terraform/website/docs/configuration-0-11/interpolation.html.md

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---
layout: "language"
page_title: "Interpolation Syntax - 0.11 Configuration Language"
sidebar_current: "docs-conf-old-interpolation"
description: |-
Embedded within strings in Terraform, whether you're using the Terraform syntax or JSON syntax, you can interpolate other values into strings. These interpolations are wrapped in `${}`, such as `${var.foo}`.
---
# Interpolation Syntax
-> **Note:** This page is about Terraform 0.11 and earlier. For Terraform 0.12
and later, see
[Configuration Language: Expressions](/docs/configuration/expressions/index.html) and
[Configuration Language: Functions](../configuration/functions.html).
Embedded within strings in Terraform, whether you're using the
Terraform syntax or JSON syntax, you can interpolate other values. These
interpolations are wrapped in `${}`, such as `${var.foo}`.
The interpolation syntax is powerful and allows you to reference
variables, attributes of resources, call functions, etc.
You can perform [simple math](#math) in interpolations, allowing
you to write expressions such as `${count.index + 1}`. And you can
also use [conditionals](#conditionals) to determine a value based
on some logic.
You can escape interpolation with double dollar signs: `$${foo}`
will be rendered as a literal `${foo}`.
## Available Variables
There are a variety of available variable references you can use.
#### User string variables
Use the `var.` prefix followed by the variable name. For example,
`${var.foo}` will interpolate the `foo` variable value.
#### User map variables
The syntax is `var.<MAP>["<KEY>"]`. For example, `${var.amis["us-east-1"]}`
would get the value of the `us-east-1` key within the `amis` map
variable.
#### User list variables
The syntax is `"${var.<LIST>}"`. For example, `"${var.subnets}"`
would get the value of the `subnets` list, as a list. You can also
return list elements by index: `${var.subnets[idx]}`.
#### Attributes of your own resource
The syntax is `self.<ATTRIBUTE>`. For example `${self.private_ip}`
will interpolate that resource's private IP address.
-> **Note**: The `self.<ATTRIBUTE>` syntax is only allowed and valid within
provisioners.
#### Attributes of other resources
The syntax is `<TYPE>.<NAME>.<ATTRIBUTE>`. For example,
`${aws_instance.web.id}` will interpolate the ID attribute from the
`aws_instance` resource named `web`. If the resource has a `count`
attribute set, you can access individual attributes with a zero-based
index, such as `${aws_instance.web.0.id}`. You can also use the splat
syntax to get a list of all the attributes: `${aws_instance.web.*.id}`.
#### Attributes of a data source
The syntax is `data.<TYPE>.<NAME>.<ATTRIBUTE>`. For example. `${data.aws_ami.ubuntu.id}` will interpolate the `id` attribute from the `aws_ami` [data source](./data-sources.html) named `ubuntu`. If the data source has a `count`
attribute set, you can access individual attributes with a zero-based
index, such as `${data.aws_subnet.example.0.cidr_block}`. You can also use the splat
syntax to get a list of all the attributes: `${data.aws_subnet.example.*.cidr_block}`.
#### Outputs from a module
The syntax is `module.<NAME>.<OUTPUT>`. For example `${module.foo.bar}` will
interpolate the `bar` output from the `foo`
[module](/docs/modules/index.html).
#### Count information
The syntax is `count.index`. For example, `${count.index}` will
interpolate the current index in a multi-count resource. For more
information on `count`, see the [resource configuration
page](./resources.html).
#### Path information
The syntax is `path.<TYPE>`. TYPE can be `cwd`, `module`, or `root`.
`cwd` will interpolate the current working directory. `module` will
interpolate the path to the current module. `root` will interpolate the
path of the root module. In general, you probably want the
`path.module` variable.
#### Terraform meta information
The syntax is `terraform.<FIELD>`. This variable type contains metadata about
the currently executing Terraform run. FIELD can currently only be `env` to
reference the currently active [state environment](/docs/state/environments.html).
## Conditionals
Interpolations may contain conditionals to branch on the final value.
```hcl
resource "aws_instance" "web" {
subnet = "${var.env == "production" ? var.prod_subnet : var.dev_subnet}"
}
```
The conditional syntax is the well-known ternary operation:
```text
CONDITION ? TRUEVAL : FALSEVAL
```
The condition can be any valid interpolation syntax, such as variable
access, a function call, or even another conditional. The true and false
value can also be any valid interpolation syntax. The returned types by
the true and false side must be the same.
The supported operators are:
* Equality: `==` and `!=`
* Numerical comparison: `>`, `<`, `>=`, `<=`
* Boolean logic: `&&`, `||`, unary `!`
A common use case for conditionals is to enable/disable a resource by
conditionally setting the count:
```hcl
resource "aws_instance" "vpn" {
count = "${var.something ? 1 : 0}"
}
```
In the example above, the "vpn" resource will only be included if
"var.something" evaluates to true. Otherwise, the VPN resource will
not be created at all.
## Built-in Functions
Terraform ships with built-in functions. Functions are called with the
syntax `name(arg, arg2, ...)`. For example, to read a file:
`${file("path.txt")}`.
~> **Note**: Proper escaping is required for JSON field values containing quotes
(`"`) such as `environment` values. If directly setting the JSON, they should be
escaped as `\"` in the JSON, e.g. `"value": "I \"love\" escaped quotes"`. If
using a Terraform variable value, they should be escaped as `\\\"` in the
variable, e.g. `value = "I \\\"love\\\" escaped quotes"` in the variable and
`"value": "${var.myvariable}"` in the JSON.
### Supported built-in functions
The supported built-in functions are:
* `abs(float)` - Returns the absolute value of a given float.
Example: `abs(1)` returns `1`, and `abs(-1)` would also return `1`,
whereas `abs(-3.14)` would return `3.14`. See also the `signum` function.
* `basename(path)` - Returns the last element of a path.
* `base64decode(string)` - Given a base64-encoded string, decodes it and
returns the original string.
* `base64encode(string)` - Returns a base64-encoded representation of the
given string.
* `base64gzip(string)` - Compresses the given string with gzip and then
encodes the result to base64. This can be used with certain resource
arguments that allow binary data to be passed with base64 encoding, since
Terraform strings are required to be valid UTF-8.
* `base64sha256(string)` - Returns a base64-encoded representation of raw
SHA-256 sum of the given string.
**This is not equivalent** of `base64encode(sha256(string))`
since `sha256()` returns hexadecimal representation.
* `base64sha512(string)` - Returns a base64-encoded representation of raw
SHA-512 sum of the given string.
**This is not equivalent** of `base64encode(sha512(string))`
since `sha512()` returns hexadecimal representation.
* `bcrypt(password, cost)` - Returns the Blowfish encrypted hash of the string
at the given cost. A default `cost` of 10 will be used if not provided.
* `ceil(float)` - Returns the least integer value greater than or equal
to the argument.
* `chomp(string)` - Removes trailing newlines from the given string.
* `chunklist(list, size)` - Returns the `list` items chunked by `size`.
Examples:
* `chunklist(aws_subnet.foo.*.id, 1)`: will outputs `[["id1"], ["id2"], ["id3"]]`
* `chunklist(var.list_of_strings, 2)`: will outputs `[["id1", "id2"], ["id3", "id4"], ["id5"]]`
* `cidrhost(iprange, hostnum)` - Takes an IP address range in CIDR notation
and creates an IP address with the given host number. If given host
number is negative, the count starts from the end of the range.
For example, `cidrhost("10.0.0.0/8", 2)` returns `10.0.0.2` and
`cidrhost("10.0.0.0/8", -2)` returns `10.255.255.254`.
* `cidrnetmask(iprange)` - Takes an IP address range in CIDR notation
and returns the address-formatted subnet mask format that some
systems expect for IPv4 interfaces. For example,
`cidrnetmask("10.0.0.0/8")` returns `255.0.0.0`. Not applicable
to IPv6 networks since CIDR notation is the only valid notation for
IPv6.
* `cidrsubnet(iprange, newbits, netnum)` - Takes an IP address range in
CIDR notation (like `10.0.0.0/8`) and extends its prefix to include an
additional subnet number. For example,
`cidrsubnet("10.0.0.0/8", 8, 2)` returns `10.2.0.0/16`;
`cidrsubnet("2607:f298:6051:516c::/64", 8, 2)` returns
`2607:f298:6051:516c:200::/72`.
* `coalesce(string1, string2, ...)` - Returns the first non-empty value from
the given arguments. At least two arguments must be provided.
* `coalescelist(list1, list2, ...)` - Returns the first non-empty list from
the given arguments. At least two arguments must be provided.
* `compact(list)` - Removes empty string elements from a list. This can be
useful in some cases, for example when passing joined lists as module
variables or when parsing module outputs.
Example: `compact(module.my_asg.load_balancer_names)`
* `concat(list1, list2, ...)` - Combines two or more lists into a single list.
Example: `concat(aws_instance.db.*.tags.Name, aws_instance.web.*.tags.Name)`
* `contains(list, element)` - Returns *true* if a list contains the given element
and returns *false* otherwise. Examples: `contains(var.list_of_strings, "an_element")`
* `dirname(path)` - Returns all but the last element of path, typically the path's directory.
* `distinct(list)` - Removes duplicate items from a list. Keeps the first
occurrence of each element, and removes subsequent occurrences. This
function is only valid for flat lists. Example: `distinct(var.usernames)`
* `element(list, index)` - Returns a single element from a list
at the given index. If the index is greater than the number of
elements, this function will wrap using a standard mod algorithm.
This function only works on flat lists. Examples:
* `element(aws_subnet.foo.*.id, count.index)`
* `element(var.list_of_strings, 2)`
* `file(path)` - Reads the contents of a file into the string. Variables
in this file are _not_ interpolated. The contents of the file are
read as-is. The `path` is interpreted relative to the working directory.
[Path variables](#path-information) can be used to reference paths relative
to other base locations. For example, when using `file()` from inside a
module, you generally want to make the path relative to the module base,
like this: `file("${path.module}/file")`.
* `floor(float)` - Returns the greatest integer value less than or equal to
the argument.
* `flatten(list of lists)` - Flattens lists of lists down to a flat list of
primitive values, eliminating any nested lists recursively. Examples:
* `flatten(data.github_user.user.*.gpg_keys)`
* `format(format, args, ...)` - Formats a string according to the given
format. The syntax for the format is standard `sprintf` syntax.
Good documentation for the syntax can be [found here](https://golang.org/pkg/fmt/).
Example to zero-prefix a count, used commonly for naming servers:
`format("web-%03d", count.index + 1)`.
* `formatlist(format, args, ...)` - Formats each element of a list
according to the given format, similarly to `format`, and returns a list.
Non-list arguments are repeated for each list element.
For example, to convert a list of DNS addresses to a list of URLs, you might use:
`formatlist("https://%s:%s/", aws_instance.foo.*.public_dns, var.port)`.
If multiple args are lists, and they have the same number of elements, then the formatting is applied to the elements of the lists in parallel.
Example:
`formatlist("instance %v has private ip %v", aws_instance.foo.*.id, aws_instance.foo.*.private_ip)`.
Passing lists with different lengths to formatlist results in an error.
* `indent(numspaces, string)` - Prepends the specified number of spaces to all but the first
line of the given multi-line string. May be useful when inserting a multi-line string
into an already-indented context. The first line is not indented, to allow for the
indented string to be placed after some sort of already-indented preamble.
Example: `" \"items\": ${ indent(4, "[\n \"item1\"\n]") },"`
* `index(list, elem)` - Finds the index of a given element in a list.
This function only works on flat lists.
Example: `index(aws_instance.foo.*.tags.Name, "foo-test")`
* `join(delim, list)` - Joins the list with the delimiter for a resultant string.
This function works only on flat lists.
Examples:
* `join(",", aws_instance.foo.*.id)`
* `join(",", var.ami_list)`
* `jsonencode(value)` - Returns a JSON-encoded representation of the given
value, which can contain arbitrarily-nested lists and maps. Note that if
the value is a string then its value will be placed in quotes.
* `keys(map)` - Returns a lexically sorted list of the map keys.
* `length(list)` - Returns the number of members in a given list or map, or the number of characters in a given string.
* `${length(split(",", "a,b,c"))}` = 3
* `${length("a,b,c")}` = 5
* `${length(map("key", "val"))}` = 1
* `list(items, ...)` - Returns a list consisting of the arguments to the function.
This function provides a way of representing list literals in interpolation.
* `${list("a", "b", "c")}` returns a list of `"a", "b", "c"`.
* `${list()}` returns an empty list.
* `log(x, base)` - Returns the logarithm of `x`.
* `lookup(map, key, [default])` - Performs a dynamic lookup into a map
variable. The `map` parameter should be another variable, such
as `var.amis`. If `key` does not exist in `map`, the interpolation will
fail unless you specify a third argument, `default`, which should be a
string value to return if no `key` is found in `map`. This function
only works on flat maps and will return an error for maps that
include nested lists or maps.
* `lower(string)` - Returns a copy of the string with all Unicode letters mapped to their lower case.
* `map(key, value, ...)` - Returns a map consisting of the key/value pairs
specified as arguments. Every odd argument must be a string key, and every
even argument must have the same type as the other values specified.
Duplicate keys are not allowed. Examples:
* `map("hello", "world")`
* `map("us-east", list("a", "b", "c"), "us-west", list("b", "c", "d"))`
* `matchkeys(values, keys, searchset)` - For two lists `values` and `keys` of
equal length, returns all elements from `values` where the corresponding
element from `keys` exists in the `searchset` list. E.g.
`matchkeys(aws_instance.example.*.id,
aws_instance.example.*.availability_zone, list("us-west-2a"))` will return a
list of the instance IDs of the `aws_instance.example` instances in
`"us-west-2a"`. No match will result in empty list. Items of `keys` are
processed sequentially, so the order of returned `values` is preserved.
* `max(float1, float2, ...)` - Returns the largest of the floats.
* `merge(map1, map2, ...)` - Returns the union of 2 or more maps. The maps
are consumed in the order provided, and duplicate keys overwrite previous
entries.
* `${merge(map("a", "b"), map("c", "d"))}` returns `{"a": "b", "c": "d"}`
* `min(float1, float2, ...)` - Returns the smallest of the floats.
* `md5(string)` - Returns a (conventional) hexadecimal representation of the
MD5 hash of the given string.
* `pathexpand(string)` - Returns a filepath string with `~` expanded to the home directory. Note:
This will create a plan diff between two different hosts, unless the filepaths are the same.
* `pow(x, y)` - Returns the base `x` of exponential `y` as a float.
Example:
* `${pow(3,2)}` = 9
* `${pow(4,0)}` = 1
* `replace(string, search, replace)` - Does a search and replace on the
given string. All instances of `search` are replaced with the value
of `replace`. If `search` is wrapped in forward slashes, it is treated
as a regular expression. If using a regular expression, `replace`
can reference subcaptures in the regular expression by using `$n` where
`n` is the index or name of the subcapture. If using a regular expression,
the syntax conforms to the [re2 regular expression syntax](https://github.com/google/re2/wiki/Syntax).
* `rsadecrypt(string, key)` - Decrypts `string` using RSA. The padding scheme
PKCS #1 v1.5 is used. The `string` must be base64-encoded. `key` must be an
RSA private key in PEM format. You may use `file()` to load it from a file.
* `sha1(string)` - Returns a (conventional) hexadecimal representation of the
SHA-1 hash of the given string.
Example: `"${sha1("${aws_vpc.default.tags.customer}-s3-bucket")}"`
* `sha256(string)` - Returns a (conventional) hexadecimal representation of the
SHA-256 hash of the given string.
Example: `"${sha256("${aws_vpc.default.tags.customer}-s3-bucket")}"`
* `sha512(string)` - Returns a (conventional) hexadecimal representation of the
SHA-512 hash of the given string.
Example: `"${sha512("${aws_vpc.default.tags.customer}-s3-bucket")}"`
* `signum(integer)` - Returns `-1` for negative numbers, `0` for `0` and `1` for positive numbers.
This function is useful when you need to set a value for the first resource and
a different value for the rest of the resources.
Example: `element(split(",", var.r53_failover_policy), signum(count.index))`
where the 0th index points to `PRIMARY` and 1st to `FAILOVER`
* `slice(list, from, to)` - Returns the portion of `list` between `from` (inclusive) and `to` (exclusive).
Example: `slice(var.list_of_strings, 0, length(var.list_of_strings) - 1)`
2019-03-21 20:20:29 +01:00
* `sort(list)` - Returns a lexicographically sorted list of the strings contained in
the list passed as an argument. Sort may only be used with lists which contain only
strings.
Examples: `sort(aws_instance.foo.*.id)`, `sort(var.list_of_strings)`
* `split(delim, string)` - Returns a list by splitting the string based on
the delimiter. This is useful for pushing lists through module
outputs since they currently only support string values. Depending on the
use, the string this is being performed within may need to be wrapped
in brackets to indicate that the output is actually a list, e.g.
`a_resource_param = ["${split(",", var.CSV_STRING)}"]`.
Example: `split(",", module.amod.server_ids)`
* `substr(string, offset, length)` - Extracts a substring from the input string. A negative offset is interpreted as being equivalent to a positive offset measured backwards from the end of the string. A length of `-1` is interpreted as meaning "until the end of the string".
* `timestamp()` - Returns a UTC timestamp string in RFC 3339 format. This string will change with every
invocation of the function, so in order to prevent diffs on every plan & apply, it must be used with the
[`ignore_changes`](./resources.html#ignore_changes) lifecycle attribute.
* `timeadd(time, duration)` - Returns a UTC timestamp string corresponding to adding a given `duration` to `time` in RFC 3339 format.
For example, `timeadd("2017-11-22T00:00:00Z", "10m")` produces a value `"2017-11-22T00:10:00Z"`.
* `title(string)` - Returns a copy of the string with the first characters of all the words capitalized.
* `transpose(map)` - Swaps the keys and list values in a map of lists of strings. For example, transpose(map("a", list("1", "2"), "b", list("2", "3")) produces a value equivalent to map("1", list("a"), "2", list("a", "b"), "3", list("b")).
* `trimspace(string)` - Returns a copy of the string with all leading and trailing white spaces removed.
* `upper(string)` - Returns a copy of the string with all Unicode letters mapped to their upper case.
* `urlencode(string)` - Returns an URL-safe copy of the string.
* `uuid()` - Returns a random UUID string. This string will change with every invocation of the function, so in order to prevent diffs on every plan & apply, it must be used with the [`ignore_changes`](./resources.html#ignore_changes) lifecycle attribute.
* `values(map)` - Returns a list of the map values, in the order of the keys
returned by the `keys` function. This function only works on flat maps and
will return an error for maps that include nested lists or maps.
* `zipmap(list, list)` - Creates a map from a list of keys and a list of
values. The keys must all be of type string, and the length of the lists
must be the same.
For example, to output a mapping of AWS IAM user names to the fingerprint
of the key used to encrypt their initial password, you might use:
`zipmap(aws_iam_user.users.*.name, aws_iam_user_login_profile.users.*.key_fingerprint)`.
The hashing functions `base64sha256`, `base64sha512`, `md5`, `sha1`, `sha256`,
and `sha512` all have variants with a `file` prefix, like `filesha1`, which
interpret their first argument as a path to a file on disk rather than as a
literal string. This allows safely creating hashes of binary files that might
otherwise be corrupted in memory if loaded into Terraform strings (which are
assumed to be UTF-8). `filesha1(filename)` is equivalent to `sha1(file(filename))`
in Terraform 0.11 and earlier, but the latter will fail for binary files in
Terraform 0.12 and later.
## Templates
Long strings can be managed using templates.
[Templates](https://registry.terraform.io/providers/hashicorp/template/latest/docs) are
[data-sources](./data-sources.html) defined by a
string with interpolation tokens (usually loaded from a file) and some variables
to use during interpolation. They have a computed `rendered` attribute
containing the result.
A template data source looks like:
```hcl
# templates/greeting.tpl
${hello} ${world}!
```
```hcl
data "template_file" "example" {
template = "${file("templates/greeting.tpl")}"
vars {
hello = "goodnight"
world = "moon"
}
}
output "rendered" {
value = "${data.template_file.example.rendered}"
}
```
Then the rendered value would be `goodnight moon!`.
-> **Note:** If you specify the template as a literal string instead of loading
a file, the inline template must use double dollar signs (like `$${hello}`) to
prevent Terraform from interpolating values from the configuration into the
string. This is because `template_file` creates its own instance of the
interpolation system, with values provided by its nested `vars` block instead of
by the surrounding scope of the configuration.
You may use any of the built-in functions in your template. For more
details on template usage, please see the
[template_file documentation](https://registry.terraform.io/providers/hashicorp/template/latest/docs/data-sources/file).
### Using Templates with Count
Here is an example that combines the capabilities of templates with the interpolation
from `count` to give us a parameterized template, unique to each resource instance:
```hcl
variable "hostnames" {
default = {
"0" = "example1.org"
"1" = "example2.net"
}
}
data "template_file" "web_init" {
# Render the template once for each instance
count = "${length(var.hostnames)}"
template = "${file("templates/web_init.tpl")}"
vars {
# count.index tells us the index of the instance we are rendering
hostname = "${var.hostnames[count.index]}"
}
}
resource "aws_instance" "web" {
# Create one instance for each hostname
count = "${length(var.hostnames)}"
# Pass each instance its corresponding template_file
user_data = "${data.template_file.web_init.*.rendered[count.index]}"
}
```
With this, we will build a list of `template_file.web_init` data resources
which we can use in combination with our list of `aws_instance.web` resources.
## Math
Simple math can be performed in interpolations:
```hcl
variable "count" {
default = 2
}
resource "aws_instance" "web" {
# ...
count = "${var.count}"
# Tag the instance with a counter starting at 1, ie. web-001
tags {
Name = "${format("web-%03d", count.index + 1)}"
}
}
```
The supported operations are:
- *Add* (`+`), *Subtract* (`-`), *Multiply* (`*`), and *Divide* (`/`) for **float** types
- *Add* (`+`), *Subtract* (`-`), *Multiply* (`*`), *Divide* (`/`), and *Modulo* (`%`) for **integer** types
Operator precedences is the standard mathematical order of operations:
*Multiply* (`*`), *Divide* (`/`), and *Modulo* (`%`) have precedence over
*Add* (`+`) and *Subtract* (`-`). Parenthesis can be used to force ordering.
```text
"${2 * 4 + 3 * 3}" # computes to 17
"${3 * 3 + 2 * 4}" # computes to 17
"${2 * (4 + 3) * 3}" # computes to 42
```
You can use the [terraform console](/docs/commands/console.html) command to
try the math operations.
-> **Note:** Since Terraform allows hyphens in resource and variable names,
it's best to use spaces between math operators to prevent confusion or unexpected
behavior. For example, `${var.instance-count - 1}` will subtract **1** from the
`instance-count` variable value, while `${var.instance-count-1}` will interpolate
the `instance-count-1` variable value.