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@ -3,104 +3,99 @@ page_description: Docker explained in depth
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page_keywords: docker, introduction, documentation, about, technology, understanding
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# Understanding Docker
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**What is Docker?**
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Docker is a platform for developing, shipping, and running applications.
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Docker is designed to deliver your applications faster. With Docker you
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can separate your applications from your infrastructure AND treat your
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infrastructure like a managed application. We want to help you ship code
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faster, test faster, deploy faster and shorten the cycle between writing
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code and running code.
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Docker is an open platform for developing, shipping, and running applications.
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Docker is designed to deliver your applications faster. With Docker you can
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separate your applications from your infrastructure AND treat your
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infrastructure like a managed application. Docker helps you ship code faster,
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test faster, deploy faster, and shorten the cycle between writing code and
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running code.
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Docker does this by combining a lightweight container virtualization
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platform with workflow and tooling that helps you manage and deploy your
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applications.
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Docker does this by combining a lightweight container virtualization platform
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with workflows and tooling that help you manage and deploy your applications.
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At its core Docker provides a way to run almost any application securely
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isolated into a container. The isolation and security allows you to run
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many containers simultaneously on your host. The lightweight nature of
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containers, which run without the extra overload of a hypervisor, means
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you can get more out of your hardware.
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At its core, Docker provides a way to run almost any application securely
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isolated in a container. The isolation and security allow you to run many
|
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containers simultaneously on your host. The lightweight nature of containers,
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which run without the extra load of a hypervisor, means you can get more out of
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your hardware.
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Surrounding the container virtualization, we provide tooling and a
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platform to help you get your applications (and its supporting
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components) into Docker containers, to distribute and ship those
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containers to your teams to develop and test on them and then to deploy
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those applications to your production environment whether it be in a
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local data center or the Cloud.
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Surrounding the container virtualization are tooling and a platform which can
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help you in several ways:
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* getting your applications (and supporting components) into Docker containers
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* distributing and shipping those containers to your teams for further development
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and testing
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* deploying those applications to your production environment,
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whether it be in a local data center or the Cloud.
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## What can I use Docker for?
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* Faster delivery of your applications
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*Faster delivery of your applications*
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Docker is perfect for helping you with the development lifecycle. Docker
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can allow your developers to develop on local containers that contain
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your applications and services. It can integrate into a continuous
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integration and deployment workflow.
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allows your developers to develop on local containers that contain your
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applications and services. It can then integrate into a continuous integration and
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deployment workflow.
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|
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Your developers write code locally and share their development stack via
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Docker with their colleagues. When they are ready they can push their
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code and the stack they are developing on to a test environment and
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execute any required tests. From the testing environment you can then
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push your Docker images into production and deploy your code.
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For example, your developers write code locally and share their development stack via
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Docker with their colleagues. When they are ready, they push their code and the
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stack they are developing onto a test environment and execute any required
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tests. From the testing environment, you can then push the Docker images into
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production and deploy your code.
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* Deploy and scale more easily
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*Deploying and scaling more easily*
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Docker's container platform allows you to have highly portable
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workloads. Docker containers can run on a developer's local host, on
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physical or virtual machines in a data center or in the Cloud.
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Docker's container-based platform allows for highly portable workloads. Docker
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containers can run on a developer's local host, on physical or virtual machines
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in a data center, or in the Cloud.
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Docker's portability and lightweight nature also makes managing
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workloads dynamically easy. You can use Docker to build and scale out
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applications and services. Docker's speed means that scaling can be near
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real time.
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Docker's portability and lightweight nature also make dynamically managing
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workloads easy. You can use Docker to quickly scale up or tear down applications
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and services. Docker's speed means that scaling can be near real time.
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* Get higher density and run more workloads
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*Achieving higher density and running more workloads**
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Docker is lightweight and fast. It provides a viable (and
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cost-effective!) alternative to hypervisor-based virtual machines. This
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is especially useful in high density environments, for example building
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your own Cloud or Platform-as-a-Service. But it is also useful
|
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for small and medium deployments where you want to get more out of the
|
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resources you have.
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Docker is lightweight and fast. It provides a viable, cost-effective alternative
|
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to hypervisor-based virtual machines. This is especially useful in high density
|
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environments: for example, building your own Cloud or Platform-as-a-Service. But
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it is also useful for small and medium deployments where you want to get more
|
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out of the resources you have.
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## What are the major Docker components?
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Docker has two major components:
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* Docker: the open source container virtualization platform.
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* [Docker Hub](https://hub.docker.com): our Software-as-a-Service
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platform for sharing and managing Docker containers.
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**Note:** Docker is licensed with the open source Apache 2.0 license.
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## What is the architecture of Docker?
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**Note:** Docker is licensed under the open source Apache 2.0 license.
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Docker has a client-server architecture. The Docker *client* talks to
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the Docker *daemon* which does the heavy lifting of building, running
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and distributing your Docker containers. Both the Docker client and the
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daemon *can* run on the same system, or you can connect a Docker client
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with a remote Docker daemon. The Docker client and service can
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communicate via sockets or through a RESTful API.
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## What is Docker's architecture?
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Docker uses a client-server architecture. The Docker *client* talks to the
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Docker *daemon*, which does the heavy lifting of building, running, and
|
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distributing your Docker containers. Both the Docker client and the daemon *can*
|
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run on the same system, or you can connect a Docker client to a remote Docker
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daemon. The Docker client and service communicate via sockets or through a
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RESTful API.
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![Docker Architecture Diagram](/article-img/architecture.svg)
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### The Docker daemon
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As shown on the diagram above, the Docker daemon runs on a host machine.
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The user does not directly interact with the daemon, but instead through
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the Docker client.
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As shown in the diagram above, the Docker daemon runs on a host machine. The
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user does not directly interact with the daemon, but instead through the Docker
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client.
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### The Docker client
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The Docker client, in the form of the `docker` binary, is the primary user
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interface to Docker. It is tasked with accepting commands from the user
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and communicating back and forth with a Docker daemon.
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interface to Docker. It accepts commands from the user and communicates back and
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forth with a Docker daemon.
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### Inside Docker
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Inside Docker there are three concepts we’ll need to understand:
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To understand Docker's internals, you need to know about three components:
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* Docker images.
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* Docker registries.
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@ -108,35 +103,29 @@ Inside Docker there are three concepts we’ll need to understand:
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#### Docker images
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The Docker image is a read-only template, for example an Ubuntu operating system
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with Apache and your web application installed. Docker containers are
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created from images. You can download Docker images that other people
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have created or Docker provides a simple way to build new images or
|
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update existing images. You can consider Docker images to be the **build**
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portion of Docker.
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A Docker image is a read-only template. For example, an image could contain an Ubuntu
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operating system with Apache and your web application installed. Images are used to create
|
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Docker containers. Docker provides a simple way to build new images or update existing
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images, or you can download Docker images that other people have already created.
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Docker images are the **build** component of Docker.
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|
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#### Docker Registries
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Docker registries hold images. These are public or private stores from which you upload
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or download images. The public Docker registry is called
|
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[Docker Hub](http://index.docker.io). It provides a huge collection of existing
|
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images for your use. These can be images you create yourself or you
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can use images that others have previously created. Docker registries are the
|
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**distribution** component of Docker.
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|
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Docker registries hold images. These are public (or private!) stores
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that you can upload or download images to and from. The public Docker
|
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registry is called [Docker Hub](https://hub.docker.com). It provides a
|
||||
huge collection of existing images that you can use. These images can be
|
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images you create yourself or you can make use of images that others
|
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have previously created. You can consider Docker registries the
|
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**distribution** portion of Docker.
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####Docker containers
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Docker containers are similar to a directory. A Docker container holds everything that
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is needed for an application to run. Each container is created from a Docker
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image. Docker containers can be run, started, stopped, moved, and deleted. Each
|
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container is an isolated and secure application platform. Docker containers are the
|
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**run** component of Docker.
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|
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#### Docker containers
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Docker containers are like a directory. A Docker container holds
|
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everything that is needed for an application to run. Each container is
|
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created from a Docker image. Docker containers can be run, started,
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stopped, moved and deleted. Each container is an isolated and secure
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application platform. You can consider Docker containers the **run**
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portion of Docker.
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## So how does Docker work?
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We've learned so far that:
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##So how does Docker work?
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So far, we've learned that:
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1. You can build Docker images that hold your applications.
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2. You can create Docker containers from those Docker images to run your
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|
@ -147,182 +136,149 @@ We've learned so far that:
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Let's look at how these elements combine together to make Docker work.
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### How does a Docker Image work?
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We've already seen that Docker images are read-only templates from which Docker
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containers are launched. Each image consists of a series of layers. Docker
|
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makes use of [union file systems](http://en.wikipedia.org/wiki/UnionFS) to
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combine these layers into a single image. Union file systems allow files and
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directories of separate file systems, known as branches, to be transparently
|
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overlaid, forming a single coherent file system.
|
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|
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We've already seen that Docker images are read-only templates that
|
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Docker containers are launched from. Each image consists of a series of
|
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layers. Docker makes use of [union file
|
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systems](http://en.wikipedia.org/wiki/UnionFS) to combine these layers
|
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into a single image. Union file systems allow files and directories of
|
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separate file systems, known as branches, to be transparently overlaid,
|
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forming a single coherent file system.
|
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One of the reasons Docker is so lightweight is because of these layers. When you
|
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change a Docker image—for example, update an application to a new version— a new layer
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gets built. Thus, rather than replacing the whole image or entirely
|
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rebuilding, as you may do with a virtual machine, only that layer is added or
|
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updated. Now you don't need to distribute a whole new image, just the update,
|
||||
making distributing Docker images faster and simpler.
|
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|
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One of the reasons Docker is so lightweight is because of these layers.
|
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When you change a Docker image, for example update an application to a
|
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new version, this builds a new layer. Hence, rather than replacing the whole
|
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image or entirely rebuilding, as you may do with a virtual machine, only
|
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that layer is added or updated. Now you don't need to distribute a whole new image,
|
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just the update, making distributing Docker images fast and simple.
|
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Every image starts from a base image, for example `ubuntu`, a base Ubuntu image,
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or `fedora`, a base Fedora image. You can also use images of your own as the
|
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basis for a new image, for example if you have a base Apache image you could use
|
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this as the base of all your web application images.
|
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|
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Every image starts from a base image, for example `ubuntu`, a base Ubuntu
|
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image, or `fedora`, a base Fedora image. You can also use images of your
|
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own as the basis for a new image, for example if you have a base Apache
|
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image you could use this as the base of all your web application images.
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> **Note:** Docker usually gets these base images from
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> [Docker Hub](https://index.docker.io).
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>
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Docker images are then built from these base images using a simple, descriptive
|
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set of steps we call *instructions*. Each instruction creates a new layer in our
|
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image. Instructions include actions like:
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|
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> **Note:**
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> Docker usually gets these base images from [Docker Hub](https://hub.docker.com).
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* Run a command. * Add a file or directory. * Create an environment variable. *
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What process to run when launching a container from this image.
|
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|
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Docker images are then built from these base images using a simple
|
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descriptive set of steps we call *instructions*. Each instruction
|
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creates a new layer in our image. Instructions include steps like:
|
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|
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* Run a command.
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* Add a file or directory.
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* Create an environment variable.
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* What process to run when launching a container from this image.
|
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|
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These instructions are stored in a file called a `Dockerfile`. Docker
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reads this `Dockerfile` when you request an image be built, executes the
|
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instructions and returns a final image.
|
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These instructions are stored in a file called a `Dockerfile`. Docker reads this
|
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`Dockerfile` when you request a build of an image, executes the instructions, and
|
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returns a final image.
|
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|
||||
### How does a Docker registry work?
|
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The Docker registry is the store for your Docker images. Once you build a Docker
|
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image you can *push* it to a public registry [Docker Hub](https://index.docker.io) or to
|
||||
your own registry running behind your firewall.
|
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|
||||
The Docker registry is the store for your Docker images. Once you build
|
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a Docker image you can *push* it to a public registry [Docker
|
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Hub](https://hub.docker.com) or to your own registry running behind your
|
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firewall.
|
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Using the Docker client, you can search for already published images and then
|
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pull them down to your Docker host to build containers from them.
|
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|
||||
Using the Docker client, you can search for already published images and
|
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then pull them down to your Docker host to build containers from them.
|
||||
|
||||
[Docker Hub](https://hub.docker.com) provides both public and
|
||||
private storage for images. Public storage is searchable and can be
|
||||
downloaded by anyone. Private storage is excluded from search
|
||||
results and only you and your users can pull them down and use them to
|
||||
build containers. You can [sign up for a plan
|
||||
here](https://registry.hub.docker.com/plans/).
|
||||
[Docker Hub](https://index.docker.io) provides both public and private storage
|
||||
for images. Public storage is searchable and can be downloaded by anyone.
|
||||
Private storage is excluded from search results and only you and your users can
|
||||
pull images down and use them to build containers. You can [sign up for a storage plan
|
||||
here](https://index.docker.io/plans).
|
||||
|
||||
### How does a container work?
|
||||
|
||||
A container consists of an operating system, user added files and
|
||||
meta-data. As we've discovered each container is built from an image. That image tells
|
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Docker what the container holds, what process to run when the container
|
||||
is launched and a variety of other configuration data. The Docker image
|
||||
is read-only. When Docker runs a container from an image it adds a
|
||||
read-write layer on top of the image (using a union file system as we
|
||||
saw earlier) in which your application is then run.
|
||||
A container consists of an operating system, user-added files, and meta-data. As
|
||||
we've seen, each container is built from an image. That image tells Docker
|
||||
what the container holds, what process to run when the container is launched, and
|
||||
a variety of other configuration data. The Docker image is read-only. When
|
||||
Docker runs a container from an image, it adds a read-write layer on top of the
|
||||
image (using a union file system as we saw earlier) in which your application can
|
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then run.
|
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|
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### What happens when you run a container?
|
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|
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The Docker client using the `docker` binary, or via the API, tells the
|
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Docker daemon to run a container. Let's take a look at what happens
|
||||
next.
|
||||
Either by using the `docker` binary or via the API, the Docker client tells the Docker
|
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daemon to run a container.
|
||||
|
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$ docker run -i -t ubuntu /bin/bash
|
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|
||||
Let's break down this command. The Docker client is launched using the
|
||||
`docker` binary with the `run` option telling it to launch a new
|
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container. The bare minimum the Docker client needs to tell the
|
||||
Docker daemon to run the container is:
|
||||
Let's break down this command. The Docker client is launched using the `docker`
|
||||
binary with the `run` option telling it to launch a new container. The bare
|
||||
minimum the Docker client needs to tell the Docker daemon to run the container
|
||||
is:
|
||||
|
||||
* What Docker image to build the container from, here `ubuntu`, a base
|
||||
Ubuntu image;
|
||||
* What Docker image to build the container from, here `ubuntu`, a base Ubuntu
|
||||
image;
|
||||
* The command you want to run inside the container when it is launched,
|
||||
here `bin/bash` to shell the Bash shell inside the new container.
|
||||
here `bin/bash`, to start the Bash shell inside the new container.
|
||||
|
||||
So what happens under the covers when we run this command?
|
||||
So what happens under the hood when we run this command?
|
||||
|
||||
Docker begins with:
|
||||
In order, Docker does the following:
|
||||
|
||||
- **Pulling the `ubuntu` image:**
|
||||
Docker checks for the presence of the `ubuntu` image and if it doesn't
|
||||
exist locally on the host, then Docker downloads it from
|
||||
[Docker Hub](https://hub.docker.com). If the image already exists then
|
||||
Docker uses it for the new container.
|
||||
- **Creates a new container:**
|
||||
Once Docker has the image it creates a container from it:
|
||||
* **Allocates a filesystem and mounts a read-write _layer_:**
|
||||
The container is created in the file system and a read-write layer is
|
||||
added to the image.
|
||||
* **Allocates a network / bridge interface:**
|
||||
Creates a network interface that allows the Docker container to talk to
|
||||
the local host.
|
||||
* **Sets up an IP address:**
|
||||
Finds and attaches an available IP address from a pool.
|
||||
- **Executes a process that you specify:**
|
||||
Runs your application, and;
|
||||
- **Captures and provides application output:**
|
||||
Connects and logs standard input, outputs and errors for you to see how
|
||||
your application is running.
|
||||
- **Pulls the `ubuntu` image:** Docker checks for the presence of the `ubuntu`
|
||||
image and, if it doesn't exist locally on the host, then Docker downloads it from
|
||||
[Docker Hub](https://index.docker.io). If the image already exists, then Docker
|
||||
uses it for the new container.
|
||||
- **Creates a new container:** Once Docker has the image, it uses it to create a
|
||||
container.
|
||||
- **Allocates a filesystem and mounts a read-write _layer_:** The container is created in
|
||||
the file system and a read-write layer is added to the image.
|
||||
- **Allocates a network / bridge interface:** Creates a network interface that allows the
|
||||
Docker container to talk to the local host.
|
||||
- **Sets up an IP address:** Finds and attaches an available IP address from a pool.
|
||||
- **Executes a process that you specify:** Runs your application, and;
|
||||
- **Captures and provides application output:** Connects and logs standard input, outputs
|
||||
and errors for you to see how your application is running.
|
||||
|
||||
Now you have a running container! From here you can manage your running
|
||||
container, interact with your application and then when finished stop
|
||||
and remove your container.
|
||||
You now have a running container! From here you can manage your container, interact with
|
||||
your application and then, when finished, stop and remove your container.
|
||||
|
||||
## The underlying technology
|
||||
|
||||
Docker is written in Go and makes use of several Linux kernel features to
|
||||
deliver the features we've seen.
|
||||
deliver the functionality we've seen.
|
||||
|
||||
### Namespaces
|
||||
Docker takes advantage of a technology called `namespaces` to provide the
|
||||
isolated workspace we call the *container*. When you run a container, Docker
|
||||
creates a set of *namespaces* for that container.
|
||||
|
||||
Docker takes advantage of a technology called `namespaces` to provide an
|
||||
isolated workspace we call a *container*. When you run a container,
|
||||
Docker creates a set of *namespaces* for that container.
|
||||
|
||||
This provides a layer of isolation: each aspect of a container runs in
|
||||
its own namespace and does not have access outside it.
|
||||
This provides a layer of isolation: each aspect of a container runs in its own
|
||||
namespace and does not have access outside it.
|
||||
|
||||
Some of the namespaces that Docker uses are:
|
||||
|
||||
- **The `pid` namespace:**
|
||||
Used for process isolation (PID: Process ID).
|
||||
- **The `net` namespace:**
|
||||
Used for managing network interfaces (NET: Networking).
|
||||
- **The `ipc` namespace:**
|
||||
Used for managing access to IPC resources (IPC: InterProcess
|
||||
Communication).
|
||||
- **The `mnt` namespace:**
|
||||
Used for managing mount-points (MNT: Mount).
|
||||
- **The `uts` namespace:**
|
||||
Used for isolating kernel and version identifiers. (UTS: Unix Timesharing
|
||||
System).
|
||||
- **The `pid` namespace:** Used for process isolation (PID: Process ID).
|
||||
- **The `net` namespace:** Used for managing network interfaces (NET:
|
||||
Networking).
|
||||
- **The `ipc` namespace:** Used for managing access to IPC
|
||||
resources (IPC: InterProcess Communication).
|
||||
- **The `mnt` namespace:** Used for managing mount-points (MNT: Mount).
|
||||
- **The `uts` namespace:** Used for isolating kernel and version identifiers. (UTS: Unix
|
||||
Timesharing System).
|
||||
|
||||
### Control groups
|
||||
|
||||
Docker also makes use of another technology called `cgroups` or control
|
||||
groups. A key need to run applications in isolation is to have them only
|
||||
use the resources you want. This ensures containers are good
|
||||
multi-tenant citizens on a host. Control groups allow Docker to
|
||||
share available hardware resources to containers and if required, set up to
|
||||
limits and constraints, for example limiting the memory available to a
|
||||
specific container.
|
||||
Docker also makes use of another technology called `cgroups` or control groups.
|
||||
A key to running applications in isolation is to have them only use the
|
||||
resources you want. This ensures containers are good multi-tenant citizens on a
|
||||
host. Control groups allow Docker to share available hardware resources to
|
||||
containers and, if required, set up limits and constraints. For example,
|
||||
limiting the memory available to a specific container.
|
||||
|
||||
### Union file systems
|
||||
|
||||
Union file systems or UnionFS are file systems that operate by creating
|
||||
layers, making them very lightweight and fast. Docker uses union file
|
||||
systems to provide the building blocks for containers. We learned about
|
||||
union file systems earlier in this document. Docker can make use of
|
||||
several union file system variants including: AUFS, btrfs, vfs, and
|
||||
DeviceMapper.
|
||||
Union file systems, or UnionFS, are file systems that operate by creating layers,
|
||||
making them very lightweight and fast. Docker uses union file systems to provide
|
||||
the building blocks for containers. Docker can make use of several union file system variants
|
||||
including: AUFS, btrfs, vfs, and DeviceMapper.
|
||||
|
||||
### Container format
|
||||
|
||||
Docker combines these components into a wrapper we call a container
|
||||
format. The default container format is called `libcontainer`. Docker
|
||||
also supports traditional Linux containers using
|
||||
[LXC](https://linuxcontainers.org/). In future Docker may support other
|
||||
container formats, for example integration with BSD Jails or Solaris
|
||||
Zones.
|
||||
Docker combines these components into a wrapper we call a container format. The
|
||||
default container format is called `libcontainer`. Docker also supports
|
||||
traditional Linux containers using [LXC](https://linuxcontainers.org/). In the
|
||||
future, Docker may support other container formats, for example, by integrating with
|
||||
BSD Jails or Solaris Zones.
|
||||
|
||||
## Next steps
|
||||
|
||||
### Installing Docker
|
||||
|
||||
Visit the [installation](/installation/#installation) section.
|
||||
Visit the [installation section](/installation/#installation).
|
||||
|
||||
### The Docker User Guide
|
||||
|
||||
[Learn how to use Docker](/userguide/).
|
||||
[Learn Docker in depth](/userguide/).
|
||||
|
||||
|
||||
|
|
Loading…
Reference in a new issue