This HCL extension defines a convention for describing HCL types using function call and variable reference syntax, allowing configuration formats to include type information provided by users.
The type syntax is processed statically from a hcl.Expression, so it cannot use any of the usual language operators. This is similar to type expressions in statically-typed programming languages.
variable "example" {
type = list(string)
}
The extension is built using the hcl.ExprAsKeyword
and hcl.ExprCall
functions, and so it relies on the underlying syntax to define how "keyword"
and "call" are interpreted. The above shows how they are interpreted in
the HCL native syntax, while the following shows the same information
expressed in JSON:
{
"variable": {
"example": {
"type": "list(string)"
}
}
}
Notice that since we have additional contextual information that we intend to allow only calls and keywords the JSON syntax is able to parse the given string directly as an expression, rather than as a template as would be the case for normal expression evaluation.
For more information, see the godoc reference.
When expressed in the native syntax, the following expressions are permitted in a type expression:
string
- stringbool
- booleannumber
- numberany
-cty.DynamicPseudoType
(in functionTypeConstraint
only)list(<type_expr>)
- list of the type given as an argumentset(<type_expr>)
- set of the type given as an argumentmap(<type_expr>)
- map of the type given as an argumenttuple([<type_exprs...>])
- tuple with the element types given in the single list argumentobject({<attr_name>=<type_expr>, ...}
- object with the attributes and corresponding types given in the single map argument
For example:
list(string)
object({name=string,age=number})
map(object({name=string,age=number}))
Note that the object constructor syntax is not fully-general for all possible object types because it requires the attribute names to be valid identifiers. In practice it is expected that any time an object type is being fixed for type checking it will be one that has identifiers as its attributes; object types with weird attributes generally show up only from arbitrary object constructors in configuration files, which are usually treated either as maps or as the dynamic pseudo-type.
As part of object expressions attributes can be marked as optional. Missing
object attributes would typically result in an error when type constraints are
validated or used. Optional missing attributes, however, would not result in an
error. The cty
"convert" function will populate
missing optional attributes with null values.
For example:
object({name=string,age=optional(number)})
Optional attributes can also be specified with default values. The
TypeConstraintWithDefaults
function will return a Defaults
object that can
be used to populate missing optional attributes with defaults in a given
cty.Value
.
For example:
object({name=string,age=optional(number, 0)})
Along with defining a convention for writing down types using HCL expression constructs, this package also includes a mechanism for representing types as values that can be used as data within an HCL-based language.
typeexpr.TypeConstraintType
is a
cty
capsule type
that encapsulates cty.Type
values. You can construct such a value directly
using the TypeConstraintVal
function:
tyVal := typeexpr.TypeConstraintVal(cty.String)
// We can unpack the type from a value using TypeConstraintFromVal
ty := typeExpr.TypeConstraintFromVal(tyVal)
However, the primary purpose of typeexpr.TypeConstraintType
is to be
specified as the type constraint for an argument, in which case it serves
as a signal for HCL to treat the argument expression as a type constraint
expression as defined above, rather than as a normal value expression.
"An argument" in the above in practice means the following two locations:
-
As the type constraint for a parameter of a cty function that will be used in an
hcl.EvalContext
. In that case, function calls in the HCL native expression syntax will require the argument to be valid type constraint expression syntax and the function implementation will receive aTypeConstraintType
value as the argument value for that parameter. -
As the type constraint for a
hcldec.AttrSpec
orhcldec.BlockAttrsSpec
when decoding an HCL body usinghcldec
. In that case, the attributes with that type constraint will be required to be valid type constraint expression syntax and the result will be aTypeConstraintType
value.
Note that the special handling of these arguments means that an argument
marked in this way must use the type constraint syntax directly. It is not
valid to pass in a value of TypeConstraintType
that has been obtained
dynamically via some other expression result.
TypeConstraintType
is provided with the intent of using it internally within
application code when incorporating type constraint expression syntax into
an HCL-based language, not to be used for dynamic "programming with types". A
calling application could support programming with types by defining its own
capsule type, but that is not the purpose of TypeConstraintType
.
Building on the TypeConstraintType
described in the previous section, this
package also provides typeexpr.ConvertFunc
which is a cty function that
can be placed into a cty.EvalContext
(conventionally named "convert") in
order to provide a general type conversion function in an HCL-based language:
foo = convert("true", bool)
The second parameter uses the mechanism described in the previous section to
require its argument to be a type constraint expression rather than a value
expression. In doing so, it allows converting with any type constraint that
can be expressed in this package's type constraint syntax. In the above example,
the foo
argument would receive a boolean true, or cty.True
in cty
terms.
The target type constraint must always be provided statically using inline type constraint syntax. There is no way to dynamically select a type constraint using this function.