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---
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layout: "intro"
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page_title: "Use Cases"
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sidebar_current: "use-cases"
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---
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# Use Cases
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Before understanding use cases, it's useful to know [what Terraform is](/intro/index.html).
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This page lists some concrete use cases for Terraform, but the possible use cases are
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much broader than what we cover. Due to its extensible nature, providers and provisioners
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can be added to further extend Terraform's ability to manipulate resources.
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#### Heroku App Setup
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Heroku is a popular PaaS for hosting web apps. Developers create an app, and then
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attach add-ons, such as a database, or email provider. One of the best features it
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the ability to elastically scale the number of dynos or workers. However, most
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non-trivial applications quickly need many add-ons and external services.
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Terraform can be used to codify the setup required for a Heroku application, ensuring
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that all the required add-ons are available but it can go even further, configuring
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DNSimple to set a CNAME, or setting up CloudFlare as a CDN for the
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app. Best of all, Terraform can do all of this without using a web interface in
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under 30 seconds.
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#### Multi-Tier Applications
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A very common pattern is the N-tier architecture. The most common 2-tier architecture is
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a pool of web servers that use a database tier. Additional tiers get added for API servers,
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caching servers, routing meshes, etc. This pattern is used because the tiers can be scaled
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independently and provide a separation of concerns.
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Terraform is an ideal tool for building and managing these infrastructures. Each tier can
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be described as a collection of resources, and the dependencies between each tier is handled
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automatically; Terraform will ensure the database tier is available before the web servers
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are started and that the load balancers are aware of the web nodes. Each tier can then be
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scaled easily using Terraform by modifying a single `count` configuration value. Because
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the creation and provisioning of a resource is codified and automated, elastically scaling
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with load becomes trivial.
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#### Self-Service Clusters
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At a certain organizational size, it becomes very challenging for a centralized
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operations team to manage a large and growing infrastructure. Instead it becomes
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more attractive to make "self-serve" infrastructure, allowing product teams to
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manage their own infrastructure using tooling provided by the central operations team.
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Using Terraform, the knowledge of how to build and scale a service can be codified
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in a configuration. Terraform configurations can be shared within an organization
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enabling customer teams to use the configuration as a black box and use Terraform as
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a tool to manage their services.
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#### Software Demos
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Modern software is increasing networked and distributed. Although there exists
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tools like [Vagrant](http://www.vagrantup.com/) to build virtualized environments
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for demos, it is still very challenging to demo software on real infrastructure
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which more closely match production environments.
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Sofware writers can provide a Terraform configuration to create, provision and
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bootstrap a demo on cloud providers like AWS. This allows end users to easily demo
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the software on their own infrastructure, and even enables tweaking parameters like
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cluster size to more rigorously test tools at any scale.
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#### Disposable Environments
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It is common practice to have both a production and staging or QA environment.
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These environments are smaller clones of their production counterpart, but are
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used to test new applications before releasing in production. As the production
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environment grows larger and more complex, it becomes increasingly onerous to
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maintain an up-to-date staging environment.
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Using Terraform, the production environment can codified and then shared with
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staging, QA or dev. These configurations can be used to rapidly spin up new
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environments to test in, and then easily disposed of. Terraform can help tame
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the difficulty of maintaining parallel environments, and makes it practical
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to elastically create and destroy them.
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#### Software Defined Networking
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Software Defined Networking (SDN) is becoming increasingly prevalent in the
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datacenter, as it provides more control to operators and developers and
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allows the network to better support the applications running on top. Most SDN
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implementations have a control layer and infrastructure layer.
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Terraform can be used to codify the configuration for software defined networks.
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This configuration can then be used by Terraform to to automatically setup and modify
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settings by interfacing with the control layer. This allows configuration to be
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versioned and changes to be automated. As an example, [AWS VPC](http://aws.amazon.com/vpc/)
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is one of the most commonly used SDN implementations, and [can be configured by
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Terraform](/docs/providers/aws/r/vpc.html).
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#### Resource Schedulers
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In large scale infrastructures, static assignment of applications to machines
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becomes increasingly challenging. To solve that problem, there are a number
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of schedulers like Borg, Mesos, YARN, and Kubernetes. These can be used to
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dynamically schedule Docker containers, Hadoop, Spark, and many other software
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tools.
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Terraform is not limited to physical providers like AWS. Resource schedulers
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can be treated as a provider, allowing Terraform to request resources from them.
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This allows Terraform to be used in layers: to setup the physical infrastructure
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running the schedulers as well as onto the scheduled grid.
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#### Multi-Cloud Deployment
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It's often attractive to spread infrastructure across multiple clouds to increase
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fault-tolerance. By using only a single region or cloud provider, fault tolerance
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is limited by the availability of that provider. Having a multi-cloud deployment
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allows for more graceful recovery of the loss of a region or entire provider.
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Realizing multi-cloud deployments can be very challenging as many existing tools
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for infrastructure management are cloud-specific. Terraform is cloud agnostic,
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and allows a single configuration to be used to manage multiple providers, and
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to even handle cross-cloud dependcies. This simplifies management and orchestration,
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helping operators build large scale multi-cloud infrastructures.
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