Vagrant Box:
Boxes are the package format for Vagrant environments. A box can be used by anyone on any platform that Vagrant supports to bring up an identical working environment.
Docker
Docker is a tool that packages, provisions and runs containers independent of the OS. A container packages the application service or function with all of the libraries, configuration files, dependencies and other necessary parts to operate
Question :
How docker and vagrant box are different from each other?
What freedom does they provide for the developer and production?
How Developer can make use of the Vagrant and differenciate the differences between docker and vagrant.
Vagrant : Vagrant is a project that helps the spawning of virtual machines. It started as an command line of VirtualBox, something similar to Gemfile for VM's. You can choose the base image to start with, network, IP, share folders and put it all in a file that anyone can reuse to spawn the same configured machine. Vagrant has different extensions, provisioning options and VM providers. You can run a VirtualBox, VMware and it is extensible enough to be able to create instances on EC2.
Docker : Docker, allows to package an application with all of its dependencies into a standardized unit of software development. So, it reduces a friction between developer, QA and testing. The idea is to share the linux kernel. It dynamically change your application, adding new capabilities every single day, scaling out services to quickly changing the problem areas. Docker is putting itself in an excited place as the interface to PaaS be it networking, discovery and service discovery with applications not having to care about underlying infrastructure. The industry now benefits from a standardized container work-flow and an ecosystem of helpful tools, services and vibrant community around it.
Following are few points ease for developer and production deployments:
ACCELERATE DEVELOPERS : Your development environment is the first and foremost thing in IT. Whatever you want, the different tools, databases, instances, networks, etc. you can easily create all these with docker using simple commands(Image creation using Dockerfile or pull from Docker Hub). Get 0 to 100 with docker machine within seconds and as a developer I can focus more on my application.
EMPOWER CREATIVITY : The loosely coupled architecture where every instance i.e. container here is completely isolated with each other. So, their is no any conflict between the tools, softwares, etc. So, the more creative way developer can utilize the system.
ELIMINATE ENVIRONMENT INCONSISTENCIES : Docker containers are responsible for actual running of the applications and includes the operating system, user-files and metadata. And docker image is same across the environment so your build will go seamlessly from dev to qa, staging and production.
In production environment you must have a zero downtime along with automated deployments. You should take care of all things as service discovery, logging and monitoring, scaling and vulnerability scanning for docker images, etc. All these things accelerate the deployment process and help you better serve the production environment. You don't need to login into production server for any configuration change, logging or monitoring. Docker will do it for you. Developers must understand that docker is a tool, it's nothing without other components. But, it will definitely reduce your huge deployment from hours to minutes. Hope this will clear. Thank you.
Docker relies on containerization, while Vagrant utilizes virtualization.
Related
I'm new to devops and kubernetes and was setting up the local development environment.
For having hurdle-free deployment, I wanted to keep the development environment as similar as possible to the deployment environment. So, for that, I'm using minikube for single node cluster, and that solves a lot of my problems but right now, according to my knowledge, a developer need to do following to see the changes:
write a code locally,
create a container image and then push it to container register
apply the kubernetes configuration with updated container image
But the major issue with this approach is the high development time, Can you suggest some better approach by which I can see the changes in real-time?
The official Kubernetes blog lists a couple of CI/CD dev tools for building Kubernetes based applications: https://kubernetes.io/blog/2018/05/01/developing-on-kubernetes/
However, as others have mentioned, dev cycles can become a lot slower with CI/CD approaches for development. Therefore, a colleague and I started the DevSpace CLI. It lets you create a DevSpace inside Kubernetes which allows you a direct terminal access and real-time file synchronization. That means you can use it with any IDE and even use hot reloading tools such as nodemon for nodejs.
DevSpace CLI on GitHub: https://github.com/covexo/devspace
I am afraid that the first two steps are practically mandatory if you want to have a proper CI/CD environment in Kubernetes. Because of the ephemeral nature of containers, it is strongly discouraged to perform hotfixes in containers, as they could disappear at any moment.
There are tools like helm or kubecfg that can help you with the third step
apply the kubernetes configuration with updated container image
They allow versioning and deployment upgrades. You would still need to learn how to use but they have innumerable advantages.
Another option that comes to mind (that without Kubernetes) would be to use development containers with Docker. In this kind of containers your code is in a volume, so it is easier to test changes. In the worst case you would only have to restart the container.
Examples of development containers (by Bitnami) (https://bitnami.com/containers):
https://github.com/bitnami/bitnami-docker-express
https://github.com/bitnami/bitnami-docker-laravel
https://github.com/bitnami/bitnami-docker-rails
https://github.com/bitnami/bitnami-docker-symfony
https://github.com/bitnami/bitnami-docker-codeigniter
https://github.com/bitnami/bitnami-docker-java-play
https://github.com/bitnami/bitnami-docker-swift
https://github.com/bitnami/bitnami-docker-tomcat
https://github.com/bitnami/bitnami-docker-python
https://github.com/bitnami/bitnami-docker-node
I think using Docker / Kubernetes already during development of a component is the wrong approach, exactly because of this slow development cycles. I would just develop as I'm used to do (e.g. running the component in the IDE, or a local app server), and only build images and start testing it in a production like environment once I have something ready to deploy. I only use local Docker containers, or our Kubernetes development environment, for running components on which the currently developed component depends: that might be a database, or other microservices, or whatever.
On the Jenkins X project we're big fans of using DevPods for fast development - which basically mean you compile/test/run your code inside a pod inside the exact same kubernetes cluster as your CI/CD runs using the exact same tools (maven, git, kubectl, helm etc).
This lets you use your desktop IDE of your choice while all your developers get to work using the exact same operating system, containers and images for development tools.
I do like minikube but developers often hit issues trying to get it running (usually related to docker or virtualisation issues). Plus many developers laptops are not big enough to run lots of services inside minikube and its always going to behave differently to your real cluster - plus then the developers tools and operating system are often very different to whats running in your CI/CD and cluster.
Here's a demo of how to automate your CI/CD on Kubernetes with live development with DevPods to show how it all works
It's not been so long for me to get involved in Kubernetes and Docker, but to my knowledge, I think it's the first step to learn whether it is possible and how to dockerize your application.
Kubernetes is not a tool for creating docker image and it is simply pulling pre-built image by Docker.
There are quite a few useful courses in the Udemy including this one.
https://www.udemy.com/docker-and-kubernetes-the-complete-guide/
I am trying to help a sysadmin group reduce server & service downtime on the projects they manage. Their biggest issue is that they have to take down a service, install upgrade/configure, and then restart it and hope it works.
I have heard that docker is a solution to this problem, but usually from developer circles in the context of deploying their node/python/ruby/c#/java, etc. applications to production.
The group I am trying to help is using vendor software that requires a lot of configuration and management. Can docker still be used in this case? Can we install any random software on a container? Then keep that in a private repository, upgrade versions, etc.?
This is a windows environment if that makes any difference.
Docker excels at stateless applications. You can use it for persistent data style applications, but requires the use of volume commands.
Can docker still be used in this case?
Yes, but it depends on the application. It should be able to be installed headless, and a couple other things that are pretty specific. (EG: talking to third party servers to get an license can create issues)
Can we install any random software on a container?
Yes... but: remember that when the container restarts, that software will be gone. It's better to create it as an image, and then deploy it.See my example below.
Then keep that in a private repository, upgrade versions, etc.?
Yes.
Here is an example pipeline:
Create a Dockerfile for the OS and what steps it takes to install the application. (Should be headless)
Build the image (at this point, it's called an image, not a container)
Test the image locally by creating a local container. This container is what has the configuration data such as environment variables, the volumes for persistent data it needs, etc.
If it satisifies the local developers wants, then you can either:
Let your build servers create the image and publish it an internal
docker registry (best practice)
Let your local developer publish it
to an internal docker registry
At that point, your next level environments can then pull down the image from the docker registry, configure them and create the container.
In short, it will require a lot of elbow grease but is possible.
Can we install any random software on a container?
Generally yes, but you can have many problems with legacy software which was developed to work on bare metal.
At first it can be persistence problem, but it can be solved using volumes.
At second program that working good on full OS can work not so good in container. Containers have some difference with VM's or bare metal. For example due to missing init process some containers have zombie process issue. About others difference you can read here
Docker have big profit for stateless apps, but some heave legacy apps can work not so good inside containers and should be tested good before using it in production.
I'm currently investigating using Mesosphere in production to run a couple of micro-services as Docker containers.
I got the DCOS deployment done and was able to successfully run one of the services. Before continuing with this approach I however also need to capture the development side (not of Mesos or Mesosphere itself but the development of the micro-services).
Are there any best practices how to run a local deployment of Mesosphere in a Vagrantbox or something similar that would enable our developers to run all the services that are in our eco-system from existing docker images and run the one service you are currently working on from a local code folder?
I already know how to link the devs code folder into a Vagrant machine and should also get the Docker part running but I'm still kind off lost on the whole Mesosphere integration part.
Is there anyone who could forward me to some resource in the Internet describing a possible solution for this? Did anyone of you do something similar and would care to share some insights on this?
Sneak Peak
Mesosphere is actively working on improving the developer experience surrounding DCOS. Part of that effort includes work on a local development cluster to aid application, service, and DCOS package developers. However, the solution is not quite ready for prime time yet. We have begun giving early access to select DCOS Enterprise Edition customers tho. If you'd like to hear more about that, please talk to your sales representative or contact sales through our web site: https://mesosphere.com/contact/
Public Tools
That said, there are many different tools already available that can help when developing Mesos frameworks or Marathon applications.
mesos-compose-dind
playa-mesos
mini mesos
coreos-mesos-cluster
vagrant-mesos
vagrant-puppet-mesosphere
Disambiguation
Mesosphere, Inc. is the company developing the Datacenter Operating System (DCOS).
The "mesosphere stack" historically refers to Mesos + Marathon (sometimes Chronos too, depending who you ask).
DCOS builds upon those open source tools and adds more (web gui, package manager, cli, centralized control plane, dns, etc.).
Update 2017-08-03
The two currently recommended local development options for DC/OS are:
dcos-vagrant
dcos-docker
I think there's not "the" solution... I guess every company will try to work out the best way to find a fit with their development processes.
My company for example is not using DCOS, but a normal Mesos cluster with clustered Marathon and Chronos schedulers. We have three environments, each running CoreOS and Mesos/Marathon (in different versions, to be able to test against version upgrades etc.):
Local Vagrant clusters for our developers for local development/testing (can be configured to use different CoreOS/Mesos/Marathon versions based on the user_data files)
A test cluster (virtualized, latest CoreOS beta, latest Mesos/Marathon/Chronos)
A production cluster (bare metal, latest CoreOS stable, currently Mesos 0.25.0 and Marathon 0.14.1)
Our build cycle uses a build server (TeamCity in our case, Jenkins etc. should also work fine) which builds the Docker images and pushed them to our private Docker repository. The images are tagged automatically in this process.
We also have to possibility to automatically launch them via Marathon API calls to the cluster defined in the build itself, or they can be deployed manually by the developers. The updated Docker images are thereby pulled from our private Docker repository (make sure to use "forcePullImage": true to get the latest version if you don't use specific image tags).
See
https://mesosphere.github.io/marathon/docs/native-docker.html
https://mesosphere.github.io/marathon/docs/native-docker-private-registry.html
https://mesosphere.github.io/marathon/docs/rest-api.html#post-v2-apps
https://github.com/tobilg/coreos-mesos-cluster
I'm not au fait with any of these technologies (embarrassing really), but at my present gig, the company badly needs to automate.
So as I begin to read-up on Puppet and Chef and PowerShell DSC, I then remember that Docker and containerisation is coming to Windows.
Does Docker do away with the need for these tools, or do they work together?
I understand that Docker uses virtualisation technology in the OS, so I get the feeling that Docker solves a different problem, and a configuration tool is still needed but I've no certain, practical knowledge.
Does Docker do away with the need for these tools, or do they work together?
They work together: provisioning and containerization solve different issues, and you actually can provision docker containers themselves with a provisioning tool.
See for instance "Docker: Using Puppet"
Tools like Chef & Puppet are important for configuration, but they do have one weakness that Docker helps to shore up. They are not always fully idempotent (hype notwithstanding). In other words, running Chef twice on the same virtual machine may cause unexpected and hard-to-find changes on that machine, and you'd be restoring a backup to get to a known good state.
By contrast, a Docker deployment involves building an entirely new image and swapping it out with your old image. Rollback involves simply unswapping them and comparing them to diagnose the problems in the new image.
Note that you still might very well use Chef to build your Docker container. But you might very well not. Since containers are supposed to run just one process in a particular way, I've found that a series of simple shell commands is way preferable to the overhead entailed by Chef.
In short no, you don't need anything like Chef or Puppet. Of course you can use if like to but it's not required.
If you build your system in such way that everything in containerized then what you need is only a tiny OS like CoreOS or Atomic.
So you just configure your VM via Cloud-Config if needed and deploy your container either with cloud config or Docker cli itself. The idea is your machines should have a static state and they can be created whenever you want new one and destroyed when you don't need.
There are other tools that can help with Docker orchestration which another story by itself.
Tools like Swarm, Kubernetes and Mesosphere.
docker-machine is also very helpful for development purpose. (maybe deployment too).
Here is CoreOS example:
https://coreos.com/os/docs/latest/cloud-config.html
Resource: I do it in production for different apps.
UPDATE:
BTW, Docker is not only a visualization technology. It does some sort of containerization (you can call it virtualization too) and that's only a small part of the what Docker can do. Docker can configure, build, ship and run application whit eliminating its dependencies on host machine. And that's why you don't need those classic configuration tools.
Puppet and Chef are configuration management tools, where as Docker is a virtualization tool such as LXC.
Usually you'd be using Chef or puppet to manage Docker containers. For example take a look at Chef docs.
EDIT as per #ptierno comment.
Docker is three things: a cool way to run a process, a decent image-based deploy system, and a mediocre system image builder.
The first is not related to config management as those tools aren't involved in running a process, at least not directly. The second takes the place of some amount of config management in production by doing it ahead of time when you build the image. There is still often some need for last-mile config for stuff like service discovery and secrets but this can be handled by lighter tools like consul-templates or confd. The last is where the rub lies. docker build is simple, easy to get started with, and mostly unhelpful for complex situations. You get, at most, a single inheritance tree between dockerfiles which makes stuff like multi-axis matrix builds ({app1 app2 app3} x {prod qa dev}) more difficult than it could be. Also building composable abstraction for other groups to use is difficult, though again it isn't impossible. Using something like Packer to drive image builds can produce simpler code sometimes, and supports the full suite of CAPS (Chef, Ansible, Puppet, Salt) tools. This is mostly aimed at the use case where you are treating Docker images like tiny VMs, which I wish fewer people would do, but it's a thing so here we are.
I've heard about Docker some days ago and wanted to go across.
But in fact, I don't know what is the purpose of this "container"?
What is a container?
Can it replace a virtual machine dedicated to development?
What is the purpose, in simple words, of using Docker in companies? The main advantage?
VM: Using virtual machine (VM) software, for example, Ubuntu can be installed inside a Windows. And they would both run at the same time. It is like building a PC, with its core components like CPU, RAM, Disks, Network Cards etc, within an operating system and assemble them to work as if it was a real PC. This way, the virtual PC becomes a "guest" inside an actual PC which with its operating system, which is called a host.
Container: It's same as above but instead of using an entire operating system, it cut down the "unnecessary" components of the virtual OS to create a minimal version of it. This lead to the creation of LXC (Linux Containers). It therefore should be faster and more efficient than VMs.
Docker: A docker container, unlike a virtual machine and container, does not require or include a separate operating system. Instead, it relies on the Linux kernel's functionality and uses resource isolation.
Purpose of Docker: Its primary focus is to automate the deployment of applications inside software containers and the automation of operating system level virtualization on Linux. It's more lightweight than standard Containers and boots up in seconds.
(Notice that there's no Guest OS required in case of Docker)
[ Note, this answer focuses on Linux containers and may not fully apply to other operating systems. ]
What is a container ?
It's an App: A container is a way to run applications that are isolated from each other. Rather than virtualizing the hardware to run multiple operating systems, containers rely on virtualizing the operating system to run multiple applications. This means you can run more containers on the same hardware than VMs because you only have one copy of the OS running, and you do not need to preallocate the memory and CPU cores for each instance of your app. Just like any other app, when a container needs the CPU or Memory, it allocates them, and then frees them up when done, allowing other apps to use those same limited resources later.
They leverage kernel namespaces: Each container by default will receive an environment where the following are namespaced:
Mount: filesystems, / in the container will be different from / on the host.
PID: process id's, pid 1 in the container is your launched application, this pid will be different when viewed from the host.
Network: containers run with their own loopback interface (127.0.0.1) and a private IP by default. Docker uses technologies like Linux bridge networks to connect multiple containers together in their own private lan.
IPC: interprocess communication
UTS: this includes the hostname
User: you can optionally shift all the user id's to be offset from that of the host
Each of these namespaces also prevent a container from seeing things like the filesystem or processes on the host, or in other containers, unless you explicitly remove that isolation.
And other linux security tools: Containers also utilize other security features like SELinux, AppArmor, Capabilities, and Seccomp to limit users inside the container, including the root user, from being able to escape the container or negatively impact the host.
Package your apps with their dependencies for portability: Packaging an application into a container involves assembling not only the application itself, but all dependencies needed to run that application, into a portable image. This image is the base filesystem used to create a container. Because we are only isolating the application, this filesystem does not include the kernel and other OS utilities needed to virtualize an entire operating system. Therefore, an image for a container should be significantly smaller than an image for an equivalent virtual machine, making it faster to deploy to nodes across the network. As a result, containers have become a popular option for deploying applications into the cloud and remote data centers.
Can it replace a virtual machine dedicated to development ?
It depends: If your development environment is running Linux, and you either do not need access to hardware devices, or it is acceptable to have direct access to the physical hardware, then you'll find a migration to a Linux container fairly straight forward. The ideal target for a docker container are applications like web based API's (e.g. a REST app), which you access via the network.
What is the purpose, in simple words, of using Docker in companies ? The main advantage ?
Dev or Ops: Docker is typically brought into an environment in one of two paths. Developers looking for a way to more rapidly develop and locally test their application, and operations looking to run more workload on less hardware than would be possible with virtual machines.
Or Devops: One of the ideal targets is to leverage Docker immediately from the CI/CD deployment tool, compiling the application and immediately building an image that is deployed to development, CI, prod, etc. Containers often reduce the time to move the application from the code check-in until it's available for testing, making developers more efficient. And when designed properly, the same image that was tested and approved by the developers and CI tools can be deployed in production. Since that image includes all the application dependencies, the risk of something breaking in production that worked in development are significantly reduced.
Scalability: One last key benefit of containers that I'll mention is that they are designed for horizontal scalability in mind. When you have stateless apps under heavy load, containers are much easier and faster to scale out due to their smaller image size and reduced overhead. For this reason you see containers being used by many of the larger web based companies, like Google and Netflix.
Same questions were hitting my head some days ago and what i found after getting into it, let's understand in very simple words.
Why one would think about docker and containers when everything seems fine with current process of application architecture and development !!
Let's take an example that we are developing an application using nodeJs , MongoDB, Redis, RabbitMQ etc services [you can think of any other services].
Now we face these following things as problems in application development and shipping process if we forget about existence of docker or other alternatives of containerizing applications.
Compatibility of services(nodeJs, mongoDB, Redis, RabbitMQ etc.) with OS(even after finding compatible versions with OS, if something unexpected happens related to versions then we need to relook the compatibility again and fix that).
If two system components requires a library/dependency with different versions in application in OS(That need a relook every time in case of an unexpected behaviour of application due to library and dependency version issue).
Most importantly , If new person joins the team, we find it very difficult to setup the new environment, person has to follow large set of instructions and run hundreds of commands to finally setup the environment And it takes time and effort.
People have to make sure that they are using right version of OS and check compatibilities of services with OS.And each developer has to follow this each time while setting up.
We also have different environment like dev, test and production.If One developer is comfortable using one OS and other is comfortable with other OS And in this case, we can't guarantee that our application will behave in same way in these two different situations.
All of these make our life difficult in process of developing , testing and shipping the applications.
So we need something which handles compatibility issue and allows us to make changes and modifications in any system component without affecting other components.
Now we think about docker because it's purpose is to
containerise the applications and automate the deployment of applications and ship them very easily.
How docker solves above issues-
We can run each service component(nodeJs, MongoDB, Redis, RabbitMQ) in different containers with its own dependencies and libraries in the same OS but with different environments.
We have to just run docker configuration once then all our team developers can get started with simple docker run command, we have saved lot of time and efforts here:).
So containers are isolated environments with all dependencies and
libraries bundled together with their own process and networking
interfaces and mounts.
All containers use the same OS resources
therefore they take less time to boot up and utilise the CPU
efficiently with less hardware costs.
I hope this would be helpful.
Why use docker:
Docker makes it really easy to install and running software without worrying about setup or dependencies. Docker is really made it easy and really straight forward for you to install and run software on any given computer not just your computer but on web servers as well or any cloud based computing platform. For example when I went to install redis in my computer by using bellow command
wget http://download.redis.io/redis-stable.tar.gz
I got error,
Now I could definitely go and troubleshoot this install that program and then try installing redis again, and I kind of get into endless cycle of trying to do all bellow troubleshooting as you I am installing and running software.
Now let me show you how easy it is to run read as if you are making use of Docker instead. just run the command docker run -it redis, this command will install docker without any error.
What docker is:
To understand what is docker you have to know about docker Ecosystem.
Docker client, server, Machine, Images, Hub, Composes are all projects tools pieces of software that come together to form a platform where ecosystem around creating and running something called containers, now if you run the command docker run redis something called docker CLI reached out to something called the Docker Hub and it downloaded a single file called an image.
An image is a single file containing all the dependencies and all the configuration required to run a very specific program, for example redis this which is what the image that you just downloaded was supposed to run.
This is a single file that gets stored on your hard drive and at some point time you can use this image to create something called a container.
A container is an instance of an image and you can kind of think it as being like a running program with it's own isolated set of hardware resources so it kind of has its own little set or its own little space of memory has its own little space of networking technology and its own little space of hard drive space as well.
Now lets examine when you give bellow command:
sudo docker run hello-world
Above command will starts up the docker client or docker CLI, Docker CLI is in charge of taking commands from you kind of doing a little bit of processing on them and then communicating the commands over to something called the docker server, and docker server is in charge of the heavy lifting when we ran the command Docker run hello-world,
That meant that we wanted to start up a new container using the image with the name of hello world, the hello world image has a tiny tittle program inside of it whose sole purpose or sole job is to print out the message that you see in the terminal.
Now when we ran that command and it was issued over to the docker server a series of actions very quickly occurred in background. The Docker server saw that we were trying to start up a new container using an image called hello world.
The first thing that the docker server did was check to see if it already had a local copy like a copy on your personal machine of the hello world image or that hello world file.So the docker server looked into something called the image cache.
Now because you and I just installed Docker on our personal computers that image cache is currently empty, We have no images that have already been downloaded before.
So because the image cache was empty the docker server decided to reach out to a free service called Docker hub. The Docker Hub is a repository of free public images that you can freely download and run on your personal computer. So Docker server reached out to Docker Hub and and downloaded the hello world file and stored it on your computer in the image-cache, where it can now be re-run at some point the future very quickly without having to re-downloading it from the docker hub.
After that the docker server will use it to create an instance of a container, and we know that a container is an instance of an image, its sole purpose is to run one very specific program. So the docker server then essentially took that image file from image cache and loaded it up into memory to created a container out of it and then ran a single program inside of it. And that single programs purpose was to print out the message that you see.
What a container is:
A container is a process or a set of processes that have a grouping of resource specifically assigned to it, in the bellow is a diagram that anytime that we think about a container we've got some running process that sends a system call to a kernel, the kernel is going to look at that incoming system call and direct it to a very specific portion of the hard drive, the RAM, CPU or what ever else it might need and a portion of each of these resources is made available to that singular process.
Let me try to provide as simple answers as possible:
But in fact, I don't know what is the purpose of this "container"?
What is a container?
Simply put: a package containing software. More specifically, an application and all its dependencies bundled together. A regular, non-dockerised application environment is hooked directly to the OS, whereas a Docker container is an OS abstraction layer.
And a container differs from an image in that a container is a runtime instance of an image - similar to how objects are runtime instances of classes in case you're familiar with OOP.
Can it replace a virtual machine dedicated to development?
Both VMs and Docker containers are virtualisation techniques, in that they provide abstraction on top of system infrastructure.
A VM runs a full “guest” operating system with virtual access to host resources through a hypervisor. This means that the VM often provides the environment with more resources than it actually needs In general, VMs provide an environment with more resources than most applications need. Therefore, containers are a lighter-weight technique. The two solve different problems.
What is the purpose, in simple words, of using Docker in companies?
The main advantage?
Containerisation goes hand-in-hand with microservices. The smaller services that make up the larger application are often tested and run in Docker containers. This makes continuous testing easier.
Also, because Docker containers are read-only they enforce a key DevOps principle: production services should remain unaltered
Some general benefits of using them:
Great isolation of services
Great manageability as containers contain everything the app needs
Encapsulation of implementation technology (in the containers)
Efficient resource utilisation (due to light-weight os virtualisation) in comparison to VMs
Fast deployment
If you don't have any prior experience with Docker this answer will cover the basics needed as a developer.
Docker has become a standard tool for DevOps as it is an effective application to improve operational efficiencies. When you look at why Docker was created and why it is very popular, it is mostly for its ability to reduce the amount of time it takes to set up the environments where applications run and are developed.
Just look at how long it takes to set up an environment where you have React as the frontend, a node and express API for backend, which also needs Mongo. And that's just to start. Then when your team grows and you have multiple developers working on the same front and backend and therefore they need to set up the same resources in their local environment for testing purposes, how can you guarantee every developer will run the same environment resources, let alone the same versions? All of these scenarios play well into Docker's strengths where it's value comes from setting containers with specific settings, environments and even versions of resources. Simply type a few commands to have Docker set up, install, and run your resources automatically.
Let's briefly go over the main components. A container is basically where your application or specific resource is located. For example, you could have the Mongo database in one container, then the frontend React application, and finally your node express server in the third container.
Then you have an image, which is from what the container is built. The images contains all the information that a container needs to build a container exactly the same way across any systems. It's like a recipe.
Then you have volumes, which holds the data of your containers. So if your applications are on containers, which are static and unchanging, the data that change is on the volumes.
And finally, the pieces that allow all these items to speak is networking. Yes, that sounds simple, but understand that each container in Docker have no idea of the existence of each container. They're fully isolated. So unless we set up networking in Docker, they won't have any idea how to connect to one and another.
There are really good answers above which I found really helpful.
Below I had drafted a simpler answer:
Reasons to dockerize my web application?
a. One OS for multiple applications ( Resources are shared )
b. Resource manangement ( CPU / RAM) is efficient.
c. Serverless Implementation made easier -Yes, AWS ECS with Fargate, But serverless can be achieved with Lamdba
d. Infra As Code - Agree, but IaC can be achieved via Terraforms
e. "It works in my machine" Issue
Still, below questions are open when choosing dockerization
A simple spring boot application
a. Jar file with size ~50MB
b. creates a Docker Image ~500MB
c. Cant I simply choose a small ec2 instance for my microservices.
Financial Benefits (reducing the individual instance cost) ?
a. No need to pay for individual OS subscription
b. Is there any monetary benefit like the below implementation?
c. let say select t3.2xlarge ( 8 core / 32 GB) and start 4-5 docker images ?