--- layout: "docs" page_title: "JSON Configuration Syntax - Configuration Language" sidebar_current: "docs-config-json-syntax" description: |- In addition to the native syntax that is most commonly used with Terraform, the Terraform language can also be expressed in a JSON-compatible syntax. --- # JSON Configuration Syntax -> **Note:** This page is about Terraform 0.12 and later. The JSON configuration syntax in 0.11 and earlier was never formally documented. For other information about Terraform 0.11 and earlier, see [0.11 Configuration Language](../configuration-0-11/index.html). Most Terraform configurations are written in [the native Terraform language syntax](./syntax.html), which is designed to be easy for humans to read and update. Terraform also supports an alternative syntax that is JSON-compatible. This syntax is useful when generating portions of a configuration programmatically, since existing JSON libraries can be used to prepare the generated configuration files. The JSON syntax is defined in terms of the native syntax. Everything that can be expressed in native syntax can also be expressed in JSON syntax, but some constructs are more complex to represent in JSON due to limitations of the JSON grammar. Terraform expects native syntax for files named with a `.tf` suffix, and JSON syntax for files named with a `.tf.json` suffix. The low-level JSON syntax, just as with the native syntax, is defined in terms of a specification called _HCL_. It is not necessary to know all of the details of HCL syntax or its JSON mapping in order to use Terraform, and so this page summarizes the most important differences between native and JSON syntax. If you are interested, you can find a full definition of HCL's JSON syntax in [its specification](https://github.com/hashicorp/hcl2/blob/master/hcl/json/spec.md). ## JSON File Structure At the root of any JSON-based Terraform configuration is a JSON object. The properties of this object correspond to the top-level block types of the Terraform language. For example: ```json { "variable": { "example": { "default": "hello" } } } ``` Each top-level object property must match the name of one of the expected top-level block types. Block types that expect labels, such as `variable` shown above, are represented by one nested object value for each level of label. `resource` blocks expect two labels, so two levels of nesting are required: ```json { "resource": { "aws_instance": { "example": { "instance_type": "t2.micro", "ami": "ami-abc123" } } } } ``` After any nested objects representing the labels, finally one more nested object represents the body of the block itself. In the above examples, the `default` argument for `variable "example"` and the `instance_type` and `ami` arguments for `resource "aws_instance" "example"` are specified. Taken together, the above two configuration files are equivalent to the following blocks in the native syntax: ```hcl variable "example" { default = "hello" } resource "aws_instance" "example" { instance_type = "t2.micro" ami = "ami-abc123" } ``` Within each top-level block type the rules for mapping to JSON are slightly different (see [Block-type-specific Exceptions][inpage-exceptions] below), but the following general rules apply in most cases: * The JSON object representing the block body contains properties that correspond either to argument names or to nested block type names. * Where a property corresponds to an argument that accepts [arbitrary expressions](./expressions.html) in the native syntax, the property value is mapped to an expression as described under [_Expression Mapping_](#expression-mapping) below. For arguments that do _not_ accept arbitrary expressions, the interpretation of the property value depends on the argument, as described in the [block-type-specific exceptions](#block-type-specific-exceptions) given later in this page. * Where a property name corresponds to an expected nested block type name, the value is interpreted as described under [_Nested Block Mapping_](#nested-block-mapping) below, unless otherwise stated in [the block-type-specific exceptions](#block-type-specific-exceptions) given later in this page. ## Expression Mapping Since JSON grammar is not able to represent all of the Terraform language [expression syntax](./expressions.html), JSON values interpreted as expressions are mapped as follows: | JSON | Terraform Language Interpretation | | ------- | ------------------------------------------------------------------------------------------------------------- | | Boolean | A literal `bool` value. | | Number | A literal `number` value. | | String | Parsed as a [string template](./expressions.html#string-templates) and then evaluated as described below. | | Object | Each property value is mapped per this table, producing an `object(...)` value with suitable attribute types. | | Array | Each element is mapped per this table, producing a `tuple(...)` value with suitable element types. | | Null | A literal `null`. | When a JSON string is encountered in a location where arbitrary expressions are expected, its value is first parsed as a [string template](./expressions.html#string-templates) and then it is evaluated to produce the final result. If the given template consists _only_ of a single interpolation sequence, the result of its expression is taken directly, without first converting it to a string. This allows non-string expressions to be used within the JSON syntax: ```json { "output": { "example": { "value": "${aws_instance.example}" } } } ``` The `output "example"` declared above has the object value representing the given `aws_instance` resource block as its value, rather than a string value. This special behavior does not apply if any literal or control sequences appear in the template; in these other situations, a string value is always produced. ## Nested Block Mapping When a JSON object property is named after a nested block type, the value of this property represents one or more blocks of that type. The value of the property must be either a JSON object or a JSON array. The simplest situation is representing only a single block of the given type when that type expects no labels, as with the `lifecycle` nested block used within `resource` blocks: ```json { "resource": { "aws_instance": { "example": { "lifecycle": { "create_before_destroy": true } } } } } ``` The above is equivalent to the following native syntax configuration: ```hcl resource "aws_instance" "example" { lifecycle { create_before_destroy = true } } ``` When the nested block type requires one or more labels, or when multiple blocks of the same type can be given, the mapping gets a little more complicated. For example, the `provisioner` nested block type used within `resource` blocks expects a label giving the provisioner to use, and the ordering of provisioner blocks is significant to decide the order of operations. The following native syntax example shows a `resource` block with a number of provisioners of different types: ```hcl resource "aws_instance" "example" { # (resource configuration omitted for brevity) provisioner "local-exec" { command = "echo 'Hello World' >example.txt" } provisioner "file" { source = "example.txt" destination = "/tmp/example.txt" } provisioner "remote-exec" { inline = [ "sudo install-something -f /tmp/example.txt", ] } } ``` In order to preserve the order of these blocks, you must use a JSON array as the direct value of the property representing this block type, as in this JSON equivalent of the above: ```json { "resource": { "aws_instance": { "example": { "provisioner": [ { "local-exec": { "command": "echo 'Hello World' >example.txt" } }, { "file": { "source": "example.txt", "destination": "/tmp/example.txt" } }, { "remote-exec": { "inline": ["sudo install-something -f /tmp/example.txt"] } } ] } } } } ``` Each element of the `provisioner` array is an object with a single property whose name represents the label for each `provisioner` block. For block types that expect multiple labels, this pattern of alternating array and object nesting can be used for each additional level. If a nested block type requires labels but the order does _not_ matter, you may omit the array and provide just a single object whose property names correspond to unique block labels. This is allowed as a shorthand for the above for simple cases, but the alternating array and object approach is the most general. We recommend using the most general form if systematically converting from native syntax to JSON, to ensure that the meaning of the configuration is preserved exactly. ### Comment Properties Although we do not recommend hand-editing of JSON syntax configuration files -- this format is primarily intended for programmatic generation and consumption -- a limited form of _comments_ are allowed inside JSON objects that represent block bodies using a special property name: ```json { "resource": { "aws_instance": { "example": { "//": "This instance runs the scheduled tasks for backup", "instance_type": "t2.micro", "ami": "ami-abc123" } } } } ``` In any object that represents a block body, properties named `"//"` are ignored by Terraform entirely. This exception does _not_ apply to objects that are being [interpreted as expressions](#expression-mapping), where this would be interpreted as an object type attribute named `"//"`. This special property name can also be used at the root of a JSON-based configuration file. This can be useful to note which program created the file. ```json { "//": "This file is generated by generate-outputs.py. DO NOT HAND-EDIT!", "output": { "example": { "value": "${aws_instance.example}" } } } ``` ## Block-type-specific Exceptions [inpage-block]: #block-type-specific-exceptions Certain arguments within specific block types are processed in a special way by Terraform, and so their mapping to the JSON syntax does not follow the general rules described above. The following sub-sections describe the special mapping rules that apply to each top-level block type. ### `resource` and `data` blocks Some meta-arguments for the `resource` and `data` block types take direct references to objects, or literal keywords. When represented in JSON, the reference or keyword is given as a JSON string with no additonal surrounding spaces or symbols. For example, the `provider` meta-argument takes a `.` reference to a provider configuration, which appears unquoted in the native syntax but must be presented as a string in the JSON syntax: ```json { "resource": { "aws_instance": { "example": { "provider": "aws.foo" } } } } ``` This special processing applies to the following meta-arguments: * `provider`: a single string, as shown above * `depends_on`: an array of strings containing references to named entities, like `["aws_instance.example"]`. * `ignore_changes` within the `lifecycle` block: if set to `all`, a single string `"all"` must be given. Otherwise, an array of JSON strings containing property references must be used, like `["ami"]`. Special processing also applies to the `type` argument of any `connection` blocks, whether directly inside the `resource` block or nested inside `provisioner` blocks: the given string is interpreted literally, and not parsed and evaluated as a string template. ### `variable` blocks All arguments inside `variable` blocks have non-standard mappings to JSON: * `type`: a string containing a type expression, like `"string"` or `"list(string)"`. * `default`: a literal JSON value that can be converted to the given type. Strings within this value are taken literally and _not_ interpreted as string templates. * `description`: a literal JSON string, _not_ interpreted as a template. ```json { "variable": { "example": { "type": "string", "default": "hello" } } } ``` ### `output` blocks The `description` and `sensitive` arguments are interpreted as literal JSON values. The `description` string is not interpreted as a string template. The `value` argument is [interpreted as an expression](#expression-mapping). ```json { "output": { "example": { "value": "${aws_instance.example}" } } } ``` ### `locals` blocks The value of the JSON object property representing the locals block type must be a JSON object whose property names are the local value names to declare: ```json { "locals": { "greeting": "Hello, ${var.name}" } } ``` The value of each of these nested properties is [interpreted as an expression](#expression-mapping). ### `module` blocks The `source` and `version` meta-arguments must be given as literal strings. The values are not interpreted as string templates. The `providers` meta-argument must be given as a JSON object whose properties are the compact provider addresses to expose into the child module and whose values are the provider addresses to use from the current module, both given as literal strings: ```json { "module": { "example": { "source": "hashicorp/consul/azurerm", "version": "= 1.0.0", "providers": { "aws": "aws.usw1" } } } } ``` ### `provider` blocks The `alias` and `version` meta-arguments must be given as literal strings. The values are not interpreted as string templates. ```json { "provider": { "aws": { "alias": "usw1", "region": "us-west-1" } } } ``` ### `terraform` blocks Since no settings within `terraform` blocks accept named object references or function calls, all setting values are taken literally. String values are not interpreted as string templates. Since only one `backend` block is allowed per `terraform` block, the compact block mapping can be used to represent it, with a nested object containing a single property whose name represents the backend type. ```json { "terraform": { "required_version": ">= 0.12.0", "backend": { "s3": { "region": "us-west-2", "bucket": "acme-terraform-states" } } } } ```