v1.4.7/website/docs/language/expressions/dynamic-blocks.mdx - terraform - Git at Google

 ---
 page_title: Dynamic Blocks - Configuration Language
 description: >-
   Dynamic blocks automatically construct multi-level, nested block structures.
   Learn to configure dynamic blocks and understand their behavior.
 ---

 # `dynamic` Blocks

 Within top-level block constructs like resources, expressions can usually be
 used only when assigning a value to an argument using the `name = expression`
 form. This covers many uses, but some resource types include repeatable _nested
 blocks_ in their arguments, which typically represent separate objects that
 are related to (or embedded within) the containing object:

 ```hcl
 resource "aws_elastic_beanstalk_environment" "tfenvtest" {
   name = "tf-test-name" # can use expressions here

   setting {
     # but the "setting" block is always a literal block
   }
 }
 ```

 You can dynamically construct repeatable nested blocks like `setting` using a
 special `dynamic` block type, which is supported inside `resource`, `data`,
 `provider`, and `provisioner` blocks:

 ```hcl
 resource "aws_elastic_beanstalk_environment" "tfenvtest" {
   name                = "tf-test-name"
   application         = "${aws_elastic_beanstalk_application.tftest.name}"
   solution_stack_name = "64bit Amazon Linux 2018.03 v2.11.4 running Go 1.12.6"

   dynamic "setting" {
     for_each = var.settings
     content {
       namespace = setting.value["namespace"]
       name = setting.value["name"]
       value = setting.value["value"]
     }
   }
 }
 ```

 A `dynamic` block acts much like a [`for` expression](/language/expressions/for), but produces
 nested blocks instead of a complex typed value. It iterates over a given
 complex value, and generates a nested block for each element of that complex
 value.

 - The label of the dynamic block (`"setting"` in the example above) specifies
   what kind of nested block to generate.
 - The `for_each` argument provides the complex value to iterate over.
 - The `iterator` argument (optional) sets the name of a temporary variable
   that represents the current element of the complex value. If omitted, the name
   of the variable defaults to the label of the `dynamic` block (`"setting"` in
   the example above).
 - The `labels` argument (optional) is a list of strings that specifies the block
   labels, in order, to use for each generated block. You can use the temporary
   iterator variable in this value.
 - The nested `content` block defines the body of each generated block. You can
   use the temporary iterator variable inside this block.

 Since the `for_each` argument accepts any collection or structural value,
 you can use a `for` expression or splat expression to transform an existing
 collection.

 The iterator object (`setting` in the example above) has two attributes:

 - `key` is the map key or list element index for the current element. If the
   `for_each` expression produces a _set_ value then `key` is identical to
   `value` and should not be used.
 - `value` is the value of the current element.

 A `dynamic` block can only generate arguments that belong to the resource type,
 data source, provider or provisioner being configured. It is _not_ possible
 to generate meta-argument blocks such as `lifecycle` and `provisioner`
 blocks, since Terraform must process these before it is safe to evaluate
 expressions.

 The `for_each` value must be a collection with one element per desired
 nested block. If you need to declare resource instances based on a nested
 data structure or combinations of elements from multiple data structures you
 can use Terraform expressions and functions to derive a suitable value.
 For some common examples of such situations, see the
 [`flatten`](/language/functions/flatten)
 and
 [`setproduct`](/language/functions/setproduct)
 functions.

 ## Multi-level Nested Block Structures

 Some providers define resource types that include multiple levels of blocks
 nested inside one another. You can generate these nested structures dynamically
 when necessary by nesting `dynamic` blocks in the `content` portion of other
 `dynamic` blocks.

 For example, a module might accept a complex data structure like the following:

 ```hcl
 variable "load_balancer_origin_groups" {
   type = map(object({
     origins = set(object({
       hostname = string
     }))
   }))
 }
 ```

 If you were defining a resource whose type expects a block for each origin
 group and then nested blocks for each origin within a group, you could ask
 Terraform to generate that dynamically using the following nested `dynamic`
 blocks:

 ```hcl
   dynamic "origin_group" {
     for_each = var.load_balancer_origin_groups
     content {
       name = origin_group.key

       dynamic "origin" {
         for_each = origin_group.value.origins
         content {
           hostname = origin.value.hostname
         }
       }
     }
   }
 ```

 When using nested `dynamic` blocks it's particularly important to pay attention
 to the iterator symbol for each block. In the above example,
 `origin_group.value` refers to the current element of the outer block, while
 `origin.value` refers to the current element of the inner block.

 If a particular resource type defines nested blocks that have the same type
 name as one of their parents, you can use the `iterator` argument in each of
 `dynamic` blocks to choose a different iterator symbol that makes the two
 easier to distinguish.

 ## Best Practices for `dynamic` Blocks

 Overuse of `dynamic` blocks can make configuration hard to read and maintain, so
 we recommend using them only when you need to hide details in order to build a
 clean user interface for a re-usable module. Always write nested blocks out
 literally where possible.

 If you find yourself defining most or all of a `resource` block's arguments and
 nested blocks using directly-corresponding attributes from an input variable
 then that might suggest that your module is not creating a useful abstraction.
 It may be better for the calling module to define the resource itself then
 pass information about it into your module. For more information on this design
 tradeoff, see [When to Write a Module](/language/modules/develop#when-to-write-a-module)
 and [Module Composition](/language/modules/develop/composition).
	---
	page_title: Dynamic Blocks - Configuration Language
	description: >-
	Dynamic blocks automatically construct multi-level, nested block structures.
	Learn to configure dynamic blocks and understand their behavior.
	---

	# `dynamic` Blocks

	Within top-level block constructs like resources, expressions can usually be
	used only when assigning a value to an argument using the `name = expression`
	form. This covers many uses, but some resource types include repeatable _nested
	blocks_ in their arguments, which typically represent separate objects that
	are related to (or embedded within) the containing object:

	```hcl
	resource "aws_elastic_beanstalk_environment" "tfenvtest" {
	name = "tf-test-name" # can use expressions here

	setting {
	# but the "setting" block is always a literal block
	}
	}
	```

	You can dynamically construct repeatable nested blocks like `setting` using a
	special `dynamic` block type, which is supported inside `resource`, `data`,
	`provider`, and `provisioner` blocks:

	```hcl
	resource "aws_elastic_beanstalk_environment" "tfenvtest" {
	name = "tf-test-name"
	application = "${aws_elastic_beanstalk_application.tftest.name}"
	solution_stack_name = "64bit Amazon Linux 2018.03 v2.11.4 running Go 1.12.6"

	dynamic "setting" {
	for_each = var.settings
	content {
	namespace = setting.value["namespace"]
	name = setting.value["name"]
	value = setting.value["value"]
	}
	}
	}
	```

	A `dynamic` block acts much like a [`for` expression](/language/expressions/for), but produces
	nested blocks instead of a complex typed value. It iterates over a given
	complex value, and generates a nested block for each element of that complex
	value.

	- The label of the dynamic block (`"setting"` in the example above) specifies
	what kind of nested block to generate.
	- The `for_each` argument provides the complex value to iterate over.
	- The `iterator` argument (optional) sets the name of a temporary variable
	that represents the current element of the complex value. If omitted, the name
	of the variable defaults to the label of the `dynamic` block (`"setting"` in
	the example above).
	- The `labels` argument (optional) is a list of strings that specifies the block
	labels, in order, to use for each generated block. You can use the temporary
	iterator variable in this value.
	- The nested `content` block defines the body of each generated block. You can
	use the temporary iterator variable inside this block.

	Since the `for_each` argument accepts any collection or structural value,
	you can use a `for` expression or splat expression to transform an existing
	collection.

	The iterator object (`setting` in the example above) has two attributes:

	- `key` is the map key or list element index for the current element. If the
	`for_each` expression produces a _set_ value then `key` is identical to
	`value` and should not be used.
	- `value` is the value of the current element.

	A `dynamic` block can only generate arguments that belong to the resource type,
	data source, provider or provisioner being configured. It is _not_ possible
	to generate meta-argument blocks such as `lifecycle` and `provisioner`
	blocks, since Terraform must process these before it is safe to evaluate
	expressions.

	The `for_each` value must be a collection with one element per desired
	nested block. If you need to declare resource instances based on a nested
	data structure or combinations of elements from multiple data structures you
	can use Terraform expressions and functions to derive a suitable value.
	For some common examples of such situations, see the
	[`flatten`](/language/functions/flatten)
	and
	[`setproduct`](/language/functions/setproduct)
	functions.

	## Multi-level Nested Block Structures

	Some providers define resource types that include multiple levels of blocks
	nested inside one another. You can generate these nested structures dynamically
	when necessary by nesting `dynamic` blocks in the `content` portion of other
	`dynamic` blocks.

	For example, a module might accept a complex data structure like the following:

	```hcl
	variable "load_balancer_origin_groups" {
	type = map(object({
	origins = set(object({
	hostname = string
	}))
	}))
	}
	```

	If you were defining a resource whose type expects a block for each origin
	group and then nested blocks for each origin within a group, you could ask
	Terraform to generate that dynamically using the following nested `dynamic`
	blocks:

	```hcl
	dynamic "origin_group" {
	for_each = var.load_balancer_origin_groups
	content {
	name = origin_group.key

	dynamic "origin" {
	for_each = origin_group.value.origins
	content {
	hostname = origin.value.hostname
	}
	}
	}
	}
	```

	When using nested `dynamic` blocks it's particularly important to pay attention
	to the iterator symbol for each block. In the above example,
	`origin_group.value` refers to the current element of the outer block, while
	`origin.value` refers to the current element of the inner block.

	If a particular resource type defines nested blocks that have the same type
	name as one of their parents, you can use the `iterator` argument in each of
	`dynamic` blocks to choose a different iterator symbol that makes the two
	easier to distinguish.

	## Best Practices for `dynamic` Blocks

	Overuse of `dynamic` blocks can make configuration hard to read and maintain, so
	we recommend using them only when you need to hide details in order to build a
	clean user interface for a re-usable module. Always write nested blocks out
	literally where possible.

	If you find yourself defining most or all of a `resource` block's arguments and
	nested blocks using directly-corresponding attributes from an input variable
	then that might suggest that your module is not creating a useful abstraction.
	It may be better for the calling module to define the resource itself then
	pass information about it into your module. For more information on this design
	tradeoff, see [When to Write a Module](/language/modules/develop#when-to-write-a-module)
	and [Module Composition](/language/modules/develop/composition).