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-<!--
-title: "Netdata, Prometheus, Grafana stack"
-custom_edit_url: https://github.com/netdata/netdata/edit/master/backends/WALKTHROUGH.md
--->
-
-# Netdata, Prometheus, Grafana stack
-
-## Intro
-
-In this article I will walk you through the basics of getting Netdata, Prometheus and Grafana all working together and
-monitoring your application servers. This article will be using docker on your local workstation. We will be working
-with docker in an ad-hoc way, launching containers that run ‘/bin/bash’ and attaching a TTY to them. I use docker here
-in a purely academic fashion and do not condone running Netdata in a container. I pick this method so individuals
-without cloud accounts or access to VMs can try this out and for it’s speed of deployment.
-
-## Why Netdata, Prometheus, and Grafana
-
-Some time ago I was introduced to Netdata by a coworker. We were attempting to troubleshoot python code which seemed to
-be bottlenecked. I was instantly impressed by the amount of metrics Netdata exposes to you. I quickly added Netdata to
-my set of go-to tools when troubleshooting systems performance.
-
-Some time ago, even later, I was introduced to Prometheus. Prometheus is a monitoring application which flips the normal
-architecture around and polls rest endpoints for its metrics. This architectural change greatly simplifies and decreases
-the time necessary to begin monitoring your applications. Compared to current monitoring solutions the time spent on
-designing the infrastructure is greatly reduced. Running a single Prometheus server per application becomes feasible
-with the help of Grafana.
-
-Grafana has been the go to graphing tool for… some time now. It’s awesome, anyone that has used it knows it’s awesome.
-We can point Grafana at Prometheus and use Prometheus as a data source. This allows a pretty simple overall monitoring
-architecture: Install Netdata on your application servers, point Prometheus at Netdata, and then point Grafana at
-Prometheus.
-
-I’m omitting an important ingredient in this stack in order to keep this tutorial simple and that is service discovery.
-My personal preference is to use Consul. Prometheus can plug into consul and automatically begin to scrape new hosts
-that register a Netdata client with Consul.
-
-At the end of this tutorial you will understand how each technology fits together to create a modern monitoring stack.
-This stack will offer you visibility into your application and systems performance.
-
-## Getting Started - Netdata
-
-To begin let’s create our container which we will install Netdata on. We need to run a container, forward the necessary
-port that Netdata listens on, and attach a tty so we can interact with the bash shell on the container. But before we do
-this we want name resolution between the two containers to work. In order to accomplish this we will create a
-user-defined network and attach both containers to this network. The first command we should run is:
-
-```sh
-docker network create --driver bridge netdata-tutorial
-```
-
-With this user-defined network created we can now launch our container we will install Netdata on and point it to this
-network.
-
-```sh
-docker run -it --name netdata --hostname netdata --network=netdata-tutorial -p 19999:19999 centos:latest '/bin/bash'
-```
-
-This command creates an interactive tty session (-it), gives the container both a name in relation to the docker daemon
-and a hostname (this is so you know what container is which when working in the shells and docker maps hostname
-resolution to this container), forwards the local port 19999 to the container’s port 19999 (-p 19999:19999), sets the
-command to run (/bin/bash) and then chooses the base container images (centos:latest). After running this you should be
-sitting inside the shell of the container.
-
-After we have entered the shell we can install Netdata. This process could not be easier. If you take a look at [this
-link](/packaging/installer/README.md), the Netdata devs give us several one-liners to install Netdata. I have not had
-any issues with these one liners and their bootstrapping scripts so far (If you guys run into anything do share). Run
-the following command in your container.
-
-```sh
-bash <(curl -Ss https://my-netdata.io/kickstart.sh) --dont-wait
-```
-
-After the install completes you should be able to hit the Netdata dashboard at <http://localhost:19999/> (replace
-localhost if you’re doing this on a VM or have the docker container hosted on a machine not on your local system). If
-this is your first time using Netdata I suggest you take a look around. The amount of time I’ve spent digging through
-/proc and calculating my own metrics has been greatly reduced by this tool. Take it all in.
-
-Next I want to draw your attention to a particular endpoint. Navigate to
-<http://localhost:19999/api/v1/allmetrics?format=prometheus&help=yes> In your browser. This is the endpoint which
-publishes all the metrics in a format which Prometheus understands. Let’s take a look at one of these metrics.
-`netdata_system_cpu_percentage_average{chart="system.cpu",family="cpu",dimension="system"} 0.0831255 1501271696000` This
-metric is representing several things which I will go in more details in the section on prometheus. For now understand
-that this metric: `netdata_system_cpu_percentage_average` has several labels: (chart, family, dimension). This
-corresponds with the first cpu chart you see on the Netdata dashboard.
-
-![](https://github.com/ldelossa/NetdataTutorial/raw/master/Screen%20Shot%202017-07-28%20at%204.00.45%20PM.png)
-
-This CHART is called ‘system.cpu’, The FAMILY is cpu, and the DIMENSION we are observing is “system”. You can begin to
-draw links between the charts in Netdata to the prometheus metrics format in this manner.
-
-## Prometheus
-
-We will be installing prometheus in a container for purpose of demonstration. While prometheus does have an official
-container I would like to walk through the install process and setup on a fresh container. This will allow anyone
-reading to migrate this tutorial to a VM or Server of any sort.
-
-Let’s start another container in the same fashion as we did the Netdata container.
-
-```sh
-docker run -it --name prometheus --hostname prometheus
---network=netdata-tutorial -p 9090:9090 centos:latest '/bin/bash'
-```
-
-This should drop you into a shell once again. Once there quickly install your favorite editor as we will be editing
-files later in this tutorial.
-
-```sh
-yum install vim -y
-```
-
-Prometheus provides a tarball of their latest stable versions [here](https://prometheus.io/download/).
-
-Let’s download the latest version and install into your container.
-
-```sh
-cd /tmp && curl -s https://api.github.com/repos/prometheus/prometheus/releases/latest \
-| grep "browser_download_url.*linux-amd64.tar.gz" \
-| cut -d '"' -f 4 \
-| wget -qi -
-
-mkdir /opt/prometheus
-
-sudo tar -xvf /tmp/prometheus-*linux-amd64.tar.gz -C /opt/prometheus --strip=1
-```
-
-This should get prometheus installed into the container. Let’s test that we can run prometheus and connect to it’s web
-interface.
-
-```sh
-/opt/prometheus/prometheus
-```
-
-Now attempt to go to <http://localhost:9090/>. You should be presented with the prometheus homepage. This is a good
-point to talk about Prometheus’s data model which can be viewed here: <https://prometheus.io/docs/concepts/data_model/>
-As explained we have two key elements in Prometheus metrics. We have the ‘metric’ and its ‘labels’. Labels allow for
-granularity between metrics. Let’s use our previous example to further explain.
-
-```conf
-netdata_system_cpu_percentage_average{chart="system.cpu",family="cpu",dimension="system"} 0.0831255 1501271696000
-```
-
-Here our metric is ‘netdata_system_cpu_percentage_average’ and our labels are ‘chart’, ‘family’, and ‘dimension. The
-last two values constitute the actual metric value for the metric type (gauge, counter, etc…). We can begin graphing
-system metrics with this information, but first we need to hook up Prometheus to poll Netdata stats.
-
-Let’s move our attention to Prometheus’s configuration. Prometheus gets it config from the file located (in our example)
-at `/opt/prometheus/prometheus.yml`. I won’t spend an extensive amount of time going over the configuration values
-documented here: <https://prometheus.io/docs/operating/configuration/>. We will be adding a new“job” under the
-“scrape_configs”. Let’s make the “scrape_configs” section look like this (we can use the dns name Netdata due to the
-custom user-defined network we created in docker beforehand).
-
-```yaml
-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: 'netdata'
-
- metrics_path: /api/v1/allmetrics
- params:
- format: [ prometheus ]
-
- static_configs:
- - targets: ['netdata:19999']
-```
-
-Let’s start prometheus once again by running `/opt/prometheus/prometheus`. If we now navigate to prometheus at
-‘<http://localhost:9090/targets’> we should see our target being successfully scraped. If we now go back to the
-Prometheus’s homepage and begin to type ‘netdata\_’ Prometheus should auto complete metrics it is now scraping.
-
-![](https://github.com/ldelossa/NetdataTutorial/raw/master/Screen%20Shot%202017-07-28%20at%205.13.43%20PM.png)
-
-Let’s now start exploring how we can graph some metrics. Back in our Netdata container lets get the CPU spinning with a
-pointless busy loop. On the shell do the following:
-
-```sh
-[root@netdata /]# while true; do echo "HOT HOT HOT CPU"; done
-```
-
-Our Netdata cpu graph should be showing some activity. Let’s represent this in Prometheus. In order to do this let’s
-keep our metrics page open for reference: <http://localhost:19999/api/v1/allmetrics?format=prometheus&help=yes> We are
-setting out to graph the data in the CPU chart so let’s search for “system.cpu”in the metrics page above. We come across
-a section of metrics with the first comments `# COMMENT homogeneous chart "system.cpu", context "system.cpu", family
-"cpu", units "percentage"` Followed by the metrics. This is a good start now let us drill down to the specific metric we
-would like to graph.
-
-```conf
-# COMMENT
-netdata_system_cpu_percentage_average: dimension "system", value is percentage, gauge, dt 1501275951 to 1501275951 inclusive
-netdata_system_cpu_percentage_average{chart="system.cpu",family="cpu",dimension="system"} 0.0000000 1501275951000
-```
-
-Here we learn that the metric name we care about is‘netdata_system_cpu_percentage_average’ so throw this into Prometheus
-and see what we get. We should see something similar to this (I shut off my busy loop)
-
-![](https://github.com/ldelossa/NetdataTutorial/raw/master/Screen%20Shot%202017-07-28%20at%205.47.53%20PM.png)
-
-This is a good step toward what we want. Also make note that Prometheus will tag on an ‘instance’ label for us which
-corresponds to our statically defined job in the configuration file. This allows us to tailor our queries to specific
-instances. Now we need to isolate the dimension we want in our query. To do this let us refine the query slightly. Let’s
-query the dimension also. Place this into our query text box.
-`netdata_system_cpu_percentage_average{dimension="system"}` We now wind up with the following graph.
-
-![](https://github.com/ldelossa/NetdataTutorial/raw/master/Screen%20Shot%202017-07-28%20at%205.54.40%20PM.png)
-
-Awesome, this is exactly what we wanted. If you haven’t caught on yet we can emulate entire charts from Netdata by using
-the `chart` dimension. If you’d like you can combine the ‘chart’ and ‘instance’ dimension to create per-instance charts.
-Let’s give this a try: `netdata_system_cpu_percentage_average{chart="system.cpu", instance="netdata:19999"}`
-
-This is the basics of using Prometheus to query Netdata. I’d advise everyone at this point to read [this
-page](/backends/prometheus/README.md#using-netdata-with-prometheus). The key point here is that Netdata can export metrics from
-its internal DB or can send metrics “as-collected” by specifying the ‘source=as-collected’ url parameter like so.
-<http://localhost:19999/api/v1/allmetrics?format=prometheus&help=yes&types=yes&source=as-collected> If you choose to use
-this method you will need to use Prometheus's set of functions here: <https://prometheus.io/docs/querying/functions/> to
-obtain useful metrics as you are now dealing with raw counters from the system. For example you will have to use the
-`irate()` function over a counter to get that metric's rate per second. If your graphing needs are met by using the
-metrics returned by Netdata's internal database (not specifying any source= url parameter) then use that. If you find
-limitations then consider re-writing your queries using the raw data and using Prometheus functions to get the desired
-chart.
-
-## Grafana
-
-Finally we make it to grafana. This is the easiest part in my opinion. This time we will actually run the official
-grafana docker container as all configuration we need to do is done via the GUI. Let’s run the following command:
-
-```sh
-docker run -i -p 3000:3000 --network=netdata-tutorial grafana/grafana
-```
-
-This will get grafana running at ‘<http://localhost:3000/’> Let’s go there and
-
-login using the credentials Admin:Admin.
-
-The first thing we want to do is click ‘Add data source’. Let’s make it look like the following screenshot
-
-![](https://github.com/ldelossa/NetdataTutorial/raw/master/Screen%20Shot%202017-07-28%20at%206.36.55%20PM.png)
-
-With this completed let’s graph! Create a new Dashboard by clicking on the top left Grafana Icon and create a new graph
-in that dashboard. Fill in the query like we did above and save.
-
-![](https://github.com/ldelossa/NetdataTutorial/raw/master/Screen%20Shot%202017-07-28%20at%206.39.38%20PM.png)
-
-## Conclusion
-
-There you have it, a complete systems monitoring stack which is very easy to deploy. From here I would begin to
-understand how Prometheus and a service discovery mechanism such as Consul can play together nicely. My current prod
-deployments automatically register Netdata services into Consul and Prometheus automatically begins to scrape them. Once
-achieved you do not have to think about the monitoring system until Prometheus cannot keep up with your scale. Once this
-happens there are options presented in the Prometheus documentation for solving this. Hope this was helpful, happy
-monitoring.
-
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