In this post we will setup a Docker Image for Traefik Proxy on the ARM Architecture, specifically on the Raspberry Pi, which we will deploy to our Raspberry Pi Docker Swarm.
Then we will build and push our image to a registry, then setup traefik and also setup a web application that sits behind our Traefik Proxy.
What is Traefik
Traefik is a modern load balancer and reverse proxy built for micro services.
Dockerfile
We will be running Traefik on Alpine 3.8:
1234567891011121314
FROM rbekker87/armhf-alpine:3.8
ENV TRAEFIK_VERSION 1.7.0-rc3
ENV ARCH arm
ADD https://github.com/containous/traefik/releases/download/v${TRAEFIK_VERSION}/traefik_linux-${ARCH} /traefik
RUN apk add --no-cache ca-certificates \&& chmod +x /traefik \&& rm -rf /var/cache/apk/*
EXPOSE808080443ENTRYPOINT["/traefik"]
Build and Push
Build and Push your image to your registry of choice:
Check if the services in your stack is running. Since our deploy mode was global, there will be a replica running on each node, and in my swarm I’ve got 3 nodes:
123
$ docker stack services proxy
ID NAME MODE REPLICAS IMAGE PORTS
16x31j7o0f0r proxy_traefik global 3/3 rbekker87/armhf-traefik:1.7.0-rc3 *:80->80/tcp,*:8080->8080/tcp
Deploy a Web Service hooked up to Traefik
Pre-Requirement:
To register subdomains on the fly, set you DNS for your domain to the following (im using pistack.co.za in this example):
pistack.co.zaAx.x.x.x
*.pistack.co.zaAx.x.x.x
Next, we will deploy we app that will be associated to our Traefik service domain, so we will inform Traefik that our web app fqdn and port that will be registered with the proxy.
In the above compose, you will notice that our traefik backend is set to our service name, our port is the port that the proxy will forward requests to the containers port, since the proxy and the whoami container is in the same network, they will be able to communicate with each other. Then we also have our frontend rule which will be the endpoint we will reach our application on.
Deploy the stack:
12
$ docker stack deploy -c whoami.yml web
Creating service web_whoami
List the tasks running in our web stack:
123
$ docker stack services web
ID NAME MODE REPLICAS IMAGE PORTS
31ylfcfb7uyw web_whoami replicated 3/3 rbekker87/golang-whoami:alpine-amrhf
Once all the replicas is running, move along to test the application
Testing our Application:
I have 3 replicas each running on their own container, so each container will respond with its own hostname:
12345
$ docker service ps web_whoami
ID NAME IMAGE NODE DESIRED STATE CURRENT STATE ERROR PORTS
ivn8fgfosvgd web_whoami.1 rbekker87/golang-whoami:alpine-amrhf rpi-01 Running Running 26 minutes ago
rze6u6z56aop web_whoami.2 rbekker87/golang-whoami:alpine-amrhf rpi-02 Running Running 26 minutes ago
6fjua869r498 web_whoami.3 rbekker87/golang-whoami:alpine-amrhf rpi-04 Running Running 23 minutes ago
Hostname resolution to our Ghost Blog Service: In our swarm we have a service called blog which is associated to the docknet network, so the dns resolution will resolve to the vip of the service. As seen in the figure below:
123
$ docker service ls
ID NAME MODE REPLICAS IMAGE PORTS
nq42a6jfwx3d blog replicated 1/1 rbekker87/armhf-ghost:2.0.3
$ docker service ls
ID NAME MODE REPLICAS IMAGE PORTS
je7x21l7egoh nginx_proxy replicated 1/1 registry.gitlab.com/user/docker/arm-nginx:caching *:80->80/tcp
nq42a6jfwx3d blog replicated 1/1 rbekker87/armhf-ghost:2.0.3
Once you access your proxy on port 80, you should see your Ghost Blog Homepage like below:
I had my Ghost Blog listening on port 2368 and exposing port 80 on Docker so that the port translation directs port 80 traffic to port 2368 on Ghost directly.
Alex responded on my tweet and introduced Nginx Caching:
With this approach benchmarking results was not so great in terms of requests per second, and as this hostname will be only used for a blog, its a great idea to cache the content, this was achieved with the help from Alex’s blog: blog.alexellis.io/save-and-boost-with-nginx/
How Nginx was Configured:
I have a blogpost on how I setup Nginx on an Alpine Image, where I setup caching and proxy-pass the connections through to my ghost blog.
Benchmarking: Before Nginx with Caching was Implemented:
When doing an apache benchmark I got 9.31 requests per second performing the test on my LAN:
As the curious person that I am, I like to play around with new stuff that I stumble upon, and one of them was having a docker swarm cluster running on 3 Raspberry Pi’s on my LAN.
The idea is to have 3 Raspberry Pi’s (Model 3 B), a Manager Node, and 2 Worker Nodes, each with a 32 GB SanDisk SD Card, which I will also be part of a 3x Replicated GlusterFS Volume that will come in handy later for some data that needs persistent data.
If you have an internal DNS Server, set an A Record for each node, or for simplicity, set your hosts file on each node so that your hostname for each node responds to it’s provisioned IP Address:
Time to set up our swarm. As we have more than one network interface, we will need to setup our swarm by specifying the IP Address of our network interface that is accessible from our LAN:
Now that we have our IP Address, initialize the swarm on the manager node:
12345678910
pi@rpi-01:~ $ docker swarm init --advertise-addr 192.168.0.2
Swarm initialized: current node (siqyf3yricsvjkzvej00a9b8h) is now a manager.
To add a worker to this swarm, run the following command:
docker swarm join \ --token SWMTKN-1-0eith07xkcg93lzftuhjmxaxwfa6mbkjsmjzb3d3sx9cobc2zp-97s6xzdt27y2gk3kpm0cgo6y2 \ 192.168.0.2:2377
To add a manager to this swarm, run 'docker swarm join-token manager' and follow the instructions.
Then from rpi-02 join the manager node of the swarm:
12
pi@rpi-02:~ $ docker swarm join --token SWMTKN-1-0eith07xkcg93lzftuhjmxaxwfa6mbkjsmjzb3d3sx9cobc2zp-97s6xzdt27y2gk3kpm0cgo6y2 192.168.0.2:2377
This node joined a swarm as a worker.
Then from rpi-03 join the manager node of the swarm:
12
pi@rpi-03:~ $ docker swarm join --token SWMTKN-1-0eith07xkcg93lzftuhjmxaxwfa6mbkjsmjzb3d3sx9cobc2zp-97s6xzdt27y2gk3kpm0cgo6y2 192.168.0.2:2377
This node joined a swarm as a worker.
Then from the manager node: rpi-01, ensure that the nodes are checked in:
12345
pi@rpi-01:~ $ docker node ls
ID HOSTNAME STATUS AVAILABILITY MANAGER STATUS
62s7gx1xdm2e3gp5qoca2ru0d rpi-03 Ready Active
6fhyfy9yt761ar9pl84dkxck3 * rpi-01 Ready Active Leader
pg0nyy9l27mtfc13qnv9kywe7 rpi-02 Ready Active
Setting Up a Replicated GlusterFS Volume
I have decided to setup a replicated glusterfs volume to have data replicated throughout the cluster if I would like to have some persistent data. From each node, install the GlusterFS Client and Server:
Then your GlusterFS Volume will be mounted on all the nodes, and when a file is written to the /mnt/ partition, data will be replicated to all the nodes in the Cluster:
Docker Swarm’s Routing mesh takes care of the internal routing, so requests will respond even if the container is not running on the node that you are making the request against.
With that said, verifying on which node our service is running:
123
pi@rpi-01:~ $ docker service ps web
ID NAME IMAGE NODE DESIRED STATE CURRENT STATE ERROR PORTS
sd67cd18s5m0 web.1 hypriot/rpi-busybox-httpd:latest rpi-02 Running Running 2 minutes ago
When we make a HTTP Request to one of these Nodes IP Addresses, our request will be responded with this awesome static page:
We can see we only have one container in our swarm, let’s scale that up to 3 containers:
12
pi@rpi-01:~ $ docker service scale web01=3
web01 scaled to 3
Now that the service is scaled to 3 containers, requests will be handled using the round-robin algorithm. To ensured that the service scaled, we will see that we will have 3 replicas:
123
pi@rpi-01:~ $ docker service ls
ID NAME MODE REPLICAS IMAGE PORTS
vsvyanuw6q6y web replicated 3/3 hypriot/rpi-busybox-httpd:latest *:891->80/tcp
Verifying where these containers are running on:
12345
pi@rpi-01:~ $ docker service ps web01
ID NAME IMAGE NODE DESIRED STATE CURRENT STATE ERROR PORTS
sd67cd18s5m0 web.1 hypriot/rpi-busybox-httpd:latest rpi-02 Running Running 2 minutes ago
ope3ya7hh9j4 web.2 hypriot/rpi-busybox-httpd:latest rpi-03 Running Running 30 seconds ago
07m1ww7ptxro web.3 hypriot/rpi-busybox-httpd:latest rpi-01 Running Running 28 seconds ago
Lastly, removing the service from our swarm:
12
pi@rpi-01:~ $ docker service rm web01
web01
Massive Thanks:
a Massive thanks to Alex Ellis for mentioning me on one of his blogposts:
The last couple of days I picked up on my ELK Stack a couple thousands of SSH Brute Force Attacks, so I decided I will just revisit my SSH Server configuration, and change my SSH Port to something else for the interim. The dashboard that showed me the results at that point in time:
Then I decided I actually would like to setup a SSH Honeypot to listen on Port 22 and change my SSH Server to listen on 222 and capture their IP Addresses, Usernames and Passwords that they are trying to use and dump it all in a file so that I can build up my own password dictionary :D
SSH Configuration:
Changing the SSH Port:
1
$ sudo vim /etc/ssh/sshd_config
Change the port to 222:
1
Port 222
Restart the SSH Server:
1
$ sudo /etc/init.d/ssh restart
Verify that the SSH Server is running on the new port:
I’m working on capturing some data that I want to use for analytics, and a big part of that is capturing the query string parameters that is in the request URL.
So essentially I would like to break the data up into key value pairs, using Python and the urllib module, which will then pushed into a database like MongoDB or DynamoDB.
Our URL:
So the URL’s that we will have, will more or less look like the following:
So we have documents ingested into Elasticsearch, and one of the fields has a IP Address, but at this moment it’s just an IP Address, the goal is to have more information from this IP Address, so that we can use Kibana’s Coordinate Maps to map our data on a Geographical Map.
In order to do this we need to make use of the GeoIP Ingest Processor Plugin, which adds information about the grographical location of the IP Address that it receives. This information is retrieved from the Maxmind Datases.
So when we pass our IP Address through the processor, for example one of Github’s IP Addresses: 192.30.253.113 we will in return get:
While testing DynamoDB for a specific use case I picked up at times where a GetItem will incur about 150ms in RequestLatency on the Max Statistic. This made me want to understand the behavior that I’m observing.
I will go through my steps drilling down on pointers where latency can be reduced.
DynamoDB Performance Testing Overview
Tests:
Create 2 Tables with 10 WCU / 10 RCU, one encrypted, one non-encrypted
Your database is getting hammered with requests and building up some load over time and we would like to place a caching layer in front of our database that will return data from the caching layer, to reduce some traffic to our database and also improve our performance for our application.
The Scenario:
Our scenario will be very simple for this demonstration:
Database will be using SQLite with product information (product_name, product_description)
Caching Layer will be Memcached
Our Client will be written in Python, which checks if the product name is in cache, if not a GET_MISS will be returned, then the data will be fetched from the database, returns it to the client and save it to the cache
Next time the item will be read, a GET_HIT will be received, then the item will be delivered to the client directly from the cache
SQL Database:
As mentioned we will be using sqlite for demonstration.
Create the table, populate some very basic data:
12345678
$sqlite3db.sql-header-columnimportsqlite3assqlSQLiteversion3.16.02016-11-0419:09:39Enter".help"forusagehints.sqlite>createtableproducts(product_nameSTRING(32),product_descriptionSTRING(32));sqlite>insertintoproductsvalues('apple','fruit called apple');sqlite>insertintoproductsvalues('guitar','musical instrument');
importsqlite3assqlfrompymemcache.clientimportbaseproduct_name='guitar'client=base.Client(('localhost',11211))result=client.get(product_name)defquery_db(product_name):db_connection=sql.connect('db.sql')c=db_connection.cursor()try:c.execute('select product_description from products where product_name = "{k}"'.format(k=product_name))data=c.fetchone()[0]db_connection.close()except:data='invalid'returndataifresultisNone:print("got a miss, need to get the data from db")result=query_db(product_name)ifresult=='invalid':print("requested data does not exist in db")else:print("returning data to client from db")print("=> Product: {p}, Description: {d}".format(p=product_name,d=result))print("setting the data to memcache")client.set(product_name,result)else:print("got the data directly from memcache")print("=> Product: {p}, Description: {d}".format(p=product_name,d=result))
Explanation:
We have a function that takes a argument of the product name, that makes the call to the database and returns the description of that product
We will make a get operation to memcached, if nothing is returned, then we know the item does not exists in our cache,
Then we will call our function to get the data from the database and return it directly to our client, and
Save it to the cache in memcached so the next time the same product is queried, it will be delivered directly from the cache
The Demo:
Our Product Name is guitar, lets call the product, which will be the first time so memcached wont have the item in its cache:
12345
$ python app.py
got a miss, need to get the data from db
returning data to client from db=> Product: guitar, Description: musical instrument
setting the data to memcache
Now from the output, we can see that the item was delivered from the database and saved to the cache, lets call that same product and observe the behavior:
123
$ python app.py
got the data directly from memcache=> Product: guitar, Description: musical instrument
When our cache instance gets rebooted we will lose our data that is in the cache, but since the source of truth will be in our database, data will be re-added to the cache as they are requested. That is one good reason not to rely on a cache service to be your primary data source.
What if the product we request is not in our cache or database, let’s say the product tree
123
$ python app.py
got a miss, need to get the data from db
requested data does not exist in db
This was a really simple scenario, but when working with masses amount of data, you can benefit from a lot of performance using caching.
