... ...
- 16. FROM golang:1.8 WORKDIR /go/src/app COPY. . RUN go-wrapper download RUN go-wrapper build EXPOSE 8080 ENTRYPOINT ["/hello-world"]
- 17. apiVersion: apps/v1beta1 kind: Deployment metadata: labels: app:hello-world name: hello-app spec: replicas: 2 template: metadata: labels: app: hello-world spec: containers: - image: paulczar/hello-world name: hello-world
- 18. $ minikube start $docker build -t hello-world . $ kubectl apply -f deployment.yaml $ curl http://localhost:8080 Hello World!
- 21. Culture - Increasedcollaboration between Development and Operations (and the rest of the business) and an attitude of shared responsibility. Automation - Increases velocity, but just as importantly reduces defects and creates consistency and repeatability. Measurement - Need to measure in order to ensure that improvement is happening. Sharing - As we share tools, discoveries and lessons new opportunities to collaborate will be discovered and duplicate work can be eliminated.
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- 28. Infrastructure Team Platform Team ApplicationTeam(s) S R E
- 29. Infrastructure Team Platform Team ApplicationTeam(s) YOU Google ( GKE, GCP ) } } S R E
- 30. Culture - Increasedcollaboration between Development and Operations (and the rest of the business) and an attitude of shared responsibility. Automation - Increases velocity, but just as importantly reduces defects and creates consistency and repeatability. Measurement - Need to measure in order to ensure that improvement is happening. Sharing - As we share tools, discoveries and lessons new opportunities to collaborate will be discovered and duplicate work can be eliminated.
- 33. Popularized Linux Containers Originatedin 2013 by a small PaaS company called DotCloud. Provided an easy to use interface to the [already existing] Linux Containers Linux containers are like lightweight VMs that use the built in Linux features instead of virtualizing the hardware. Most linux containers contain a single application rather than a whole operating system. 100s of Containers per server vs a handful of VMs. Easy to share artifacts called Images. Friendly to Developer and Operator workflows alike.
- 34. You tell Dockerhow to build a container image via a fairly simple Dockerfile which should generally live alongside your code in your version control system. A build/test system (ex. Jenkins, Travis, Concourse) should be used to build and tag images based on code changes and test results and push those images to a Registry. There are a plethora of Registries to choose from and most have a decent UI, Access Controls, and even vuln scanning. ● Docker Registry (either public in form of Docker Hub, or privately run) ● Your Cloud Provider (most public clouds have a Registry service) ● Harbor (extends opensource registry to have enterprise features) ● Artifactory (general purpose artifact repository manager) ● Quay ( one of the earliest third party registries )
- 35. A container orchestrationsystem. Greek for “Helmsman” or “Pilot” A Borg like platform using Docker as the execution engine originally built by a small team of Google engineers (Joe Beda, Brendan Burns and Craig McLuckie) and Open Sourced in 2014. GIFEE (Google Infrastructure For Everybody Else). Production ready! (for some definition of the word production.) Has a rapid release cycle of a new minor version every three months. (version 1.9 at writing of this) First project donated to the Cloud Native Compute Foundation.
- 36. An IaaS forContainers (CaaS) Abstracts away your infrastructure and provides a declarative language for the user to declare their desired state and then makes that actual state Linux containers instead of VMs. Applications not Operating Systems. Provides a consistent user experience for providing Compute, Network and Storage resources and running applications that consume them. Extends Compute, Network and Storage resources with Controllers that create, monitor and perform actions on them to create higher level abstractions.
- 37. Controllers are effectivelya infinite loop that interacts with the kubernetes API to ensure the actual state of a resource matches the declared state. #!/bin/bash while true; do count=$(kubectl get pods | grep nginx | wc -l) if $count < 5; then kubectl run --image=nginx nginx fi sleep 120 done
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- 44. Culture - Increasedcollaboration between Development and Operations (and the rest of the business) and an attitude of shared responsibility. Automation - Increases velocity, but just as importantly reduces defects and creates consistency and repeatability. Measurement - Need to measure in order to ensure that improvement is happening. Sharing - As we share tools, discoveries and lessons new opportunities to collaborate will be discovered and duplicate work can be eliminated.
- 45. How to Get an Kubernetes Areyou in the “cloud”? yes Which cloud ? GKEAKS EKS Azure Google Amazon Do you want help? no GLHF Pivotal Container Service … ... https://kubernetes.io/partners no yes Other A laptop ? minikube no yes
- 50. API Server Kube Scheduler K8sMaster Controller Manager Etcd Kubelet Kube-proxy K8s Worker Pod Pod Pod K8s Worker Pod Pod Pod K8s Worker Pod Pod Pod CNI CNI CNI Docker Kubelet Kube-proxy Docker Kubelet Kube-proxy Docker
- 51. one or moreapplication containers that are tightly coupled, sharing network and storage. Example: a web front-end Pod that consists of an NGINX container and a PHP-FPM container with a shared unix socket and a “init” container to transform their config files based on environment variables. deployment a controller that ensures a set number of replicas of a Pod is running and provides update and upgrade workflows for your Pods. Example: cloud native Node app that scales horizontally and upgrades 2 pods at a time. statefulset a controller that manages stateful application Deployments by providing sticky identity for pods and strict ordering and uniqueness. Example: Cassandra database. First pod is ‘cassandra-0’ thus all other pods in the set can be told to cluster to ‘cassandra-0’ and it will form a ring, plus the storage will survive pod restarts.
- 52. tracks Pods basedon metadata and provides connectivity and service discovery (DNS, Env variables) for them. Published as ClusterIP (default) exposes service on a cluster-internal IP. NodePort extends ClusterIP to expose services on each node’s IP via a static port. LoadBalancer extends NodePort to configure a cloud provider’s load balancer using the cloud-controller-manager. Ingress is a controller that manages an external entity to provide load balancing, SSL termination and name-based virtual hosting to services based on a set of rules.
- 53. Is [effectively] aDirectory, possibly with data in it, available to all containers in a Pod. Usually Shares lifecycle of a Pod (Created when Pod is created, destroyed when Pod is destroyed). Can be mounted from local disk, or from a network storage device such as a EBS volume, iscsi, NFS, etc.
- 54. Provides key-value pairsto be injected into a pod much like user-data is injected into a Virtual Machine in the cloud. Allows you to do last minute configuration of applications running on Kubernetes such as setting a database host, or a admin password. ConfigMaps store values as strings, Secrets store them as byte arrays (serialized as base64 encoded strings). Secrets are [currently] not encrypted by default. This is likely to change. Can be injected as files in a Volume, or as Environment Variables.
- 55.
- 56. apiVersion: v1 kind: Service metadata: name:hello-svc spec: ports: - port: 80 protocol: TCP targetPort: 8080 selector: app: hello-world type: NodePort apiVersion: apps/v1beta1 kind: Deployment metadata: labels: app: hello-world name: hello-app spec: replicas: 2 template: metadata: labels: app: hello-world spec: containers: - image: paulczar/hello-world name: hello-world hello-app Pod app=hello-world hello-app Pod app=hello-world hello-svc Service app=hello-world http 80 http 8080 - load balanced
- 57. https://url apiVersion: extensions/v1beta1 kind: Ingress metadata: name:hello-goodbye spec: rules: - http: paths: - path: /hello backend: serviceName: hello-svc servicePort: 80 - http: paths: - path: /goodbye backend: serviceName: goodbye-svc servicePort: 81 ingress-nginx app=hello-world hello-app Pod app=hello-world hello-svc Service app=hello-world http 8080 hello-app Pod app=goodbye-world goodbye-svc Service app=goodbye-world http 8080 http://url/hello http://url/goodbye
- 58. $ kubectl apply-f manifests/ deployment "hello-app" created service "hello-svc" created deployment "goodbye-app" created service "goodbye-svc" created ingress "hello-goodbye" created $ curl -k https://$(minikube ip)/hello Hello World! $ curl -k https://$(minikube ip)/goodbye Goodbye Cruel world!
- 59. apiVersion: v1 kind: ConfigMap metadata: name:hello-cm data: db: user:pass@host/db apiVersion: apps/v1beta1 kind: Deployment metadata: name: hello-app labels: app: hello-world ... ... spec: containers: - image: paulczar/hello-world name: hello-world volumeMounts: - name: config mountPath: /etc/hello volumes: - name: config configMap: name: hello-cm apiVersion: v1 kind: Service metadata: name: hello-svc labels: app: hello-world spec: ports: - port: 81 protocol: TCP targetPort: 8080 selector: app: hello-world type: NodePort
- 60. Helm is thepackage manager for Kubernetes Provides tooling to template, package, share, and run Kubernetes manifests for a given application in the form of Charts. Helm Client a CLI that helps you develop and run Charts. Tiller Server runs in your cluster and translates Helm Charts into Running Applications. ~ 150 community managed Helm Charts at https://hub.kubeapps.com/ . ├── Chart.yaml ├── templates │ ├── deployment.yaml │ ├── ingress.yaml │ ├── NOTES.txt │ └── service.yaml └── values.yaml
- 61. apiVersion: v1 kind: ConfigMap metadata: name:{{ .Chart.name}}-cm data: db: {{ .Value.db }} apiVersion: apps/v1beta1 kind: Deployment metadata: name: {{ .Chart.name}}-app labels: app: {{ .Chart.name}} ... ... spec: containers: - image: paulczar/hello-world name: hello-world volumeMounts: - name: config mountPath: /etc/hello volumes: - name: config configMap: name: {{ .Chart.name}}-cm apiVersion: v1 kind: Service metadata: name: {{ .Chart.name}}-svc labels: app: {{ .Chart.name}}-world spec: ports: - port: {{ .Value.port }} protocol: TCP targetPort: 8080 selector: app: {{ .Chart.name}}-world type: NodePort
- 62. $ helm install--name staging . --set db=’user:pass@staging.mysql/dbname’ $ helm install --name production . --set db=’user:pass@production.mysql/dbname’
- 63. Next Steps …Further reading. ● Kubernetes Docs, specifically the tutorials and troubleshooting sectiong ○ https://kubernetes.io/docs/home/ ○ https://kubernetes.io/docs/tutorials/kubernetes-basics/ ○ https://kubernetes.io/docs/tasks/debug-application-cluster/troubleshooting/ ● Writing your first Helm Chart ○ https://medium.com/@pczarkowski/writing-your-first-helm-chart-f3433344f824 ● Pivotal’s Enterprise Kubernetes Offering ○ https://pivotal.io/platform/pivotal-container-service ● Kelsey Hightower’s Kubecon Keynote showing CI/CD pipeline ○ https://www.youtube.com/watch?v=07jq-5VbBVQ
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- 65. © Copyright 2017Pivotal Software, Inc. All rights Reserved. Transforming How The World Builds Software