Type Constraints
Terraform module authors and provider developers can use detailed type constraints to validate user-provided values for their input variables and resource arguments. This requires some additional knowledge about Terraform's type system, but allows you to build a more resilient user interface for your modules and resources.
Type Keywords and Constructors
Type constraints are expressed using a mixture of type keywords and function-like constructs called type constructors.
- Type keywords are unquoted symbols that represent a static type.
- Type constructors are unquoted symbols followed by a pair of parentheses, which contain an argument that specifies more information about the type. Without its argument, a type constructor does not fully represent a type; instead, it represents a kind of similar types.
Type constraints look like other kinds of Terraform
expressions, but are a special syntax. Within the
Terraform language, they are only valid in the type
argument of an
input variable.
Primitive Types
A primitive type is a simple type that isn't made from any other types. All primitive types in Terraform are represented by a type keyword. The available primitive types are:
string
: a sequence of Unicode characters representing some text, such as"hello"
.number
: a numeric value. Thenumber
type can represent both whole numbers like15
and fractional values such as6.283185
.bool
: eithertrue
orfalse
.bool
values can be used in conditional logic.
Conversion of Primitive Types
The Terraform language will automatically convert number
and bool
values
to string
values when needed, and vice-versa as long as the string contains
a valid representation of a number or boolean value.
true
converts to"true"
, and vice-versafalse
converts to"false"
, and vice-versa15
converts to"15"
, and vice-versa
Complex Types
A complex type is a type that groups multiple values into a single value. Complex types are represented by type constructors, but several of them also have shorthand keyword versions.
There are two categories of complex types: collection types (for grouping similar values), and structural types (for grouping potentially dissimilar values).
Collection Types
A collection type allows multiple values of one other type to be grouped together as a single value. The type of value within a collection is called its element type. All collection types must have an element type, which is provided as the argument to their constructor.
For example, the type list(string)
means "list of strings", which is a
different type than list(number)
, a list of numbers. All elements of a
collection must always be of the same type.
The three kinds of collection type in the Terraform language are:
list(...)
: a sequence of values identified by consecutive whole numbers starting with zero.The keyword
list
is a shorthand forlist(any)
, which accepts any element type as long as every element is the same type. This is for compatibility with older configurations; for new code, we recommend using the full form.map(...)
: a collection of values where each is identified by a string label.The keyword
map
is a shorthand formap(any)
, which accepts any element type as long as every element is the same type. This is for compatibility with older configurations; for new code, we recommend using the full form.Maps can be made with braces ({}) and colons (:) or equals signs (=): { "foo": "bar", "bar": "baz" } OR { foo = "bar", bar = "baz" }. Quotes may be omitted on keys, unless the key starts with a number, in which case quotes are required. Commas are required between key/value pairs for single line maps. A newline between key/value pairs is sufficient in multi-line maps.
Note: Although colons are valid delimiters between keys and values,
terraform fmt
ignores them. In contrast,terraform fmt
attempts to vertically align equals signs.set(...)
: a collection of unique values that do not have any secondary identifiers or ordering.
Structural Types
A structural type allows multiple values of several distinct types to be grouped together as a single value. Structural types require a schema as an argument, to specify which types are allowed for which elements.
The two kinds of structural type in the Terraform language are:
object(...)
: a collection of named attributes that each have their own type.The schema for object types is
{ <KEY> = <TYPE>, <KEY> = <TYPE>, ... }
— a pair of curly braces containing a comma-separated series of<KEY> = <TYPE>
pairs. Values that match the object type must contain all of the specified keys, and the value for each key must match its specified type. (Values with additional keys can still match an object type, but the extra attributes are discarded during type conversion.)tuple(...)
: a sequence of elements identified by consecutive whole numbers starting with zero, where each element has its own type.The schema for tuple types is
[<TYPE>, <TYPE>, ...]
— a pair of square brackets containing a comma-separated series of types. Values that match the tuple type must have exactly the same number of elements (no more and no fewer), and the value in each position must match the specified type for that position.
For example: an object type of object({ name=string, age=number })
would match
a value like the following:
{ name = "John" age = 52}
Also, an object type of object({ id=string, cidr_block=string })
would match
the object produced by a reference to an aws_vpc
resource, like
aws_vpc.example_vpc
; although the resource has additional attributes, they
would be discarded during type conversion.
Finally, a tuple type of tuple([string, number, bool])
would match a value
like the following:
["a", 15, true]
Complex Type Literals
The Terraform language has literal expressions for creating tuple and object values, which are described in Expressions: Literal Expressions as "list/tuple" literals and "map/object" literals, respectively.
Terraform does not provide any way to directly represent lists, maps, or sets. However, due to the automatic conversion of complex types (described below), the difference between similar complex types is almost never relevant to a normal user, and most of the Terraform documentation conflates lists with tuples and maps with objects. The distinctions are only useful when restricting input values for a module or resource.
Conversion of Complex Types
Similar kinds of complex types (list/tuple/set and map/object) can usually be used interchangeably within the Terraform language, and most of Terraform's documentation glosses over the differences between the kinds of complex type. This is due to two conversion behaviors:
Whenever possible, Terraform converts values between similar kinds of complex types if the provided value is not the exact type requested. "Similar kinds" is defined as follows:
Objects and maps are similar.
A map (or a larger object) can be converted to an object if it has at least the keys required by the object schema. Any additional attributes are discarded during conversion, which means map -> object map conversions can be lossy.
Tuples and lists are similar.
- A list can only be converted to a tuple if it has exactly the required number of elements.
Sets are almost similar to both tuples and lists:
- When a list or tuple is converted to a set, duplicate values are discarded and the ordering of elements is lost.
- When a
set
is converted to a list or tuple, the elements will be in an arbitrary order. If the set's elements were strings, they will be in lexicographical order; sets of other element types do not guarantee any particular order of elements.
Whenever possible, Terraform converts element values within a complex type, either by converting complex-typed elements recursively or as described above in Conversion of Primitive Types.
For example: if a module argument requires a value of type list(string)
and a
user provides the tuple ["a", 15, true]
, Terraform will internally transform
the value to ["a", "15", "true"]
by converting the elements to the required
string
element type. Later, if the module uses those elements to set different
resource arguments that require a string, a number, and a bool (respectively),
Terraform will automatically convert the second and third strings back to the
required types at that time, since they contain valid representations of a
number and a bool.
On the other hand, automatic conversion will fail if the provided value
(including any of its element values) is incompatible with the required type. If
an argument requires a type of map(string)
and a user provides the object
{name = ["Kristy", "Claudia", "Mary Anne", "Stacey"], age = 12}
, Terraform
will raise a type mismatch error, since a tuple cannot be converted to a string.
Dynamic Types: The "any" Constraint
The keyword any
is a special construct that serves as a placeholder for a
type yet to be decided. any
is not itself a type: when interpreting a
value against a type constraint containing any
, Terraform will attempt to
find a single actual type that could replace the any
keyword to produce
a valid result.
For example, given the type constraint list(any)
, Terraform will examine
the given value and try to choose a replacement for the any
that would
make the result valid.
If the given value were ["a", "b", "c"]
-- whose physical type is
tuple([string, string, string])
, Terraform analyzes this as follows:
- Tuple types and list types are similar per the previous section, so the tuple-to-list conversion rule applies.
- All of the elements in the tuple are strings, so the type constraint
string
would be valid for all of the list elements. - Therefore in this case the
any
argument is replaced withstring
, and the final concrete value type islist(string)
.
All of the elements of a collection must have the same type, so conversion
to list(any)
requires that all of the given elements must be convertible
to a common type. This implies some other behaviors that result from the
conversion rules described in earlier sections.
- If the given value were instead
["a", 1, "b"]
then Terraform would still selectlist(string)
, because of the primitive type conversion rules, and the resulting value would be["a", "1", "b"]
due to the string conversion implied by that type constraint. - If the given value were instead
["a", [], "b"]
then the value cannot conform to the type constraint: there is no single type that both a string and an empty tuple can convert to. Terraform would reject this value, complaining that all elements must have the same type.
Although the above examples use list(any)
, a similar principle applies to
map(any)
and set(any)
.
If you wish to apply absolutely no constraint to the given value, the any
keyword can be used in isolation:
variable "no_type_constraint" { type = any}
In this case, Terraform will replace any
with the exact type of the given
value and thus perform no type conversion whatsoever.
Optional Object Type Attributes
Terraform typically returns an error when it does not receive a value for specified object attributes. When you mark an attribute as optional, Terraform instead inserts a default value for the missing attribute. This allows the receiving module to describe an appropriate fallback behavior.
To mark attributes as optional, use the optional
modifier in the object type constraint. The following example creates optional attribute b
and optional attribute with a default value c
.
variable "with_optional_attribute" { type = object({ a = string # a required attribute b = optional(string) # an optional attribute c = optional(number, 127) # an optional attribute with default value })}
The optional
modifier takes one or two arguments.
- Type: (Required) The first argument specifies the type of the attribute.
- Default: (Optional) The second argument defines the default value that Terraform should use if the attribute is not present. This must be compatible with the attribute type. If not specified, Terraform uses a
null
value of the appropriate type as the default.
An optional attribute with a non-null
default value is guaranteed to never have the value null
within the receiving module. Terraform will substitute the default value both when a caller omits the attribute altogether and when a caller explicitly sets it to null
, thereby avoiding the need for additional checks to handle a possible null value.
Terraform applies object attribute defaults top-down in nested variable types. This means that Terraform applies the default value you specify in the optional
modifier first and then later applies any nested default values to that attribute.
Example: Nested Structures with Optional Attributes and Defaults
The following example defines a variable for storage buckets that host a website. This variable type uses several optional attributes, including website
, which is itself an optional object
type that has optional attributes and defaults.
variable "buckets" { type = list(object({ name = string enabled = optional(bool, true) website = optional(object({ index_document = optional(string, "index.html") error_document = optional(string, "error.html") routing_rules = optional(string) }), {}) }))}
The following example terraform.tfvars
file specifies three bucket configurations for var.buckets
.
production
sets the routing rules to add a redirectarchived
uses default configuration, but is disableddocs
overrides the index and error documents to use text files
The production
bucket does not specify the index and error documents, and the archived
bucket omits the website configuration entirely. Terraform will use the default values specified in the bucket
type constraint.
buckets = [ { name = "production" website = { routing_rules = <<-EOT [ { "Condition" = { "KeyPrefixEquals": "img/" }, "Redirect" = { "ReplaceKeyPrefixWith": "images/" } } ] EOT } }, { name = "archived" enabled = false }, { name = "docs" website = { index_document = "index.txt" error_document = "error.txt" } },]
This configuration produces the following variable values.
- For the
production
anddocs
buckets, Terraform setsenabled
totrue
. Terraform also supplies default values forwebsite
, and then the values specified indocs
override those defaults. - For the
archived
anddocs
buckets, Terraform setsrouting_rules
to anull
value. When Terraform does not receive optional attributes and there are no specified defaults, Terraform populates those attributes with anull
value. - For the
archived
bucket, Terraform populates thewebsite
attribute with the default values specified in thebuckets
type constraint.
tolist([ { "enabled" = true "name" = "production" "website" = { "error_document" = "error.html" "index_document" = "index.html" "routing_rules" = <<-EOT [ { "Condition" = { "KeyPrefixEquals": "img/" }, "Redirect" = { "ReplaceKeyPrefixWith": "images/" } } ] EOT } }, { "enabled" = false "name" = "archived" "website" = { "error_document" = "error.html" "index_document" = "index.html" "routing_rules" = tostring(null) } }, { "enabled" = true "name" = "docs" "website" = { "error_document" = "error.txt" "index_document" = "index.txt" "routing_rules" = tostring(null) } },])
Example: Conditionally setting an optional attribute
Sometimes the decision about whether or not to set a value for an optional argument needs to be made dynamically based on some other data. In that case, the calling module
block can use a conditional expression with null
as one of its result arms to represent dynamically leaving the argument unset.
With the variable "buckets"
declaration shown in the previous section, the following example conditionally overrides the index_document
and error_document
settings in the website
object based on a new variable var.legacy_filenames
:
variable "legacy_filenames" { type = bool default = false nullable = false}module "buckets" { source = "./modules/buckets" buckets = [ { name = "maybe_legacy" website = { error_document = var.legacy_filenames ? "ERROR.HTM" : null index_document = var.legacy_filenames ? "INDEX.HTM" : null } }, ]}
When var.legacy_filenames
is set to true
, the call will override the document filenames. When it is false
, the call will leave the two filenames unspecified, thereby allowing the module to use its specified default values.