At this time of writing (2019.06.10) Scaleway’s Kubernetes as a Service, named Kapsule is in Private Beta and got access and pretty stoked on how easy it is to provision a Kubernetes cluster.
What are we doing today?
In this tutorial I will show you how easy it is to provision a 3 node Kubernetes Cluster on Scaleway. In the upcoming tutorial, I will create traefik as an ingress controller and deploy applications to our cluster. Github Repo Version available for now
Provision a Kapsule Cluster
Head over to Kapsule and provision a Kubernetes Cluster:
At this point in time, I will only create a one node “cluster”, as I want to show how to add pools after the intial creation.
After the cluster has been provisioned, you will get information about your endpoints from the Cluster Infromation Section, which we will need for our ingresses:
Test the connection by getting the info of your nodes in your kubernetes cluster:
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$ kubectl get node
NAME STATUS ROLES AGE VERSION
scw-k8s-mystifying-torvalds-default-7f263aabab Ready <none> 4m v1.14.1
Add more nodes:
Provision another pool with 2 more nodes in our cluster:
After the pool has been provisioned, verified that they have joined the cluster:
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$ kubectl get nodes
NAME STATUS ROLES AGE VERSION
scw-k8s-mystifying-torvald-jovial-mclar-25a942 Ready <none> 2m v1.14.1
scw-k8s-mystifying-torvald-jovial-mclar-eaf1a2 Ready <none> 2m v1.14.1
scw-k8s-mystifying-torvalds-default-7f263aabab Ready <none> 15m v1.14.1
Master / Node Capabilities
Usually, I will label master nodes as master: node-role.kubernetes.io/master and worker nodes as nodes: node-role.kubernetes.io/node to allow container scheduling only on the worker nodes. But Scaleway manages this on their end and when you list your nodes, the nodes that you see are your “worker” nodes.
The master nodes are managed by Scaleway.
Well Done Scaleway
Just one more reason I really love Kapsule. Simplicity at its best, well done to Scaleway. I hope most of the people got access to private beta, but if not, im pretty sure they will keep the public informed on public release dates.
As many of you might know, when you deploy a ELK stack on Amazon Web Services, you only get E and K in the ELK stack, which is Elasticsearch and Kibana. Here we will be dealing with Logstash on EC2.
What will we be doing
In this tutorial we will setup a Logstash Server on EC2, setup a IAM Role and Autenticate Requests to Elasticsearch with an IAM Role, setup Nginx so that logstash can ship logs to Elasticsearch.
I am not fond of working with access key’s and secret keys, and if I can stay away from handling secret information the better. So instead of creating a access key and secret key for logstash, we will instead create a IAM Policy that will allow the actions to Elasticsearch, associate that policy to an IAM Role, set EC2 as a trusted entity and strap that IAM Role to the EC2 Instance.
Then we will allow the IAM Role ARN to the Elasticsearch Policy, then when Logstash makes requests against Elasticsearch, it will use the IAM Role to assume temporary credentials to authenticate. That way we don’t have to deal with keys. But I mean you can create access keys if that is your preferred method, I’m just not a big fan of keeping secret keys.
The benefit of authenticating with IAM, allows you to remove a reverse proxy that is another hop to the path of your target.
Create the IAM Policy:
Create a IAM Policy that will allow actions to Elasticsearch:
Note that the aws_ directives has been left empty as that seems to be the way it needs to be set when using roles. Authentication will be assumed via the Role which is associated to the EC2 Instance.
If you are using access keys, you can populate them there.
Start Logstash
Start logstash:
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$ service logstash start
Tail the logs to see if logstash starts up correctly, it should look more or less like this:
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$ tail -f /var/log/logstash/logstash-plain.log
[2019-06-04T16:38:12,087][INFO ][logstash.runner ] Starting Logstash {"logstash.version"=>"6.8.0"}
[2019-06-04T16:38:14,480][INFO ][logstash.pipeline ] Starting pipeline {:pipeline_id=>"main", "pipeline.workers"=>2, "pipeline.batch.size"=>125, "pipeline.batch.delay"=>50}
[2019-06-04T16:38:15,226][INFO ][logstash.outputs.elasticsearch] Elasticsearch pool URLs updated {:changes=>{:removed=>[], :added=>[https://search-my-es-domain-xx.eu-west-1.es.amazonaws.com:443/]}}
[2019-06-04T16:38:15,234][INFO ][logstash.outputs.elasticsearch] Running health check to see if an Elasticsearch connection is working {:healthcheck_url=>https://search-my-es-domain-xx.eu-west-1.es.amazonaws.com:443/, :path=>"/"}
Install Nginx
As you noticed, I have specified /var/log/nginx/access.log as my input file for logstash, as we will test logstash by shipping nginx access logs to Elasticsearch Service.
Vagrant makes it really easy to provision virtual servers, which they refer as “boxes”, that enables developers to run their jobs/tasks/applications in a really easy and fast way. Vagrant utilizes a declarative configuration model, so you can describe which OS you want, bootstrap them with installation instructions as soon as it boots, etc.
What are we doing today?
When completing this tutorial, you should be able to launch a Ubuntu Virtual Server locally with Vagrant and using the Virtualbox Provider which will be responsible for running our VM’s.
I am running this on a Ubuntu 19 Desktop, but you can run this on Mac/Windows/Linux. First we will install Virtualbox, then Vagrant, then we will provision a Ubuntu box and I will also show how to inject shell commands into your Vagrantfile so that you can provision software to your VM, and also forward traffic to a web server through your host to the guest.
Head over to Virtualbox’s download page and grab the latest version of virtualbox and install it.
After the installation run vboxconfig to build the kernel modules. If you get the error that I received as seen below:
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$ sudo /sbin/vboxconfig
vboxdrv.sh: Building VirtualBox kernel modules
vboxdrv.sh: Starting VirtualBox services
vboxdrv.sh: Building VirtualBox kernel modules
vboxdrv.sh: failed: modprobe vboxdrv failed. Please use 'dmesg' to find out why
This resource on askubuntu.com helped me out. In short, theres a requirement that all the kernel modules must be signed by a key trusted by the UEFI system.
Remember the password, as you will require it when you reboot. You will get the option to “Enroll MOK”, select that, enter the initial password and reboot.
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$ sudo reboot
You should be able to get a response from the binary:
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$ VirtualBox -h
Oracle VM VirtualBox VM Selector v6.0.6_Ubuntu
Install Vagrant
Head over to Vagrant’s installation page, get the latest version for your operating system and install it.
After installing it you should get the following response:
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$ vagrant --version
Vagrant 2.2.4
Provision a Box with Vagrant
When you head over to app.vagrantup.com/boxes/search you can select the pre-packed operating system of your choice. As for this demonstration, I went with: ubuntu/trusty64
First we will need to initialize a new Vagrant environment by creating a Vagrantfile, as we will be passing the name of our operating system, it will be populated in our Vagrantfile:
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$ vagrant init ubuntu/trusty64
A `Vagrantfile` has been placed in this directory. You are now
ready to `vagrant up` your first virtual environment! Please read
the comments in the Vagrantfile as well as documentation on
`vagrantup.com` for more information on using Vagrant.
Now since the Vagrantfile has been placed in our current working directory, let’s have a look at it:
As you can see the Vagrantfile has a set of instructions of how we want our VM to be. At this moment you will only see that the image is defined as ubuntu/trusty64.
Let’s start our VM:
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$ vagrant up
Bringing machine 'default' up with 'virtualbox' provider...
==> default: Importing base box 'ubuntu/trusty64'...
==> default: Matching MAC address for NAT networking...
==> default: Checking if box 'ubuntu/trusty64' version '20190429.0.1' is up to date...
==> default: Setting the name of the VM: vagrant_default_1559238982328_97737
==> default: Clearing any previously set forwarded ports...
default: Adapter 1: nat
==> default: Forwarding ports...
default: 22 (guest) => 2222 (host) (adapter 1)
==> default: Booting VM...
==> default: Waiting for machine to boot. This may take a few minutes...
default: SSH address: 127.0.0.1:2222
default: SSH username: vagrant
default: SSH auth method: private key
default:
default: Vagrant insecure key detected. Vagrant will automatically replace
default: this with a newly generated keypair for better security.
Now that our VM has been booted, we can ssh to our server by simply running:
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$ vagrant ssh
ubuntu-server $
Making changes to your config
So let’s say we want to edit our Vagrantfile to provide shell commands to install nginx and forward our host port 8080 to our guest port 80, so that we can access our VM’s webserver on localhost using port 8080.
This is a curated list of tutorials of prometheus, from installing prometheus, installing grafana, exporters, docker versions of the prometheus / grafana / node exporter stack, etc.
$ systemctl status blackbox_exporter
blackbox_exporter.service - Blackbox Exporter
Loaded: loaded (/etc/systemd/system/blackbox_exporter.service; disabled; vendor preset: enabled)
Active: active (running) since Wed 2019-05-08 00:02:40 UTC; 5s ago
Main PID: 10084 (blackbox_export)
Tasks: 6 (limit: 4704)
CGroup: /system.slice/blackbox_exporter.service
└─10084 /usr/local/bin/blackbox_exporter --config.file /etc/blackbox_exporter/blackbox.yml
May 08 00:02:40 ip-172-31-41-126 systemd[1]: Started Blackbox Exporter.
May 08 00:02:40 ip-172-31-41-126 blackbox_exporter[10084]: level=info ts=2019-05-08T00:02:40.5229204Z caller=main.go:213 msg="Starting blackbox_exporter" version="(version=0.14.0, branch=HEAD, revision=bb
May 08 00:02:40 ip-172-31-41-126 blackbox_exporter[10084]: level=info ts=2019-05-08T00:02:40.52553523Z caller=main.go:226 msg="Loaded config file"
May 08 00:02:40 ip-172-31-41-126 blackbox_exporter[10084]: level=info ts=2019-05-08T00:02:40.525695324Z caller=main.go:330 msg="Listening on address" address=:9115
Enable the service on boot:
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$ systemctl enable blackbox_exporter
Configure Prometheus
Next, we need to provide context to prometheus on what to monitor. We will inform prometheus to monitor a web endpoint on port 8080 using the blackbox exporter (we will create a python simplehttpserver to run on port 8080).
Edit the prometheus config /etc/prometheus/prometheus.yml and append the following:
To install a blackbox exporter dashboard: https://grafana.com/dashboards/7587, create a new dashboard, select import, provide the ID: 7587, select the prometheus datasource and select save.
The dashboard should look similar to this:
Next up, Alertmanager
In the next tutorial we will setup Alertmanager to alert when our endpoint goes down
So we are pushing our time series metrics into prometheus, and now we would like to alarm based on certain metric dimensions. That’s where alertmanager fits in. We can setup targets and rules, once rules for our targets does not match, we can alarm to destinations suchs as slack, email etc.
What we will be doing:
In our previous tutorial we installed blackbox exporter to probe a endpoint. Now we will install Alertmanager and configure an alert to notify us via email and slack when our endpoint goes down. See this post if you have not seen the previous tutorial.
So when we get alerted, our alert will include a link to our alert. We need to provide the base url of that alert. That get’s done in our alertmanager systemd unit file: /etc/systemd/system/alertmanager.service under --web.external-url passing the alertmanager base ip address:
Then we need to do the same with the prometheus systemd unit file: /etc/systemd/system/prometheus.service under --web.external-url passing the prometheus base ip address:
Inspect the status of alertmanager and prometheus:
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$ systemctl status alertmanager
$ systemctl status prometheus
If everything seems good, enable alertmanager on boot:
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$ systemctl enable alertmanager
Access Alertmanager:
Access alertmanager on your endpoint on port 9093:
From our previous tutorial we started a local web service on port 8080 that is being monitored by prometheus. Let’s stop that service to test out the alerting. You should get a notification via email:
And the notification via slack:
When you start the service again and head over to the prometheus ui under alerts, you will see that the service recovered:
Install Prometheus Alertmanager Plugin
Install the Prometheus Alertmanager Plugin in Grafana. Head to the instance where grafana is installed and install the plugin:
Install the dasboard grafana.com/dashboards/8010. Create a new datasource, select the prometheus-alertmanager datasource, configure and save.
Add a new dasboard, select import and provide the ID 8010, select the prometheus-alertmanager datasource and save. You should see the following (more or less):
Grafana is a Open Source Dashboarding service that allows you to monitor, analyze and graph metrics from datasources such as prometheus, influxdb, elasticsearch, aws cloudwatch, and many more.
Not only is grafana amazing, its super pretty!
Example of how a dashboard might look like:
What are we doing today
In this tutorial we will setup grafana on linux. If you have not set up prometheus, follow this blogpost to install prometheus.
Install Grafana
I will be demonstrating how to install grafana on debian, if you have another operating system, head over to grafana documentation for other supported operating systems.
In most cases when we want to scrape a node for metrics, we will install node-exporter on a host and configure prometheus to scrape the configured node to consume metric data. But in certain cases we want to push custom metrics to prometheus. In such cases, we can make use of pushgateway.
Pushgateway allows you to push custom metrics to push gateway’s endpoint, then we configure prometheus to scrape push gateway to consume the exposed metrics into prometheus.
Pre-Requirements
If you have not set up Prometheus, head over to this blogpost to set up prometheus on Linux.
What we will do?
In this tutorial, we will setup pushgateway on linux and after pushgateway has been setup, we will push some custom metrics to pushgateway and configure prometheus to scrape metrics from pushgateway.
Install Pushgateway
Get the latest version of pushgateway from prometheus.io, then download and extract:
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$ wget https://github.com/prometheus/pushgateway/releases/download/v0.8.0/pushgateway-0.8.0.linux-amd64.tar.gz
$ tar -xvf pushgateway-0.8.0.linux-amd64.tar.gz
$ systemctl status pushgateway
pushgateway.service - Pushgateway
Loaded: loaded (/etc/systemd/system/pushgateway.service; disabled; vendor preset: enabled)
Active: active (running) since Tue 2019-05-07 09:05:57 UTC; 2min 33s ago
Main PID: 6974 (pushgateway)
Tasks: 6 (limit: 4704)
CGroup: /system.slice/pushgateway.service
└─6974 /usr/local/bin/pushgateway --web.listen-address=:9091 --web.telemetry-path=/metrics --persistence.file=/tmp/metric.store --persistence.interval=5m --log.level=info --log.format=logger:st
May 07 09:05:57 ip-172-31-41-126 systemd[1]: Started Pushgateway.
Configure Prometheus
Now we want to configure prometheus to scrape pushgateway for metrics, then the scraped metrics will be injected into prometheus’s time series database:
At the moment, I have prometheus, node-exporter and pushgateway on the same node so I will provide my complete prometheus configuration, If you are just looking for the pushgateway config, it will be the last line:
With this method, you can push any custom metrics (bash, lambda function, etc) to pushgateway and allow prometheus to consume that data into it’s time series database.
In this post we will setup a highly available mysql galera cluster on docker swarm.
About
The service is based of docker-mariadb-cluster repository and it’s designed not to have any persistent data attached to the service, but rely on the “nodes” to replicate the data.
Note, that however this proof of concept works, I always recommend to use a remote mysql database outside your cluster, such as RDS etc.
Since we don’t persist any data on the mysql cluster, I have associated a dbclient service that will run continious backups, which we will persist the path where the backups reside to disk.
The dbclient is configured to be in the same network as the cluster so it can reach the mysql service. The default behavior is that it will make a backup every hour (3600 seconds) to the /data/{date}/ path.
Deploy the stack:
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$ docker stack deploy -c docker-compose.yml galeraCreating network dbnetCreating service galera_dbclusterCreating service galera_dblbCreating service galera_dbclient
Have a look to see if all the services is running:
At the moment we only have 1 replica for our mysql cluster, let’s go ahead and scale the cluster to 3 replicas:
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$ docker service scale galera_dbcluster=3galera_dbcluster scaled to 3overall progress:3 out of 3 tasks1/3:running [==================================================>]2/3:running [==================================================>]3/3:running [==================================================>]verify:Service converged
$ docker exec -it $(docker ps -f name=galera_dbclient -q) mysql -uroot -ppassword -h dblb -e'select * from mydb.foo;'+------+| name |+------+| ruan |+------+
Simulate a Node Failure:
Simulate a node failure by killing one of the mysql containers:
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$ docker kill 9e336032ab52
Verify that one container is missing from our service:
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$ docker service lsID NAME MODE REPLICAS IMAGE PORTSp8kcr5y7szte galera_dbcluster replicated 2/3 toughiq/mariadb-cluster:latest
While the container is provisioning, as we have 2 out of 3 running containers, read the data 3 times so test that the round robin queries dont hit the affected container (the dblb wont route traffic to the affected container):
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$ docker exec -it $(docker ps -f name=galera_dbclient -q) mysql -uroot -ppassword -h dblb -e'select * from mydb.foo;'+------+| name |+------+| ruan |+------+$ docker exec -it $(docker ps -f name=galera_dbclient -q) mysql -uroot -ppassword -h dblb -e'select * from mydb.foo;'+------+| name |+------+| ruan |+------+$ docker exec -it $(docker ps -f name=galera_dbclient -q) mysql -uroot -ppassword -h dblb -e'select * from mydb.foo;'+------+| name |+------+| ruan |+------+
Verify that the 3rd container has checked in:
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$ docker service lsID NAME MODE REPLICAS IMAGE PORTSp8kcr5y7szte galera_dbcluster replicated 3/3 toughiq/mariadb-cluster:latest
How to Restore?
I’m deleting the database to simulate the scenario where we need to restore:
Vault’s transit secrets engine handles cryptographic functions on data-in-transit. Vault doesn’t store the data sent to the secrets engine, so it can also be viewed as encryption as a service.
In this tutorial we will demonstrate how to use Vault’s Transit Secret Engine.
