718 lines
28 KiB
Markdown
718 lines
28 KiB
Markdown
---
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layout: "docs"
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page_title: "Resources - Configuration Language"
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sidebar_current: "docs-config-resources"
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description: |-
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Resources are the most important element in a Terraform configuration.
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Each resource corresponds to an infrastructure object, such as a virtual
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network or compute instance.
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---
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# Resources
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-> **Note:** This page is about Terraform 0.12 and later. For Terraform 0.11 and
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earlier, see
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[0.11 Configuration Language: Resources](../configuration-0-11/resources.html).
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_Resources_ are the most important element in the Terraform language.
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Each resource block describes one or more infrastructure objects, such
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as virtual networks, compute instances, or higher-level components such
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as DNS records.
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## Resource Syntax
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Resource declarations can include a number of advanced features, but only
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a small subset are required for initial use. More advanced syntax features,
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such as single resource declarations that produce multiple similar remote
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objects, are described later in this page.
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```hcl
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resource "aws_instance" "web" {
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ami = "ami-a1b2c3d4"
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instance_type = "t2.micro"
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}
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```
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A `resource` block declares a resource of a given type ("aws_instance")
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with a given local name ("web"). The name is used to refer to this resource
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from elsewhere in the same Terraform module, but has no significance outside
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of the scope of a module.
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The resource type and name together serve as an identifier for a given
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resource and so must be unique within a module.
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Within the block body (between `{` and `}`) are the configuration arguments
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for the resource itself. Most arguments in this section depend on the
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resource type, and indeed in this example both `ami` and `instance_type` are
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arguments defined specifically for [the `aws_instance` resource type](/docs/providers/aws/r/instance.html).
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-> **Note:** Resource names must start with a letter or underscore, and may
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contain only letters, digits, underscores, and dashes.
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## Resource Types and Arguments
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Each resource is associated with a single _resource type_, which determines
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the kind of infrastructure object it manages and what arguments and other
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attributes the resource supports.
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Each resource type in turn belongs to a [provider](./providers.html),
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which is a plugin for Terraform that offers a collection of resource types. A
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provider usually provides resources to manage a single cloud or on-premises
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infrastructure platform.
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Most of the items within the body of a `resource` block are specific to the
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selected resource type. These arguments can make full use of
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[expressions](./expressions.html) and other dynamic Terraform
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language features.
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There are also some _meta-arguments_ that are defined by Terraform itself
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and apply across all resource types. (See [Meta-Arguments](#meta-arguments) below.)
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### Documentation for Resource Types
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[Terraform's provider documentation][providers] is the primary place to
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learn which resource types are available and which arguments to use for each
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resource type. Once you understand Terraform's basic syntax, the provider
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documentation will be where you spend the majority of your time on this website.
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The "[Providers][]" link at the top level of the navigation sidebar will take
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you to an alphabetical list of all of the providers distributed by HashiCorp.
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You can find a specific provider in this master list, or choose a category from
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the navigation sidebar to browse a more focused list of providers.
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You can also search GitHub or other sources for third-party providers, which can
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be installed as plugins to enable an even broader selection of resource types.
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[providers]: /docs/providers/index.html
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## Resource Behavior
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A `resource` block describes your intent for a particular infrastructure object
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to exist with the given settings. If you are writing a new configuration for
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the first time, the resources it defines will exist _only_ in the configuration,
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and will not yet represent real infrastructure objects in the target platform.
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_Applying_ a Terraform configuration is the process of creating, updating,
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and destroying real infrastructure objects in order to make their settings
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match the configuration.
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When Terraform creates a new infrastructure object represented by a `resource`
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block, the identifier for that real object is saved in Terraform's
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[state](/docs/state/index.html), allowing it to be updated and destroyed
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in response to future changes. For resource blocks that already have an
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associated infrastructure object in the state, Terraform compares the
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actual configuration of the object with the arguments given in the
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configuration and, if necessary, updates the object to match the configuration.
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This general behavior applies for all resources, regardless of type. The
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details of what it means to create, update, or destroy a resource are different
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for each resource type, but this standard set of verbs is common across them
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all.
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The meta-arguments within `resource` blocks, documented in the
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sections below, allow some details of this standard resource behavior to be
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customized on a per-resource basis.
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### Resource Dependencies
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Most resources in a configuration don't have any particular relationship, and
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Terraform can make changes to several unrelated resources in parallel.
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However, some resources must be processed after other specific resources;
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sometimes this is because of how the resource works, and sometimes the
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resource's configuration just requires information generated by another
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resource.
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Most resource dependencies are handled automatically. Terraform analyses any
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[expressions](./expressions.html) within a `resource` block to find references
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to other objects, and treats those references as implicit ordering requirements
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when creating, updating, or destroying resources. Since most resources with
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behavioral dependencies on other resources also refer to those resources' data,
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it's usually not necessary to manually specify dependencies between resources.
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However, some dependencies cannot be recognized implicitly in configuration. For
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example, if Terraform must manage access control policies _and_ take actions
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that require those policies to be present, there is a hidden dependency between
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the access policy and a resource whose creation depends on it. In these rare
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cases, [the `depends_on` meta-argument][inpage-depend] can explicitly specify a
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dependency.
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## Meta-Arguments
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Terraform CLI defines the following meta-arguments, which can be used with
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any resource type to change the behavior of resources:
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- [`depends_on`, for specifying hidden dependencies][inpage-depend]
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- [`count`, for creating multiple resource instances according to a count][inpage-count]
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- [`for_each`, to create multiple instances according to a map, or set of strings][inpage-for_each]
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- [`provider`, for selecting a non-default provider configuration][inpage-provider]
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- [`lifecycle`, for lifecycle customizations][inpage-lifecycle]
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- [`provisioner` and `connection`, for taking extra actions after resource creation][inpage-provisioner]
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These arguments often have additional restrictions on what language features can
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be used with them, which are described in each
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### `depends_on`: Explicit Resource Dependencies
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[inpage-depend]: #depends_on-explicit-resource-dependencies
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Use the `depends_on` meta-argument to handle hidden resource dependencies that
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Terraform can't automatically infer.
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Explicitly specifying a dependency is only necessary when a resource relies on
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some other resource's behavior but _doesn't_ access any of that resource's data
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in its arguments.
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This argument is available in all `resource` blocks, regardless of resource
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type. For example:
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```hcl
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resource "aws_iam_role" "example" {
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name = "example"
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# assume_role_policy is omitted for brevity in this example. See the
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# documentation for aws_iam_role for a complete example.
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assume_role_policy = "..."
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}
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resource "aws_iam_instance_profile" "example" {
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# Because this expression refers to the role, Terraform can infer
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# automatically that the role must be created first.
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role = aws_iam_role.example.name
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}
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resource "aws_iam_role_policy" "example" {
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name = "example"
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role = aws_iam_role.example.name
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policy = jsonencode({
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"Statement" = [{
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# This policy allows software running on the EC2 instance to
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# access the S3 API.
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"Action" = "s3:*",
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"Effect" = "Allow",
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}],
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})
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}
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resource "aws_instance" "example" {
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ami = "ami-a1b2c3d4"
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instance_type = "t2.micro"
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# Terraform can infer from this that the instance profile must
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# be created before the EC2 instance.
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iam_instance_profile = aws_iam_instance_profile.example
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# However, if software running in this EC2 instance needs access
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# to the S3 API in order to boot properly, there is also a "hidden"
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# dependency on the aws_iam_role_policy that Terraform cannot
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# automatically infer, so it must be declared explicitly:
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depends_on = [
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aws_iam_role_policy.example,
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]
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}
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```
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The `depends_on` meta-argument, if present, must be a list of references
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to other resources in the same module. Arbitrary expressions are not allowed
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in the `depends_on` argument value, because its value must be known before
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Terraform knows resource relationships and thus before it can safely
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evaluate expressions.
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The `depends_on` argument should be used only as a last resort. When using it,
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always include a comment explaining why it is being used, to help future
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maintainers understand the purpose of the additional dependency.
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### `count`: Multiple Resource Instances By Count
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[inpage-count]: #count-multiple-resource-instances-by-count
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-> **Note:** A given resource block cannot use both `count` and `for_each`.
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By default, a `resource` block configures one real infrastructure object.
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However, sometimes you want to manage several similar objects, such as a fixed
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pool of compute instances. Terraform has two ways to do this:
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`count` and [`for_each`][inpage-for_each].
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The `count` meta-argument accepts a whole number, and creates that many
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instances of the resource. Each instance has a distinct infrastructure object
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associated with it (as described above in
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[Resource Behavior](#resource-behavior)), and each is separately created,
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updated, or destroyed when the configuration is applied.
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```hcl
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resource "aws_instance" "server" {
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count = 4 # create four similar EC2 instances
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ami = "ami-a1b2c3d4"
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instance_type = "t2.micro"
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tags = {
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Name = "Server ${count.index}"
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}
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}
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```
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#### The `count` Object
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In resource blocks where `count` is set, an additional `count` object is
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available in expressions, so you can modify the configuration of each instance.
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This object has one attribute:
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- `count.index` — The distinct index number (starting with `0`) corresponding
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to this instance.
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#### Referring to Instances
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When `count` is set, Terraform distinguishes between the resource block itself
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and the multiple _resource instances_ associated with it. Instances are
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identified by an index number, starting with `0`.
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- `<TYPE>.<NAME>` (for example, `aws_instance.server`) refers to the resource block.
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- `<TYPE>.<NAME>[<INDEX>]` (for example, `aws_instance.server[0]`,
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`aws_instance.server[1]`, etc.) refers to individual instances.
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This is different from resources without `count` or `for_each`, which can be
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referenced without an index or key.
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-> **Note:** Within nested `provisioner` or `connection` blocks, the special
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`self` object refers to the current _resource instance,_ not the resource block
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as a whole.
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#### Using Expressions in `count`
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The `count` meta-argument accepts numeric [expressions](./expressions.html).
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However, unlike most resource arguments, the `count` value must be known
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_before_ Terraform performs any remote resource actions. This means `count`
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can't refer to any resource attributes that aren't known until after a
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configuration is applied (such as a unique ID generated by the remote API when
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an object is created).
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#### When to Use `for_each` Instead of `count`
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If your resource instances are almost identical, `count` is appropriate. If some
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of their arguments need distinct values that can't be directly derived from an
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integer, it's safer to use `for_each`.
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Before `for_each` was available, it was common to derive `count` from the
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length of a list and use `count.index` to look up the original list value:
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```hcl
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variable "subnet_ids" {
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type = list(string)
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}
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resource "aws_instance" "server" {
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# Create one instance for each subnet
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count = length(var.subnet_ids)
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ami = "ami-a1b2c3d4"
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instance_type = "t2.micro"
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subnet_id = var.subnet_ids[count.index]
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tags = {
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Name = "Server ${count.index}"
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}
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}
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```
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This was fragile, because the resource instances were still identified by their
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_index_ instead of the string values in the list. If an element was removed from
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the middle of the list, every instance _after_ that element would see its
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`subnet_id` value change, resulting in more remote object changes than intended.
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Using `for_each` gives the same flexibility without the extra churn.
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### `for_each`: Multiple Resource Instances Defined By a Map, or Set of Strings
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[inpage-for_each]: #for_each-multiple-resource-instances-defined-by-a-map-or-set-of-strings
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-> **Version note:** `for_each` was added in Terraform 0.12.6.
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-> **Note:** A given resource block cannot use both `count` and `for_each`.
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By default, a `resource` block configures one real infrastructure object.
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However, sometimes you want to manage several similar objects, such as a fixed
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pool of compute instances. Terraform has two ways to do this:
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[`count`][inpage-count] and `for_each`.
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The `for_each` meta-argument accepts a map or a set of strings, and creates an
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instance for each item in that map or set. Each instance has a distinct
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infrastructure object associated with it (as described above in
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[Resource Behavior](#resource-behavior)), and each is separately created,
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updated, or destroyed when the configuration is applied.
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-> **Note:** The keys of the map (or all the values in the case of a set of strings) must
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be _known values_, or you will get an error message that `for_each` has dependencies
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that cannot be determined before apply, and a `-target` may be needed. `for_each` keys
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cannot be the result (or rely on the result of) of impure functions, including `uuid`, `bcrypt`,
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or `timestamp`, as their evaluation is deferred resource during evaluation.
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Map:
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```hcl
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resource "azurerm_resource_group" "rg" {
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for_each = {
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a_group = "eastus"
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another_group = "westus2"
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}
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name = each.key
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location = each.value
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}
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```
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Set of strings:
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```hcl
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resource "aws_iam_user" "the-accounts" {
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for_each = toset( ["Todd", "James", "Alice", "Dottie"] )
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name = each.key
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}
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```
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#### The `each` Object
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In resource blocks where `for_each` is set, an additional `each` object is
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available in expressions, so you can modify the configuration of each instance.
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This object has two attributes:
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- `each.key` — The map key (or set member) corresponding to this instance.
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- `each.value` — The map value corresponding to this instance. (If a set was
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provided, this is the same as `each.key`.)
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#### Using Expressions in `for_each`
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The `for_each` meta-argument accepts map or set [expressions](./expressions.html).
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However, unlike most resource arguments, the `for_each` value must be known
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_before_ Terraform performs any remote resource actions. This means `for_each`
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can't refer to any resource attributes that aren't known until after a
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configuration is applied (such as a unique ID generated by the remote API when
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an object is created).
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The `for_each` value must be a map or set with one element per desired
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resource instance. If you need to declare resource instances based on a nested
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data structure or combinations of elements from multiple data structures you
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can use Terraform expressions and functions to derive a suitable value.
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For example:
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* Transform a multi-level nested structure into a flat list by
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[using nested `for` expressions with the `flatten` function](./functions/flatten.html#flattening-nested-structures-for-for_each).
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* Produce an exhaustive list of combinations of elements from two or more
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collections by
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[using the `setproduct` function inside a `for` expression](./functions/setproduct.html#finding-combinations-for-for_each).
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#### Referring to Instances
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When `for_each` is set, Terraform distinguishes between the resource block itself
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and the multiple _resource instances_ associated with it. Instances are
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identified by a map key (or set member) from the value provided to `for_each`.
|
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- `<TYPE>.<NAME>` (for example, `azurerm_resource_group.rg`) refers to the resource block.
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- `<TYPE>.<NAME>[<KEY>]` (for example, `azurerm_resource_group.rg["a_group"]`,
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`azurerm_resource_group.rg["another_group"]`, etc.) refers to individual instances.
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This is different from resources without `count` or `for_each`, which can be
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referenced without an index or key.
|
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|
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-> **Note:** Within nested `provisioner` or `connection` blocks, the special
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`self` object refers to the current _resource instance,_ not the resource block
|
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as a whole.
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#### Using Sets
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The Terraform language doesn't have a literal syntax for
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[set values](./types.html#collection-types), but you can use the `toset`
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function to explicitly convert a list of strings to a set:
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```hcl
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locals {
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subnet_ids = toset([
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"subnet-abcdef",
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"subnet-012345",
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])
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}
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resource "aws_instance" "server" {
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for_each = local.subnet_ids
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ami = "ami-a1b2c3d4"
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instance_type = "t2.micro"
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subnet_id = each.key # note: each.key and each.value are the same for a set
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tags = {
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Name = "Server ${each.key}"
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}
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}
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```
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Conversion from list to set discards the ordering of the items in the list and
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removes any duplicate elements. `toset(["b", "a", "b"])` will produce a set
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containing only `"a"` and `"b"` in no particular order; the second `"b"` is
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discarded.
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If you are writing a module with an [input variable](./variables.html) that
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will be used as a set of strings for `for_each`, you can set its type to
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`set(string)` to avoid the need for an explicit type conversion:
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|
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```
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variable "subnet_ids" {
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type = set(string)
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}
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resource "aws_instance" "server" {
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for_each = var.subnet_ids
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# (and the other arguments as above)
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}
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```
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### `provider`: Selecting a Non-default Provider Configuration
|
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[inpage-provider]: #provider-selecting-a-non-default-provider-configuration
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|
||
As described in [the Providers page](./providers.html),
|
||
Terraform optionally allows the definition of multiple alternative ("aliased")
|
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configurations for a single provider, to allow management of resources
|
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in different regions in multi-region services, etc.
|
||
The `provider` meta-argument overrides Terraform's default behavior of
|
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selecting a provider configuration based on the resource type name.
|
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|
||
By default, Terraform takes the initial word in the resource type name
|
||
(separated by underscores) and selects the default configuration for that
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named provider. For example, the resource type `google_compute_instance`
|
||
is associated automatically with the default configuration for the provider
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named `google`.
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|
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By using the `provider` meta-argument, an aliased provider configuration
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can be selected:
|
||
|
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```hcl
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# default configuration
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provider "google" {
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region = "us-central1"
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}
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# alternative, aliased configuration
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||
provider "google" {
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alias = "europe"
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region = "europe-west1"
|
||
}
|
||
|
||
resource "google_compute_instance" "example" {
|
||
# This "provider" meta-argument selects the google provider
|
||
# configuration whose alias is "europe", rather than the
|
||
# default configuration.
|
||
provider = google.europe
|
||
|
||
# ...
|
||
}
|
||
```
|
||
|
||
A resource always has an implicit dependency on its associated provider, to
|
||
ensure that the provider is fully configured before any resource actions
|
||
are taken.
|
||
|
||
The `provider` meta-argument expects [a `<PROVIDER>.<ALIAS>` reference](./providers.html#referring-to-alternate-providers), which
|
||
does not need to be quoted. Arbitrary expressions are not permitted for
|
||
`provider` because it must be resolved while Terraform is constructing the
|
||
dependency graph, before it is safe to evaluate expressions.
|
||
|
||
### `lifecycle`: Lifecycle Customizations
|
||
|
||
[inpage-lifecycle]: #lifecycle-lifecycle-customizations
|
||
|
||
The general lifecycle for resources is described above in the
|
||
[Resource Behavior](#resource-behavior) section. Some details of that behavior
|
||
can be customized using the special nested `lifecycle` block within a resource
|
||
block body:
|
||
|
||
```
|
||
resource "azurerm_resource_group" "example" {
|
||
# ...
|
||
|
||
lifecycle {
|
||
create_before_destroy = true
|
||
}
|
||
}
|
||
```
|
||
|
||
The `lifecycle` block and its contents are meta-arguments, available
|
||
for all `resource` blocks regardless of type. The following lifecycle
|
||
meta-arguments are supported:
|
||
|
||
* `create_before_destroy` (bool) - By default, when Terraform must make a
|
||
change to a resource argument that cannot be updated in-place due to
|
||
remote API limitations, Terraform will instead destroy the existing object
|
||
and then create a new replacement object with the new configured arguments.
|
||
|
||
The `create_before_destroy` meta-argument changes this behavior so that
|
||
the new replacement object is created _first,_ and then the prior object
|
||
is destroyed only once the replacement is created.
|
||
|
||
This is an opt-in behavior because many remote object types have unique
|
||
name requirements or other constraints that must be accommodated for
|
||
both a new and an old object to exist concurrently. Some resource types
|
||
offer special options to append a random suffix onto each object name to
|
||
avoid collisions, for example. Terraform CLI cannot automatically activate
|
||
such features, so you must understand the constraints for each resource
|
||
type before using `create_before_destroy` with it.
|
||
|
||
* `prevent_destroy` (bool) - This meta-argument, when set to `true`, will
|
||
cause Terraform to reject with an error any plan that would destroy the
|
||
infrastructure object associated with the resource, as long as the argument
|
||
remains present in the configuration.
|
||
|
||
This can be used as a measure of safety against the accidental replacement
|
||
of objects that may be costly to reproduce, such as database instances.
|
||
However, it will make certain configuration changes impossible to apply,
|
||
and will prevent the use of the `terraform destroy` command once such
|
||
objects are created, and so this option should be used sparingly.
|
||
|
||
Since this argument must be present in configuration for the protection to
|
||
apply, note that this setting does not prevent the remote object from
|
||
being destroyed if the `resource` block were removed from configuration
|
||
entirely: in that case, the `prevent_destroy` setting is removed along
|
||
with it, and so Terraform will allow the destroy operation to succeed.
|
||
|
||
* `ignore_changes` (list of attribute names) - By default, Terraform detects
|
||
any difference in the current settings of a real infrastructure object
|
||
and plans to update the remote object to match configuration.
|
||
|
||
In some rare cases, settings of a remote object are modified by processes
|
||
outside of Terraform, which Terraform would then attempt to "fix" on the
|
||
next run. In order to make Terraform share management responsibilities
|
||
of a single object with a separate process, the `ignore_changes`
|
||
meta-argument specifies resource attributes that Terraform should ignore
|
||
when planning updates to the associated remote object.
|
||
|
||
The arguments corresponding to the given attribute names are considered
|
||
when planning a _create_ operation, but are ignored when planning an
|
||
_update_.
|
||
|
||
```hcl
|
||
resource "aws_instance" "example" {
|
||
# ...
|
||
|
||
lifecycle {
|
||
ignore_changes = [
|
||
# Ignore changes to tags, e.g. because a management agent
|
||
# updates these based on some ruleset managed elsewhere.
|
||
tags,
|
||
]
|
||
}
|
||
}
|
||
```
|
||
|
||
You can also ignore specific map elements by writing references like
|
||
`tags["Name"]` in the `ignore_changes` list, though with an important
|
||
caveat: the ignoring applies only to in-place updates to an existing
|
||
key. Adding or removing a key is treated by Terraform as a change to the
|
||
containing map itself rather than to the individual key, and so if you
|
||
wish to ignore changes to a particular tag made by an external system
|
||
you must ensure that the Terraform configuration creates a placeholder
|
||
element for that tag name so that the external system changes will be
|
||
understood as an in-place edit of that key:
|
||
|
||
```hcl
|
||
resource "aws_instance" "example" {
|
||
# ...
|
||
|
||
tags = {
|
||
# Initial value for Name is overridden by our automatic scheduled
|
||
# re-tagging process; changes to this are ignored by ignore_changes
|
||
# below.
|
||
Name = "placeholder"
|
||
}
|
||
|
||
lifecycle {
|
||
ignore_changes = [
|
||
tags["Name"],
|
||
]
|
||
}
|
||
}
|
||
```
|
||
|
||
Instead of a list, the special keyword `all` may be used to instruct
|
||
Terraform to ignore _all_ attributes, which means that Terraform can
|
||
create and destroy the remote object but will never propose updates to it.
|
||
|
||
Only attributes defined by the resource type can be ignored.
|
||
`ignore_changes` cannot be applied to itself or to any other meta-arguments.
|
||
|
||
The `lifecycle` settings all effect how Terraform constructs and traverses
|
||
the dependency graph. As a result, only literal values can be used because
|
||
the processing happens too early for arbitrary expression evaluation.
|
||
|
||
### `provisioner` and `connection`: Resource Provisioners
|
||
|
||
[inpage-provisioner]: #provisioner-and-connection-resource-provisioners
|
||
|
||
Some infrastructure objects require some special actions to be taken after they
|
||
are created before they can become fully functional. For example, compute
|
||
instances may require configuration to be uploaded or a configuration management
|
||
program to be run before they can begin their intended operation.
|
||
|
||
Create-time actions like these can be described using _resource provisioners_.
|
||
A provisioner is another type of plugin supported by Terraform, and each
|
||
provisioner takes a different kind of action in the context of a resource
|
||
being created.
|
||
|
||
Provisioning steps should be used sparingly, since they represent
|
||
non-declarative actions taken during the creation of a resource and so
|
||
Terraform is not able to model changes to them as it can for the declarative
|
||
portions of the Terraform language.
|
||
|
||
Provisioners can also be defined to run when a resource is _destroyed_, with
|
||
certain limitations.
|
||
|
||
The `provisioner` and `connection` block types within `resource` blocks are
|
||
meta-arguments available across all resource types. Provisioners and their
|
||
usage are described in more detail in
|
||
[the Provisioners section](/docs/provisioners/index.html).
|
||
|
||
## Local-only Resources
|
||
|
||
While most resource types correspond to an infrastructure object type that
|
||
is managed via a remote network API, there are certain specialized resource
|
||
types that operate only within Terraform itself, calculating some results and
|
||
saving those results in the state for future use.
|
||
|
||
For example, local-only resource types exist for
|
||
[generating private keys](/docs/providers/tls/r/private_key.html),
|
||
[issuing self-signed TLS certificates](/docs/providers/tls/r/self_signed_cert.html),
|
||
and even [generating random ids](/docs/providers/random/r/id.html).
|
||
While these resource types often have a more marginal purpose than those
|
||
managing "real" infrastructure objects, they can be useful as glue to help
|
||
connect together other resources.
|
||
|
||
The behavior of local-only resources is the same as all other resources, but
|
||
their result data exists only within the Terraform state. "Destroying" such
|
||
a resource means only to remove it from the state, discarding its data.
|
||
|
||
## Operation Timeouts
|
||
|
||
Some resource types provide a special `timeouts` nested block argument that
|
||
allows you to customize how long certain operations are allowed to take
|
||
before being considered to have failed.
|
||
For example, [`aws_db_instance`](/docs/providers/aws/r/db_instance.html)
|
||
allows configurable timeouts for `create`, `update` and `delete` operations.
|
||
|
||
Timeouts are handled entirely by the resource type implementation in the
|
||
provider, but resource types offering these features follow the convention
|
||
of defining a child block called `timeouts` that has a nested argument
|
||
named after each operation that has a configurable timeout value.
|
||
Each of these arguments takes a string representation of a duration, such
|
||
as `"60m"` for 60 minutes, `"10s"` for ten seconds, or `"2h"` for two hours.
|
||
|
||
```hcl
|
||
resource "aws_db_instance" "example" {
|
||
# ...
|
||
|
||
timeouts {
|
||
create = "60m"
|
||
delete = "2h"
|
||
}
|
||
}
|
||
```
|
||
|
||
The set of configurable operations is chosen by each resource type. Most
|
||
resource types do not support the `timeouts` block at all. Consult the
|
||
documentation for each resource type to see which operations it offers
|
||
for configuration, if any.
|