Docker Networking Tip – Load balancing options in Docker

I had promised earlier that I will continue my Docker Networking Tip series. This is second in that series. The first one on Macvlan driver can be found here. In this presentation, I have covered different load balance options with Docker. Following topics are covered in this presentation:

• Overview of Service Discovery and Load balancing
• Service Discovery and Load balancing implementation in Docker
• Docker Load balancing use cases with Demo
  • Internal Load balancing
  • Ingress routing mesh Load balancing
  • Proxy load balancing with nginx
  • L7 load balancing with Traefik

Following is the associated Youtube video and presentation:

Docker Networking Tip – Load balancing options from Sreenivas Makam

I have put the use cases in github if you want to try it out.

If you think this is useful and would like to see more videos, please let me know. Based on the feedback received, I will try to create more Docker Networking tips in video format.

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Docker features for handling Container’s death and resurrection

Docker containers provides an isolated sandbox for the containerized program to execute. One-shot containers accomplishes a particular task and stops. Long running containers runs for an indefinite period till it either gets stopped by the user or when the root process inside container crashes. It is necessary to gracefully handle container’s death and to make sure that the Job running as container does not get impacted in an unexpected manner. When containers are run with Swarm orchestration, Swarm monitors the containers health, exit status and the entire lifecycle including upgrade and rollback. This will be a pretty long blog. I did not want to split it since it makes sense to look at this holistically. You can jump to specific sections by clicking on the links below if needed. In this blog, I will cover the following topics with examples:

• Handling Signals and exit codes
• Container restart policy
• Container health check
• Service restart with Swarm
• Service health check
• Service rolling upgrade and rollback

Handling Signals and exit codes

When we pass a signal to container using Docker CLI, Docker passes the signal to the main process running inside container(PID-1). This link has the list of all Linux signals. Docker exit codes follow the chroot exit standard for Docker defined exit codes. Other standard exit codes can come from the program running inside container. Container exit code can be seen from container events coming from Docker daemon when the container exits. For containers that have not been cleaned up, exit code can be found from “docker ps -a”.
Following is a sample “docker ps -a” output where nginx container exited with exit code 0. Here, I used “docker stop” to stop the container.

$ docker ps -a
CONTAINER ID        IMAGE                  COMMAND                  CREATED             STATUS                       PORTS               NAMES
32d675260384        nginx                  "nginx -g 'daemon ..."   18 seconds ago      Exited (0) 7 seconds ago                         web

Following is a sample “docker ps -a” output where nginx container exited with exit code 137. Here, I used “docker kill” to stop the container.

$ docker ps -a
CONTAINER ID        IMAGE                  COMMAND                  CREATED             STATUS                       PORTS               NAMES
9b5d8348cb89        nginx                  "nginx -g 'daemon ..."   11 seconds ago      Exited (137) 2 seconds ago                       web

Following is the list of standard and Docker defined exit codes:

0: Success
125: Docker run itself fails
126: Contained command cannot be invoked
127: Containerd command cannot be found
128 + n: Fatal error signal n:
130: (128+2) Container terminated by Control-C
137: (128+9) Container received a SIGKILL
143: (128+15) Container received a SIGTERM
255: Exit status out of range(-1)

Following is a simple Python program that handles Signals. This program will be run as Docker container to illustrate Docker signals and exit codes.

#!/usr/bin/python

import sys
import signal
import time

def signal_handler_int(sigid, frame):
    print "signal", sigid, ",", "Handling Ctrl+C/SIGINT!"
    sys.exit(signal.SIGINT)

def signal_handler_term(sigid, frame):
    print "signal", sigid, ",", "Handling SIGTERM!"
    sys.exit(signal.SIGTERM)

def signal_handler_usr(sigid, frame):
    print "signal", sigid, ",", "Handling SIGUSR1!"
    sys.exit(0)

def main():
    # Register signal handler
    signal.signal(signal.SIGINT, signal_handler_int)
    signal.signal(signal.SIGTERM, signal_handler_term)
    signal.signal(signal.SIGUSR1, signal_handler_usr)

    while True:
        print "I am alive"
        sys.stdout.flush()
        time.sleep(1)

# This is the standard boilerplate that calls the main() function.
if __name__ == '__main__':
    main()

Following is the Dockerfile to convert this to container:

FROM python:2.7
COPY ./signalexample.py ./signalexample.py
ENTRYPOINT ["python", "signalexample.py"]

Lets build the container:

docker build --no-cache -t smakam/signaltest:v1 .

Lets start the container:

docker run -d --name signaltest smakam/signaltest:v1 

We can watch the logs from container using docker logs:

docker logs -f signaltest

The Python program above handles SIGINT, SIGTERM and SIGUSR1. We can pass these signals to the container using Docker CLI.
Following command sends SIGINT to the container:

docker kill --signal=SIGINT signaltest

In the Docker logs, we can see the following to show that this signal is handled:

signal 2 , Handling Ctrl+C/SIGINT!

Following output shows the container exit status:

$ docker ps -a
CONTAINER ID        IMAGE                  COMMAND                  CREATED             STATUS                     PORTS               NAMES
c06266e79a43        smakam/signaltest:v1   "python signalexam..."   36 seconds ago      Exited (2) 3 seconds ago                       signaltest

Following command sends SIGTERM to the container:

docker kill --signal=SIGTERM signaltest

In the Docker logs, we can see the following to show that this signal is handled:

signal 15 , Handling SIGTERM!

Following output shows the container exit status:

$ docker ps -a
CONTAINER ID        IMAGE                  COMMAND                  CREATED             STATUS                      PORTS               NAMES
0149708f42b2        smakam/signaltest:v1   "python signalexam..."   10 seconds ago      Exited (15) 2 seconds ago                       signaltest

Following command sends SIGUSR1 to the container:

docker kill --signal=SIGUSR1 signaltest

In the Docker logs, we can see the following to show that this signal is handled:

signal 15 , Handling SIGUSR1!

Following output shows the container exit status:

$ docker ps -a
CONTAINER ID        IMAGE                  COMMAND                  CREATED             STATUS                     PORTS               NAMES
c92f7b4dd45b        smakam/signaltest:v1   "python signalexam..."   12 seconds ago      Exited (0) 2 seconds ago                       signaltest

When we execute “docker stop “, Docker first sends SIGTERM signal to the container, waits for some time and then sends SIGKILL. This is done so that the program executing inside the container can use the SIGTERM signal to do the graceful shutdown of the program.

Common mistake in Docker signal handling

In the above example, the python program runs as PID 1 inside container since we used the EXEC form of ENTRYPOINT in Dockerfile. If we use the background method of ENTRYPOINT, shell process runs as PID 1 and the python program runs as another process. Following is a sample Dockerfile for starting the program as background process.

FROM python:2.7
COPY ./signalexample.py ./signalexample.py
ENTRYPOINT python signalexample.py

In this example, Docker passes the signal to the shell process instead of to the Python program. This causes the python program to not see the signal sent to the container. If there are multiple processes running inside the container and we need to pass the signal, 1 possible approach is to run the ENTRYPOINT as a script, handle the signal in the script and pass it to the correct process. 1 example using this approach is mentioned here.

Difference between “docker stop”, “docker rm” and “docker kill”

“docker stop” – Sends SIGTERM to container, waits some time for process to handle it and then sends SIGKILL. Container filesystem remains intact.
“docker kill” – Sends SIGKILL directly. Container filesystem remains intact.
“docker rm” – Removes container filesystem. “docker rm -f” will send SIGKILL and then remove container filesystem.
Using “docker run” with “–rm” option will automatically remove containers including container filesystem when the container exits.

When container exits without the container filesystem getting removed, we can still restart the container.

Container restart policy

Container restart policy controls the restart actions when Container exits. Following are the supported restart options:

• no – This is default. Containers do not get restarted when they exit.
• on-failure – Containers restart only when there is a failure exit code. Any exit code other than 0 is treated as failure.
• unless-stopped – Containers restart as long as it was not manually stopped by user.
• always – Always restart container irrespective of exit status.

Following is an example of starting “signaltest” container with restart policy of “on-failure” and retry count of 3. Retry count 3 is the number of restarts that will be done by Docker before giving up.

docker run -d --name=signaltest --restart=on-failure:3 smakam/signaltest:v1

To show the restart happening, we can manually try to send signals to the container. In the “signaltest” example, signals SIGTERM, SIGINT and SIGKILL will cause non-zero exit code and SIGUSR1 will cause zero exit code. 1 thing to remember is that restart does not work if we stop the container or send signals using “docker kill”. I think this is because there must be an explicit check added by Docker to prevent restart in these cases since the action is triggered by user.
Lets send SIGINT to the container by passing the signal to the process. We can find the process id by doing “ps -eaf | grep signalexample” in host machine.

kill -s SIGINT  

Lets check the “docker ps” output. We can see that the “created” time is 50 seconds. Uptime is less than a second because container restarted.

$ docker ps
CONTAINER ID        IMAGE                  COMMAND                  CREATED             STATUS                  PORTS               NAMES
b867543b110c        smakam/signaltest:v1   "python signalexam..."   50 seconds ago      Up Less than a second 

Following command shows the restart policy and the restart count for the running container. In this example, container restart happened once.

$ docker inspect signaltest | grep -i -A 2 -B 2 restart
        "Name": "/signaltest",
        "RestartCount": 1,
            "RestartPolicy": {
                "Name": "on-failure",
                "MaximumRetryCount": 3

To illustrate that restart does not work on exit code 0, lets send SIGUSR1 to the container that will cause exit code 0.

sudo kill -s SIGUSR1  

In this case, container exits, but it does not get restarted.

Container restart does not work with “–rm” option. This is because “–rm” option causes container to be removed as soon as the container exit happens.

Container health check

It is possible that container does not exit but it not performing as per the requirement. Health check probes can be used to identify misbehaving containers and take action rather than waiting till the end when container dies. Health check probes are used to accomplish the specific task of checking container health. For a container like webserver, health check probe can be as simple as sending curl request to webserver port. By using container’s health, we can restart the container if health check fails.
To illustrate health check feature, I have used the container described here.
Following command starts the webserver container with health check capability enabled.

docker run -p 8080:8080 -d --rm --name health-check --health-interval=1s --health-timeout=3s --health-retries=3 --health-cmd "curl -f http://localhost:8080/health || exit 1" effectivetrainings/docker-health 

Following are all parameters related to healthcheck:

Following “docker ps” output shows container health status:

$ docker ps
CONTAINER ID        IMAGE                              COMMAND                CREATED             STATUS                    PORTS                    NAMES
947dad1c1412        effectivetrainings/docker-health   "java -jar /app.jar"   28 seconds ago      Up 26 seconds (healthy)   0.0.0.0:8080->8080/tcp   health-check

This container has a backdoor approach to mark container health as unhealthy. Lets use the backdoor approach to mark container as unhealthy like below:

curl "http://localhost:8080/environment/health?status=false"

Now, lets check the “docker ps” output. The container’s health has now become unhealthy.

$ docker ps
CONTAINER ID        IMAGE                              COMMAND                CREATED             STATUS                     PORTS                    NAMES
947dad1c1412        effectivetrainings/docker-health   "java -jar /app.jar"   3 minutes ago       Up 3 minutes (unhealthy)   0.0.0.0:8080->8080/tcp   health-check

Service restart with Swarm

Docker Swarm mode introduces a higher level of abstraction called Service and containers are part of the service. When we create a service, we specify the number of containers that needs to be part of the service using “replicas” parameter. Docker swarm will monitor the number of replicas and if any container dies, Swarm will create new container to keep the replica count as requested by the user.
Below command can be used to create signal service with 2 container replicas:

docker service create --name signaltest --replicas=2 smakam/signaltest:v1

Following command output shows the 2 containers that are part of “signaltest” service:

$ docker service ps signaltest
ID                  NAME                IMAGE                  NODE                DESIRED STATE       CURRENT STATE            ERROR               PORTS
vsgtopkkxi55        signaltest.1        smakam/signaltest:v1   ubuntu              Running             Running 36 seconds ago                       
dbbm05w91wv7        signaltest.2        smakam/signaltest:v1   ubuntu              Running             Running 36 seconds ago  

Following parameters control the container restart policy in a service:

Lets start the “signaltest” service with restart-condition of “on-failure”:

docker service create --name signaltest --replicas=2 --restart-condition=on-failure --restart-delay=3s smakam/signaltest:v1

Remember that sending signal “SIGTERM”, “SIGINT”, “SIGKILL” causes non-zero container exit codes and sending “SIGUSR1” causes zero container exit code.
Lets first send SIGTERM to 1 of the 2 containers:

docker kill --signal=SIGTERM 

Following is the “signaltest” service output that shows the 3 containers including the one that has exited with non-zero status:

$ docker service ps signaltest
ID                  NAME                IMAGE                  NODE                DESIRED STATE       CURRENT STATE            ERROR                        PORTS
35ndmu3jbpdb        signaltest.1        smakam/signaltest:v1   ubuntu              Running             Running 4 seconds ago                                 
ullnsqio5151         \_ signaltest.1    smakam/signaltest:v1   ubuntu              Shutdown            Failed 11 seconds ago    "task: non-zero exit (15)"   
2rfwgq0388mt        signaltest.2        smakam/signaltest:v1   ubuntu              Running             Running 49 seconds ago  

Following command sends SIGUSR1 signal to 1 of the containers which causes container to exit with status 0.

docker kill --signal=SIGUSR1 

Following command shows that the container did not restart since the container exit code is 0.

$ docker service ps signaltest
ID                  NAME                IMAGE                  NODE                DESIRED STATE       CURRENT STATE            ERROR                        PORTS
35ndmu3jbpdb        signaltest.1        smakam/signaltest:v1   ubuntu              Running             Running 52 seconds ago                                
ullnsqio5151         \_ signaltest.1    smakam/signaltest:v1   ubuntu              Shutdown            Failed 59 seconds ago    "task: non-zero exit (15)"   
2rfwgq0388mt        signaltest.2        smakam/signaltest:v1   ubuntu              Shutdown            Complete 3 seconds ago 

$ docker service ls
ID                  NAME                MODE                REPLICAS            IMAGE                  PORTS
xs8lzbqlr69n        signaltest          replicated          1/2                 smakam/signaltest:v1 

I don’t see a real need to change the default Swarm service restart policy from “any”.

Service health check

In the previous sections, we saw how to use container health check with “effectivetrainings/docker-health” container. Even though we could detect the container as unhealthy, we could not restart the container automatically. For standalone containers, Docker does not have native integration to restart the container on health check failure though we can achieve the same using Docker events and a script. Health check is better integrated with Swarm. With health check integrated to Swarm, when a container in a service is unhealthy, Swarm automatically shuts down the unhealthy container and starts a new container to maintain the container count as specified in the replica count of a service.

“docker service” command provides following options for health check and associated behavior.

Lets create “swarmhealth” service with 2 replicas of “docker-health” containers.

docker service create --name swarmhealth --replicas 2 -p 8080:8080 --health-interval=2s --health-timeout=10s --health-retries=10 --health-cmd "curl -f http://localhost:8080/health || exit 1" effectivetrainings/docker-health

Following output shows the “swarmhealth” service output and the 2 healthy containers:

$ docker service ps swarmhealth
ID                  NAME                IMAGE                                     NODE                DESIRED STATE       CURRENT STATE            ERROR               PORTS
jg8d78inw97n        swarmhealth.1       effectivetrainings/docker-health:latest   ubuntu              Running             Running 21 seconds ago                       
l3fdz5awv4u0        swarmhealth.2       effectivetrainings/docker-health:latest   ubuntu              Running             Running 19 seconds ago 

$ docker ps
CONTAINER ID        IMAGE                                     COMMAND                CREATED              STATUS                        PORTS                    NAMES
d9b1f1b0a9b0        effectivetrainings/docker-health:latest   "java -jar /app.jar"   About a minute ago   Up About a minute (healthy)                            swarmhealth.1.jg8d78inw97nmmbdtjzrscg1q
bb15bfc6e588        effectivetrainings/docker-health:latest   "java -jar /app.jar"   About a minute ago   Up About a minute (healthy)                            swarmhealth.2.l3fdz5awv4u045g2xiyrbpe2u

Lets mark 1 of the container unhealthy using backdoor command:

curl "http://:8080/environment/health?status=false"

Following output shows that 1 of the containers that has been shutdown which is the unhealthy container and 2 more running replicas. 1 of the replicas got restarted after the other container became unhealthy.

$ docker service ps swarmhealth
ID                  NAME                IMAGE                                     NODE                DESIRED STATE       CURRENT STATE           ERROR                              PORTS
ixxvzyuyqmcq        swarmhealth.1       effectivetrainings/docker-health:latest   ubuntu              Running             Running 4 seconds ago                                      
jg8d78inw97n         \_ swarmhealth.1   effectivetrainings/docker-health:latest   ubuntu              Shutdown            Failed 23 seconds ago   "task: non-zero exit (143): do…"   
l3fdz5awv4u0        swarmhealth.2       effectivetrainings/docker-health:latest   ubuntu              Running             Running 5 minutes ago 

Service upgrade and rollback

When we have new versions of service to be updated without taking service downtime, Docker provides many controls to do the upgrade and rollback. For example, we can control parameters like number of tasks to upgrade at a single time, actions on upgrade failure, delay between task upgrades etc. This helps us achieve release patterns like Blue green and Canary deployment patterns.

Following options are provided by Docker in “docker service” command to control rolling upgrade and rollback.

Rolling upgrade:

Rollback:

To illustrate service upgrade, I have a simple python webserver program running as container.
Following is the Python program:

#!/usr/bin/python

import sys
from BaseHTTPServer import BaseHTTPRequestHandler, HTTPServer
import urlparse
import json

class GetHandler(BaseHTTPRequestHandler):

    def do_GET(self):
        message = "You are using version 1\n"
        self.send_response(200)
        self.end_headers()
        self.wfile.write(message)
        return

def main():
    server = HTTPServer(('', 8000), GetHandler)
    print 'Starting server at http://localhost:8000'
    server.serve_forever()

# This is the standard boilerplate that calls the main() function.
if __name__ == '__main__':
    main()

This is the Dockerfile to create the Container:

FROM python:2.7
COPY ./webserver.py ./webserver.py
ENTRYPOINT ["python", "webserver.py"]

I have 2 versions of Container, smakam/webserver:v1 and smakam/webserver:v2. The only difference is the message output that either shows “You are using version 1” or “You are using version 2”.

Lets create version 1 of the service with 2 replicas:

docker service create --name webserver --replicas=2 -p 8000:8000 smakam/webserver:v1

We can access the service using script. The service request will get load balanced between the 2 replicas.

while true; do curl -s "localhost:8000";sleep 1;done

Following is the service request output that shows we are using version 1 of the service:

You are using version 1
You are using version 1
You are using version 1

Lets upgrade to version 2 of the web service. Since we have specified update-delay of 3 seconds, there will be a 3 second gap between upgrades of 2 replicas. Since the “update-parallelism” default is 1, only 1 task will be upgraded at 1 time.

docker service update --update-delay=3s --image=smakam/webserver:v2 webserver

Following is the service request output output that shows the request slowly getting migrated to version 2 as the upgrade happens 1 replica at a time.

You are using version 1
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 2
You are using version 2

Now, lets rollback to version 1 of the webserver:

docker service update --rollback webserver

Following is the service request output output that shows the request slowly getting downgraded from version 2 to version 1.

You are using version 2
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 2
You are using version 1
You are using version 1

Please let me know your feedback and if you want to see more details on any specific topic related to this. I have put the code associated with this blog here. The containers used in this blog(smakam/signaltest, smakam/webserver) are in Docker hub.

References

• Blog – Life and Death of a Container
• Blog – Trapping signals in Docker containers
• Blog – Gracefully stopping Docker containers
• Docker container restart policies
• Docker container healthcheck
• Docker service rolling update

Docker Networking Tip – Macvlan driver

Last few months, I have been looking at Docker forums(https://forums.docker.com/, https://stackoverflow.com/questions/tagged/docker) and trying to understand some of the common questions/issues faced in the Docker Networking area. This prompted me to do 2 presentations:

• Docker Networking overview
• Docker Networking – Common issues and troubleshooting techniques

I received positive feedback to these 2 presentations. As a next step, I thought preparing each Docker Networking tip as a video can help some folks to get a better picture. As a first attempt, I prepared Macvlan driver as my first Docker Networking video tip. Following is the associated Youtube video and presentation.

Docker Networking Tip – Macvlan driver from Sreenivas Makam

If you think this is useful and would like to see more videos, please let me know. Based on the feedback received, I will try to create more Docker Networking tips in video format.

Bangalore meetup – Docker Networking Troubleshooting presentation

Docker Bangalore meetup is a very active group dedicated to topics around Docker and the ecosystem around it. There was a meetup conducted yesterday at IBM office. There was a mix of topics presented including Moby, Linuxkit, Docker for Windows and Docker multi-stage builds. Thanks to Neependra for organizing the meetup, Neependra created this meetup group and has been passionately doing it from the early days of Docker. Thanks to IBM for hosting the meetup, IBM has been a very active contributor to Container and Docker ecosystem.

I did a presentation on “Docker Networking – Common issues and troubleshooting considerations”. The feedback received in the session was very positive. Following were some reasons that I did this presentation:

• Networking is a complex topic and Docker networking is continuously evolving in every release and this makes it difficult for folks to figure out the right feature to use for their use-case.
• When applications are taken from development to production, networking needs change and the typical approaches don’t always help.
• Enterprise customers have lot of legacy applications and the networking needs to satisfy connecting legacy non-containerized applications with the new container based micro services.

Following is the approach and references I took to prepare the presentation:

• Over the years, I have used some techniques for common networking stuff including Docker containers and I have captured this.
• I went through the discussions in stackoverflow and docker forums and tried to find the common networking questions that folks ask.
• Docker has a great documentation that includes Docker’s internal documentation, white papers and great set of blogs. I referred this extensively.
• Dockercon videos around networking topics.

Following link has the slides and this link has the video recording to my presentation. The slides in the recording is not very clear. I would very much appreciate if folks can provide feedback and also provide suggestions on additional Docker networking tips that can be covered. I will try to keep the slides updated based on what I learn/understand in the future.

Following are some of my earlier blogs/presentations that you can refer to get more understanding on Docker Networking recent features:

• Docker Networking Overview (This was a presentation I did inside Cisco and it covers all Docker Networking basics and its updated till Docker 17.06 version.)
• Service Discovery and Load balancing internals
• Macvlan and IPvlan basics
• Docker macvlan and ipvlan plugins

Docker CE – Installing Test(“RC”) version

Starting with Docker 17.03, Docker introduced Community edition(CE) and Enterprise edition(CE) version of their Docker software. The release numbering also changed. From Docker 1.13.1, we jump to 17.03 version. Docker CE is the free version while Docker EE is the commercially supported enterprise version. Docker enterprise edition comes in different flavors based on the cost. Please refer this link for details on comparison between different Docker editions and the supported platforms for each editions. Both Docker CE and EE follow time based release schedule. Docker CE has 3 editions. CE “stable” edition gets released once every 3 months. CE “edge” edition gets released once every month. CE “test” edition is a release candidate that gets folded into “edge” and “stable” versions. I have used Docker release candidate(“test” edition) to try out new features before they get released. The steps to install release candidate Docker version is slightly different from installing “stable” and “edge” versions. Docker CE 17.06.0-ce-rc2 got released few days back and I have started trying out the new features in this version. This is a precursor to 17.06 release that will happen in few weeks. In this blog, I will cover installation steps for Docker CE edition release candidate software versions. I have focused on 17.06.0-ce-rc2, but the steps applies to any release candidate versions. The 3 approaches I have tried are installation from Docker static binaries, Docker machine with boot2docker and installation in Ubuntu platform with package manager.

Installation using Docker machine

When Docker RC version is released, the corresponding boot2docker image also gets released. I used the steps below to to the installation.

Continue reading Docker CE – Installing Test(“RC”) version →

Compare Docker for Windows options

As part of Dockercon 2017, there was an announcement that Linux containers can run as hyperv container in Windows server. This announcement made me to take a deeper look  into Windows containers. I have worked mostly with Linux containers till now. In Windows, I have mostly used Docker machine or Toolbox till now. I recently tried out other methods to deploy containers in Windows. In this blog, I will cover different methods to run containers in Windows, technical internals on the methods and comparison between the methods. I have also covered Windows Docker base images and my experiences trying the different methods to run Docker containers in Windows. The 3 methods that I am covering are Docker Toolbox/Docker machine, Windows native containers, hyper-v containers.

Docker Toolbox

Docker Toolbox runs Docker engine on top of boot2docker VM image running in Virtualbox hypervisor. We can run Linux containers on top of the Docker engine. I have written few blogs(1, 2) about Docker Toolbox before. We can run Docker Toolbox on any Windows variants.

Windows Native containers

Continue reading Compare Docker for Windows options →

Linux Docker base images

Recently, someone asked me how to create a Docker base image for a Linux variant that they are creating. In this blog, I will cover what a Linux base image is and how to create new base images.

Linux Docker base image

Following is a sample Dockerfile to create a Python webserver Docker container image.

FROM ubuntu:14.04

# Update the sources list
RUN apt-get update

# Update
RUN apt-get install -y python2.7 python-pip

# Install app dependencies
RUN pip install Flask==0.9.0

# Bundle app source
COPY simpleapp.py /src/simpleapp.py

EXPOSE  8000
CMD ["python", "/src/simpleapp.py", "-p 8000"]

In the above example, we have given “FROM ubuntu:14.04” in the first line. ubuntu:14.04 is the base image used here. 1 common question that I get asked is that does it mean that this container contains everything present in Ubunbu VM? That is not true. What ubuntu container image contains is the packages, libraries and tools associated with Ubuntu along with the root filesystem. To give a size comparison, Ubuntu container image is around 180mb while the Ubuntu VM size is around 1GB.

Docker hub contains base container images for all major distributions including Ubuntu, rhel, centos, debian etc. It is always better to take the official images as they would have the latest security patches. The official images are maintained by the distribution vendor who works closely with Docker.

Creating Linux Docker Container base image

Docker repository provides a script “mkimage.sh” that can be used to create base images for different Linux variants. When Docker is installed in Ubuntu 14.04, “mkimage.sh” is available in “/usr/share/docker-ce/contrib/”. Following output shows the “help” for “mkimage.sh”.

$ ./mkimage.sh --help
usage: mkimage.sh [-d dir] [-t tag] [--compression algo| --no-compression] script [script-args]
   ie: mkimage.sh -t someuser/debian debootstrap --variant=minbase jessie
       mkimage.sh -t someuser/ubuntu debootstrap --include=ubuntu-minimal --components=main,universe trusty
       mkimage.sh -t someuser/busybox busybox-static
       mkimage.sh -t someuser/centos:5 rinse --distribution centos-5
       mkimage.sh -t someuser/mageia:4 mageia-urpmi --version=4
       mkimage.sh -t someuser/mageia:4 mageia-urpmi --version=4 --mirror=http://somemirror/
       mkimage.sh -t someuser/solaris solaris

Each Linux distribution provides a helper script to create the base filesystem. For example, “debootstrap” is used for debian/ubuntu variants, “rinse” is used for centos variants. “mkimage.sh” uses the root filesystem created by helper script to import that to a Docker container. The helper script installs the necessary packages and sets up the root filesystem. If you are creating a new flavor of Linux and if it based on 1 of the major distributions, we can extend the helper script. Otherwise, we can create a new helper script based on the current examples. It will be good to contribute the new helper script back to “mkimage” in Docker repository.

Following is an example to create Debian Jessie base image with mkimage.sh:

sudo ./mkimage.sh -t smakam/debian:jessie debootstrap jessie

The above command will create a new container image “smakam/debian:jessie”. It pulls the necessary files from the repository.

References

• Docker base images
• Debootstrap wiki