In TypeScript, type aliases serve three purposes:
- Aliasing other types so that we can refer to them using a simpler name.
// this...
type Person = {
firstName: string,
lastName: string,
age: number
};
function addPerson(person : Person) { ... }
// is easier to read than this...
function addPerson(person : { firstName: string, lastName: string, age: number}) { ... }
- Act sort of like an interface, providing a set of methods and properties that must exist in the objects implementing the type.
type Person = {
firstName: string,
lastName: string,
age: number,
walk: () => void,
talk: () => void
};
// you know person will have 3 properties and 2 methods,
// because the structure has already been defined.
var person : Person = { ... }
// so we can be sure that this will work
person.walk();
- Act like mapping tools between types to allow quick modifications.
type Immutable<T> = { readonly [P in keyof T]: T[P] };
type Person = {
name: string;
age: number;
};
type ImmutablePerson = Immutable<Person>;
var person: ImmutablePerson = { name: "John", age: 30 };
person.name = "Brad"; // error, readonly property
When aliasing, the type alias does not create a new type, it just creates a new name to refer to the original type. So aliasing primitives and other simple types, tuples, unions or intersections can some times be redundant.
// this doesn't make much sense
type myString = string;
On the other hand, using a type alias as an interface can limit your ability to:
- Reuse your code: interfaces can be extended or implemented by other types. Type aliases cannot.
- Debug your code: interfaces create a new name, so is easy to identify the base type of an object while debugging the application.
Finally, mapping types is an advance technique, leaving it open can quickly become a pain point in your application.
This rule disallows the use of type aliases in favor of interfaces and simplified types (primitives, tuples, unions, intersections, etc).
This rule, in its default state, does not require any argument. If you would like to enable one or more of the following you may pass an object with the options set as follows:
allowAliases
set to"always"
will allow you to do aliasing (Defaults to"never"
).allowCallbacks
set to"always"
will allow you to use type aliases with callbacks (Defaults to"never"
)allowLiterals
set to"always"
will allow you to use type aliases with literal objects (Defaults to"never"
)allowMappedTypes
set to"always"
will allow you to use type aliases as mapping tools (Defaults to"never"
)
This applies to primitive types and reference types.
The setting accepts the following values:
"always"
or"never"
to active or deactivate the feature."in-unions"
, allows aliasing in union statements, e.g.type Foo = string | string[];
"in-intersections"
, allows aliasing in intersection statements, e.g.type Foo = string & string[];
"in-unions-and-intersections"
, allows aliasing in union and/or intersection statements.
Examples of correct code for the { "allowAliases": "always" }
options:
// primitives
type Foo = "a";
type Foo = "a" | "b";
type Foo = string;
type Foo = string | string[];
type Foo = string & string[];
// reference types
interface Bar {}
class Baz implements Bar {}
type Foo = Bar;
type Foo = Bar | Baz;
type Foo = Bar & Baz;
Examples of incorrect code for the { "allowAliases": "in-unions" }
option:
// primitives
type Foo = "a";
type Foo = string;
type Foo = string & string[];
// reference types
interface Bar {}
class Baz implements Bar {}
type Foo = Bar;
type Foo = Bar & Baz;
Examples of correct code for the { "allowAliases": "in-unions" }
option:
// primitives
type Foo = "a" | "b";
type Foo = string | string[];
// reference types
interface Bar {}
class Baz implements Bar {}
type Foo = Bar | Baz;
Examples of incorrect code for the { "allowAliases": "in-intersections" }
option:
// primitives
type Foo = "a";
type Foo = "a" | "b";
type Foo = string;
type Foo = string | string[];
// reference types
interface Bar {}
class Baz implements Bar {}
type Foo = Bar;
type Foo = Bar | Baz;
Examples of correct code for the { "allowAliases": "in-intersections" }
option:
// primitives
type Foo = string & string[];
// reference types
interface Bar {}
class Baz implements Bar {}
type Foo = Bar & Baz;
Examples of incorrect code for the { "allowAliases": "in-unions-and-intersections" }
option:
// primitives
type Foo = "a";
type Foo = string;
// reference types
interface Bar {}
class Baz implements Bar {}
type Foo = Bar;
Examples of correct code for the { "allowAliases": "in-unions-and-intersections" }
option:
// primitives
type Foo = "a" | "b";
type Foo = string | string[];
type Foo = string & string[];
// reference types
interface Bar {}
class Baz implements Bar {}
type Foo = Bar | Baz;
type Foo = Bar & Baz;
This applies to function types.
The setting accepts the following values:
"always"
or"never"
to active or deactivate the feature.
Examples of correct code for the { "allowCallbacks": "always" }
option:
type Foo = () => void;
type Foo = (name: string) => string;
class Person {}
type Foo = (name: string, age: number) => string | Person;
type Foo = (name: string, age: number) => string & Person;
This applies to literal types (type Foo = { ... }
).
The setting accepts the following options:
"always"
or"never"
to active or deactivate the feature."in-unions"
, allows literals in union statements, e.g.type Foo = string | string[];
"in-intersections"
, allows literals in intersection statements, e.g.type Foo = string & string[];
"in-unions-and-intersections"
, allows literals in union and/or intersection statements.
Examples of correct code for the { "allowLiterals": "always" }
options:
type Foo = {};
type Foo = {
name: string;
age: number;
};
type Foo = {
name: string;
age: number;
walk: (miles: number) => void;
};
type Foo = { name: string } | { age: number };
type Foo = { name: string } & { age: number };
Examples of incorrect code for the { "allowLiterals": "in-unions" }
option:
type Foo = {};
type Foo = {
name: string;
age: number;
};
type Foo = {
name: string;
age: number;
walk: (miles: number) => void;
};
type Foo = { name: string } & { age: number };
Examples of correct code for the { "allowLiterals": "in-unions" }
option:
type Foo = { name: string } | { age: number };
Examples of incorrect code for the { "allowLiterals": "in-intersections" }
option:
type Foo = {};
type Foo = {
name: string;
age: number;
};
type Foo = {
name: string;
age: number;
walk: (miles: number) => void;
};
type Foo = { name: string } | { age: number };
Examples of correct code for the { "allowLiterals": "in-intersections" }
option:
type Foo = { name: string } & { age: number };
Examples of incorrect code for the { "allowLiterals": "in-unions-and-intersections" }
option:
type Foo = {};
type Foo = {
name: string;
age: number;
};
type Foo = {
name: string;
age: number;
walk: (miles: number) => void;
};
Examples of correct code for the { "allowLiterals": "in-unions-and-intersections" }
option:
type Foo = { name: string } | { age: number };
type Foo = { name: string } & { age: number };
This applies to literal types.
The setting accepts the following values:
"always"
or"never"
to active or deactivate the feature."in-unions"
, allows aliasing in union statements, e.g.type Foo = string | string[];
"in-intersections"
, allows aliasing in intersection statements, e.g.type Foo = string & string[];
"in-unions-and-intersections"
, allows aliasing in union and/or intersection statements.
Examples of correct code for the { "allowMappedTypes": "always" }
options:
type Foo<T> = { readonly [P in keyof T]: T[P] };
type Foo<T> = { [P in keyof T]?: T[P] };
type Foo<T, U> =
| { readonly [P in keyof T]: T[P] }
| { readonly [P in keyof U]: U[P] };
type Foo<T, U> = { [P in keyof T]?: T[P] } | { [P in keyof U]?: U[P] };
type Foo<T, U> = { readonly [P in keyof T]: T[P] } &
{ readonly [P in keyof U]: U[P] };
type Foo<T, U> = { [P in keyof T]?: T[P] } & { [P in keyof U]?: U[P] };
Examples of incorrect code for the { "allowMappedTypes": "in-unions" }
option:
type Foo<T> = { readonly [P in keyof T]: T[P] };
type Foo<T> = { [P in keyof T]?: T[P] };
type Foo<T, U> = { readonly [P in keyof T]: T[P] } &
{ readonly [P in keyof U]: U[P] };
type Foo<T, U> = { [P in keyof T]?: T[P] } & { [P in keyof U]?: U[P] };
Examples of correct code for the { "allowMappedTypes": "in-unions" }
option:
type Foo<T, U> =
| { readonly [P in keyof T]: T[P] }
| { readonly [P in keyof U]: U[P] };
type Foo<T, U> = { [P in keyof T]?: T[P] } | { [P in keyof U]?: U[P] };
Examples of incorrect code for the { "allowMappedTypes": "in-intersections" }
option:
type Foo<T> = { readonly [P in keyof T]: T[P] };
type Foo<T> = { [P in keyof T]?: T[P] };
type Foo<T, U> =
| { readonly [P in keyof T]: T[P] }
| { readonly [P in keyof U]: U[P] };
type Foo<T, U> = { [P in keyof T]?: T[P] } | { [P in keyof U]?: U[P] };
Examples of correct code for the { "allowMappedTypes": "in-intersections" }
option:
type Foo<T, U> = { readonly [P in keyof T]: T[P] } &
{ readonly [P in keyof U]: U[P] };
type Foo<T, U> = { [P in keyof T]?: T[P] } & { [P in keyof U]?: U[P] };
Examples of incorrect code for the { "allowMappedTypes": "in-unions-and-intersections" }
option:
type Foo<T> = { readonly [P in keyof T]: T[P] };
type Foo<T> = { [P in keyof T]?: T[P] };
Examples of correct code for the { "allowMappedTypes": "in-unions-and-intersections" }
option:
type Foo<T, U> =
| { readonly [P in keyof T]: T[P] }
| { readonly [P in keyof U]: U[P] };
type Foo<T, U> = { [P in keyof T]?: T[P] } | { [P in keyof U]?: U[P] };
type Foo<T, U> = { readonly [P in keyof T]: T[P] } &
{ readonly [P in keyof U]: U[P] };
type Foo<T, U> = { [P in keyof T]?: T[P] } & { [P in keyof U]?: U[P] };
When you can't express some shape with an interface or you need to use a union, tuple type, callback, etc. that would cause the code to be unreadable or impractical.
- TSLint: interface-over-type-literal