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Set up your LMA stack

Note:
This documentation has moved to a new home! Please update your bookmarks to the new URL for the up-to-date version of this page.

LMA to COS
The LMA stack is being succeeded by the Canonical Observability Stack (COS). While the current LMA still works, most users are recommended to consider COS instead. For more information, refer to this COS topic. In environments with more limited resources, there is also COS lite.

Logging, Monitoring, and Alerting (LMA) is a collection of tools that guarantee the availability of your running infrastructure. Your LMA stack will help point out issues in load, networking, and other resources before they become a failure point.

Architectural overview

Canonical’s LMA stack involves several discrete software services acting in concert.

Telegraf collects metrics from the operating system, running software, and other inputs. Its plugin system permits export of data in any arbitrary format; for this system we collect the data in a central data manager called Prometheus.

Prometheus works as a hub, polling data from different Telegraf nodes and sending it to various outputs, including persistent storage. For this LMA stack, visualisation is handled via Grafana and email/pager alerts are generated via the Prometheus Alertmanager plugin.

Getting started

Let’s set up a basic demonstration with two nodes, the first acting as a placeholder load with Telegraf installed - the “Workload”, and the second acting as our data visualisation system - the “Monitor”. This will help us familiarise ourselves with the various components and how they inter-operate.

Note:
For clarity, we’ll refer to these two hosts as named: workload and monitor. If you use other hostnames, substitute your preferred names as we go through this guide.

The Workload node will be running Telegraf to collect metrics from whatever load we’re monitoring. For demonstration purposes we’ll just read the CPU/memory data from the node. In a real environment, we’d have multiple hosts (each with their own Telegraf instance) collecting hardware, network, and software statuses particular to that node.

Our Monitor node will double as both a data store and a web UI, receiving data from the Workload, storing it to disk, and displaying it for analysis.

Ports

As reference, here are the ports we’ll be binding for each service:

Prometheus monitor:9090
Alertmanager monitor:9093
Grafana monitor:3000
Telegraf workload:9273

Set up the Workload node

First, let’s set up the Workload. We’ll be using LXD as our container technology in this guide, but any VM, container, or bare metal host should work, so long as it’s running Ubuntu 20.10. With LXD installed on our host we can use its lxc command line tool to create our containers:

$ lxc launch ubuntu:20.10 workload
Creating workload
Starting workload

$ lxc exec workload -- bash
workload:~#

On the Workload, install Telegraf:

workload:~# apt update
workload:~# apt install telegraf

Telegraf processes input data to transform, filter, and decorate it, and then performs selected aggregation functions on it such as tallies, averages, etc. The results are published for collection by external services; in our case Prometheus will be collecting the CPU/memory data from the Monitor node.

Open /etc/telegraf/telegraf.conf and scroll down to the “INPUT PLUGINS” section. What we’ll need is the following configuration settings, which you should find already enabled by default:

[[inputs.cpu]]
  percpu = true
  totalcpu = true
  collect_cpu_time = false
  report_active = false

Looking at the config file you’ll notice it’s almost entirely commented out. There are three different types of sections in the file: [[inputs]], which we set above; [[outputs]], which we’ll set up next; and the [[agent]] setting, with several performance tuning parameters such as the collection interval, which we’re setting to 10 seconds. The agent defaults are fine for our example and for basic use.

Finally, we need to define where Telegraf will provide its output. Open /etc/telegraf/telegraf.conf and scroll down to the “OUTPUT PLUGINS” section and add the following output configuration:

[[outputs.prometheus_client]]
  listen = "workload:9273"
  metric_version = 2

#[[outputs.influxdb]]

We won’t be using Influxdb, so you can comment that section out (if it’s enabled).

Now restart the Telegraf service:

workload:~# systemctl restart telegraf
workload:~# systemctl status telegraf
● telegraf.service - The plugin-driven server agent for reporting metrics into InfluxDB
	 Loaded: loaded (/lib/systemd/system/telegraf.service; enabled; vendor preset: enabled)
	 Active: active (running) since Sat 2020-10-31 02:17:57 UTC; 6s ago
	   Docs: https://github.com/influxdata/telegraf
   Main PID: 2562 (telegraf)
	  Tasks: 17 (limit: 77021)
	 Memory: 42.2M
	 CGroup: /system.slice/telegraf.service
			 └─2562 /usr/bin/telegraf -config /etc/telegraf/telegraf.conf -config-directory /etc/telegraf/telegraf.d

...I! Loaded inputs: swap system cpu disk diskio kernel mem processes
...I! Loaded outputs: http prometheus_client
...I! [agent] Config: Interval:10s, Quiet:false, Hostname:"workload", Flush Interval:10s
...I! [outputs.prometheus_client] Listening on http://127.0.0.1:9273/metrics

Verify that it is collecting metrics by connecting to Telegraf’s web interface:

workload:~# wget -O- http://workload:9273/metrics

# HELP cpu_usage_guest Telegraf collected metric
# TYPE cpu_usage_guest gauge
cpu_usage_guest{cpu="cpu-total",host="workload"} 0
cpu_usage_guest{cpu="cpu0",host="workload"} 0
cpu_usage_guest{cpu="cpu1",host="workload"} 0
cpu_usage_guest{cpu="cpu10",host="workload"} 0
...
cpu_usage_idle{cpu="cpu-total",host="workload"} 92.74914376428686
cpu_usage_idle{cpu="cpu0",host="workload"} 86.72897196325539
cpu_usage_idle{cpu="cpu1",host="workload"} 90.11857707405758
cpu_usage_idle{cpu="cpu10",host="workload"} 95.95141700494543

Set up the Monitor node

Now let’s create the Monitor. As before, we’ll be using LXD as the container technology but feel free to adapt these steps to your chosen alternative:

$ lxc launch ubuntu:20.10 monitor
Creating monitor
Starting monitor
$ lxc exec monitor -- bash
monitor:~#

Make a note of the newly created container’s IP address, which we’ll need later on;

monitor:~# ip addr | grep 'inet .* global'
inet 10.69.244.104/24 brd 10.69.244.255 scope global dynamic eth0

Verify the Workload’s Telegraf instance can be reached from the Monitor:

monitor:~# wget -O- http://workload:9273/metrics

We’ll be setting up a few components to run on this node using their respective Snap packages. LXD images should normally have snap pre-installed, but if not, install it manually:

monitor:~# apt install snapd

Install Prometheus

Prometheus will be our data manager. It collects data from external sources – Telegraf in our case – and distributes it to various destinations such as email/pager alerts, web UIs, API clients, remote storage services, etc. We’ll get into those shortly.

Let’s install Prometheus itself, and the Prometheus Alertmanager plugin for alerts, along with the required dependencies:

monitor:~# snap install prometheus
monitor:~# snap install prometheus-alertmanager

The snap will automatically configure and start the service. To verify this, run:

monitor:~# snap services
Service                Startup  Current   Notes
lxd.activate           enabled  inactive  -
lxd.daemon             enabled  inactive  socket-activated
prometheus.prometheus  enabled  active    -
prometheus-alertmanager.alertmanager  enabled  active    -

Verify that Prometheus is listening on the port as we expect:

visualizer:~# ss -tulpn | grep prometheus
tcp    LISTEN  0      128                     *:9090               *:*      users:(("prometheus",pid=618,fd=8))

journalctl can be also used to review the state of Snap services if more detail is needed. For example, to see where Prometheus is loading its config from:

monitor:~# journalctl | grep "prometheus.*config"
...
...msg="Completed loading of configuration file" filename=/var/snap/prometheus/32/prometheus.yml

Although the file name points to a specific Snap revision (32, in this case), we can use the generic config file /var/snap/prometheus/current/prometheus.yml here in order to make things more general. Edit this config file to register the targets we’ll be reading data from. This will go under the scrape_configs section of the file:

scrape_configs:
  # The job name is added as a label `job=<job_name>` to any timeseries scraped from this config.
  - job_name: 'prometheus'

	# metrics_path defaults to '/metrics'
	# scheme defaults to 'http'.

	static_configs:
	- targets: ['localhost:9090']

  - job_name: 'telegraf'
	static_configs:
	- targets: ['workload:9273']

Then restart Prometheus:

monitor:~# snap restart prometheus

While we’ll be using Grafana for visualisation, Prometheus also has a web interface for viewing and interacting with the collected data. At this stage, we can load it to verify that our setup is working properly. In a web browser, navigate to the Monitor’s IP address, and port 9090. You should see Prometheus’ interface, as in the following image:

prometheus_0

In the entry box, enter cpu_usage_system, select the “Graph” tab and click “Execute”. This should show a graph of our collected CPU data so far. Prometheus also has a secondary web UI using React.js.

prometheus_1 prometheus_2

Configure Alertmanager

Let’s tackle the Alert Manager next. Edit /var/snap/prometheus/current/prometheus.yml again, adding the following to the alerting and rules_files sections:

## /var/snap/prometheus/current/prometheus.yml
#...
# Alertmanager configuration
alerting:
  alertmanagers:
  - static_configs:
	- targets:
	  - 127.0.0.1:9093
rule_files:
  - 'alerts.yml'

Now create /var/snap/prometheus/current/alerts.yml with the following contents:

## /var/snap/prometheus/current/alerts.yml
groups:
- name: demo-alerts
  rules:
  - alert: HighLoad
	expr: node_load1 > 2.0
	for: 60m
	labels:
	  severity: normal
	annotations:
	  description: '{{ $labels.instance }} of job {{ $labels.job }} is under high load.'
	  summary: Instance {{ $labels.instance }} under high load.
	  value: '{{ $value }}'

  - alert: InstanceDown
	expr: up == 0
	for: 5m
	labels:
	  severity: major
	annotations:
	  summary: "Instance {{ $labels.instance }} down"
	  description: "{{ $labels.instance }} of job {{ $labels.job }} has been down for more than 5 minutes."

This adds two alerts: one for high processor load, and one to report if the node has been unreachable for over 5 minutes. We’re considering high CPU to be a load of 2 or higher for an hour; this would need to be set to something more sensible for the style of workloads your production system experiences.

With the alerts themselves now defined, we next need to instruct Alertmanager how to handle them. There is a sample configuration installed to /var/snap/prometheus-alertmanager/current/alertmanager.yml, however it’s full of example data. Instead, replace it entirely with this content:

## /var/snap/prometheus-alertmanager/current/alertmanager.yml
global:
  resolve_timeout: 5m

route:
  group_by: ['alertname']
  group_wait: 10s
  group_interval: 10s
  repeat_interval: 1h

inhibit_rules:
  - source_match:
	  severity: 'critical'
	target_match:
	  severity: 'warning'
	equal: ['alertname', 'dev', 'instance']

Restart Alertmanager after making the configuration change:

workload:~# snap restart prometheus-alertmanager

Install Grafana

Grafana provides our main dashboard, from which we can generate graphs and other visuals to study the collected metrics. Grafana can read its data directly from log files, but we’ll focus on using Prometheus as its principle data source. Grafana is available as a Snap and can be installed like this:

monitor:~# snap install grafana
grafana 6.7.4 from Alvaro Uría (aluria) installed

It uses port 3000:

# ss -tulpn | grep grafana
tcp    LISTEN  0      128                     *:3000               *:*      users:(("grafana-server",pid=1449,fd=10))

We next need to know where it expects its configuration:

monitor:~# journalctl | grep "grafana.*conf"
... msg="Config loaded from" logger=settings file=/snap/grafana/36/conf/defaults.ini
... msg="Config overridden from Environment variable" logger=settings var="GF_PATHS_PROVISIONING=/var/snap/grafana/common/conf/provisioning"
... error="open /var/snap/grafana/common/conf/provisioning/datasources: no such file or directory"
...

We can see it is getting its defaults from /snap/grafana/36/conf/, but /snap/ is a read-only directory and therefore we cannot edit the file. Instead, we should put our customisations inside /var/snap/grafana/36/conf/grafana.ini. You can also use the generic path /var/snap/grafana/current/conf/grafana.ini.

For a production installation, the defaults.ini has numerous parameters we’d want to customise for our site, however for the demo we’ll accept all the defaults. We do need to configure our data sources, but can do this via the web interface:

$ firefox http://10.69.244.104:3000

Log in with ‘admin’ and ‘admin’ as the username and password. This should bring you to the main Grafana page, where you can find links to tutorials and documentation. Delete any example data sources and/or dashboards.

grafana_0

Select the button to add a new data source and select “Prometheus”. On the “Data Sources / Prometheus” edit page, set:

  • the name to Prometheus
  • the URL to http://localhost:9090
  • ‘Access’ to “Server (default)” to make Grafana pull data from the Prometheus service we set up.

The remaining settings can be left as defaults. Click “Save & Test”.

grafana_1 grafana_2

Returning to the Grafana home page, next set up a “New Dashboard”. A dashboard can hold one or more panels, each of which can be connected to one or more data queries. Let’s add a panel for CPU data. For the query, enter “cpu_usage_system” in the Metrics field.

grafana_3 grafana_4 grafana_5

On the left you can see four buttons to configure four elements of the panel: data source, visualisation, general settings, and alerts. The general settings page allows us to set a title for the panel, for instance. Make any other customisations you want, and then save the dashboard using the save icon at the top of the page.

grafana_6 grafana_7

Using the same procedure, add additional panels for processor load and memory usage. Panels can be used to present other types of data as well, such as numerical indicators, logs, newsfeeds, or markdown-formatted documentation. For example, you can add a panel to display the system uptime, such as in the following image:

grafana_9

Try also adding a panel with the “Text” visualisation option for entering descriptive text about our demo. Save, and then view the final dashboard:

grafana_X

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