IT Cloud. Eugeny ShtoltcЧитать онлайн книгу.
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google_compute_instance.cluster: Destruction complete after 27s
google_compute_address.static-ip-address: Destroying … [id = node-cluster-243923 / europe-north1 / static-ip-address]
google_compute_address.static-ip-address: Destruction complete after 8s
To deploy the entire project, you can add it to the repository, and we will upload it to the virtual machine by copying the installation script to this virtual machine and then launching it:
Moving on to Kubernetes
In the minimal version, creating a cluster of three nodes looks like this:
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ cat main.tf
provider "google" {
credentials = "$ {file (" ../ kubernetes_key.json ")}"
project = "node-cluster-243923"
region = "europe-north1"
}
resource "google_container_cluster" "node-ks" {
name = "node-ks"
location = "europe-north1-a"
initial_node_count = 3
}
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ sudo ../terraform init
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ sudo ../terraform apply
The cluster was created in 2:15, and after I added europe-north1-a two additional zones europe-north1 -b , europe-north1-c and set the number of created instances in the zone to one, the cluster was created in 3:13 seconds , because for higher availability, the nodes were created in different data centers: europe-north1-a , europe-north1-b , europe-north1-c :
provider "google" {
credentials = "$ {file (" ../ kubernetes_key.json ")}"
project = "node-cluster-243923"
region = "europe-north1"
}
resource "google_container_cluster" "node-ks" {
name = "node-ks"
location = "europe-north1-a"
node_locations = ["europe-north1-b", "europe-north1-c"]
initial_node_count = 1
}
Now let's split our cluster into two: the control cluster with Kubernetes and the cluster for our PODs. All clusters will be distributed over three data centers. The cluster for our PODs can auto scale under load up to 2 on each zone (from three to six in total):
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ cat main.tf
provider "google" {
credentials = "$ {file (" ../ kubernetes_key.json ")}"
project = "node-cluster-243923"
region = "europe-north1"
}
resource "google_container_cluster" "node-ks" {
name = "node-ks"
location = "europe-north1-a"
node_locations = ["europe-north1-b", "europe-north1-c"]
initial_node_count = 1
}
resource "google_container_node_pool" "node-ks-pool" {
name = "node-ks-pool"
cluster = "$ {google_container_cluster.node-ks.name}"
location = "europe-north1-a"
node_count = "1"
node_config {
machine_type = "n1-standard-1"
}
autoscaling {
min_node_count = 1
max_node_count = 2
}
}
Let's see what happened and look for the IP address of the cluster entry point:
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ gcloud container clusters list
NAME LOCATION MASTER_VERSION MASTER_IP MACHINE_TYPE NODE_VERSION NUM_NODES STATUS
node-ks europe-north1-a 1.12.8-gke.6 35.228.20.35 n1-standard-1 1.12.8-gke.6 6 RECONCILING
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ gcloud container clusters describe node-ks | grep '^ endpoint'
endpoint: 35.228.20.35
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ ping 35.228.20.35 -c 2
PING 35.228.20.35 (35.228.20.35) 56 (84) bytes of data.
64 bytes from 35.228.20.35: icmp_seq = 1 ttl = 59 time = 8.33 ms
64 bytes from 35.228.20.35: icmp_seq = 2 ttl = 59 time = 7.09 ms
–– 35.228.20.35 ping statistics –
2 packets transmitted, 2 received, 0% packet loss, time 1001ms
rtt min / avg / max / mdev = 7.094 / 7.714 / 8.334 / 0.620 ms
By adding variables, which I selected in a separate file just for clarity, which parameterize our config for different uses, we can use it, for example, to create test and production clusters. Variables can be added as var.name_value , and inserted into the text similarly to JS: $ {var.name_value} , as well as path.root .
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ cat variables.tf
variable "region" {
default = "europe-north1"
}
variable "project_name" {
type = string
default = ""
}
variable "gce_key" {
default = "./kubernetes_key.json"
}
variable "node_count_zone" {
default = 1
}
They can be passed through the -var switch , for example: sudo ./terraform apply -var = "project_name = node-cluster-243923" .
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ cp ../kubernetes_key.json.
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ sudo ../terraform apply -var = "project_name = node-cluster-243923"
Our project in the folder is not only a project, but also a module ready to use:
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ cd ..
essh @ kubernetes-master: ~ / node-cluster $ cat main.tf
module "Kubernetes" {
source = "./Kubernetes"
project_name = "node-cluster-243923"
}
essh @ kubernetes-master: ~ / node-cluster $ sudo ./terraform apply
Or upload to the public repository:
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ git init
Initialized empty GIT repository in /home/essh/node-cluster/Kubernetes/.git/
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ echo "terraform.tfstate" >> .gitignore
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ echo "terraform.tfstate.backup" >> .gitignore
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ echo ".terraform /" >> .gitignore
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ rm -f kubernetes_key.json
essh @ kubernetes-master: ~ / node-cluster / Kubernetes $ git remote add origin https://github.com/ESSch/terraform-google-kubernetes.git
essh