Along with traditional OO hierarchies, another popular way of building up classes from reusable components is to build them by combining simpler partial classes. You may be familiar with the idea of mixins or traits for languages like Scala, and the pattern has also reached some popularity in the JavaScript community.
How Does A Mixin Work?
The pattern relies on using Generics with class inheritance to extend a base class. TypeScript’s best mixin support is done via the class expression pattern. You can read more about how this pattern works in JavaScript here.
To get started, we’ll need a class which will have the mixin’s applied on top of:
tsclass
TrySprite {name = "";x = 0;y = 0; constructor(name : string) { this.name =name ; } }
Then you need a type and a class which
ts// To get started, we need a type which we'll use to extend // other classes from. The main responsibility is to declare // that the type being passed in is a class. type
TryConstructor = new (...args : any[]) => {}; // This mixin adds a scale property, with getters and setters // for changing it with an encapsulated private property: functionScale <TBase extendsConstructor >(Base :TBase ) { return classScaling extendsBase { // Mixins may not declare private/protected properties // however, you can use ES2020 private fields_scale = 1;setScale (scale : number) { this._scale =scale ; } getscale (): number { return this._scale ; } }; }
With these all set up, then you can create a class which represents the base class with mixins applied:
ts// Compose a new class from the Sprite class, // with the Mixin Scale applier: const
TryEightBitSprite =Scale (Sprite ); constflappySprite = newEightBitSprite ("Bird");flappySprite .setScale (0.8);console .log (flappySprite .scale );
Constrained Mixins
In the above form, the mixin’s have no underlying knowledge of the class which can make it hard to create the design you want.
To model this, we modify the original constructor type to accept a generic argument.
ts// This was our previous constructor: type
TryConstructor = new (...args : any[]) => {}; // Now we use a generic version which can apply a constraint on // the class which this mixin is applied to typeGConstructor <T = {}> = new (...args : any[]) =>T ;
This allows for creating classes which only work with constrained base classes:
tstype
TryPositionable =GConstructor <{setPos : (x : number,y : number) => void }>; typeSpritable =GConstructor <typeofSprite >; typeLoggable =GConstructor <{
Then you can create mixins which only work when you have a particular base to build on:
tsfunction
TryJumpable <TBase extendsPositionable >(Base :TBase ) { return classJumpable extendsBase {jump () { // This mixin will only work if it is passed a base // class which has setPos defined because of the // Positionable constraint. this.setPos (0, 20); } }; }
Alternative Pattern
Previous versions of this document recommended a way to write mixins where you created both the runtime and type hierarchies separately, then merged them at the end:
ts// Each mixin is a traditional ES class class
TryJumpable {jump () {} } classDuckable {duck () {} } // Including the base classSprite {x = 0;y = 0; } // Then you create an interface which merges // the expected mixins with the same name as your base interfaceSprite extendsJumpable ,Duckable {} // Apply the mixins into the base class via // the JS at runtimeapplyMixins (Sprite , [Jumpable ,Duckable ]); letplayer = newSprite ();player .jump ();console .log (player .x ,player .y ); // This can live anywhere in your codebase: functionapplyMixins (derivedCtor : any,constructors : any[]) {constructors .forEach ((baseCtor ) => {Object .getOwnPropertyNames (baseCtor .prototype ).forEach ((name ) => {Object .defineProperty (derivedCtor .prototype ,name ,Object .getOwnPropertyDescriptor (baseCtor .prototype ,name ) ); }); }); }
This pattern relies less on the compiler, and more on your codebase to ensure both runtime and type-system are correctly kept in sync.
Constraints
The mixin pattern is supported natively inside the TypeScript compiler by code flow analysis. There are a few cases where you can hit the edges of the native support.
Decorators and Mixins #4881
You cannot use decorators to provide mixins via code flow analysis:
ts// A decorator function which replicates the mixin pattern: const
TryPausable = (target : typeofPlayer ) => { return classPausable extendstarget {shouldFreeze = false; }; }; @Pausable classPlayer {x = 0;y = 0; } // The Player class does not have the decorator's type merged: constplayer = newPlayer ();player .; Property 'shouldFreeze' does not exist on type 'Player'.2339Property 'shouldFreeze' does not exist on type 'Player'. // It the runtime aspect could be manually replicated via // type composition or interface merging. type shouldFreeze FreezablePlayer = typeofPlayer & {shouldFreeze : boolean }; constplayerTwo = (newPlayer () as unknown) asFreezablePlayer ;playerTwo .shouldFreeze ;
Static Property Mixins #17829
More of a gotcha then a constraint. The class expression pattern creates singletons, so they can’t be mapped at the type system to support different variable types.
You can work around this by using functions to return your classes which differ based on a generic:
tsfunction
Trybase <T >() { classBase { staticprop :T ; } returnBase ; } functionderived <T >() { classDerived extendsbase <T >() { staticanotherProp :T ; } returnDerived ; } classSpec extendsderived <string>() {}Spec .prop ; // stringSpec .anotherProp ; // string