declare.d.ts
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r15 | declare module "./kernel" { | ||
interface Dojo { | ||||
declare: declare.Declare; | ||||
safeMixin: typeof declare.safeMixin; | ||||
} | ||||
} | ||||
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r2 | |||
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r15 | declare namespace declare { | ||
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r2 | interface DeclareCreatedObject { | ||
declaredClass: string; | ||||
/** | ||||
* Calls a super method. | ||||
* | ||||
* This method is used inside method of classes produced with | ||||
* declare() to call a super method (next in the chain). It is | ||||
* used for manually controlled chaining. Consider using the regular | ||||
* chaining, because it is faster. Use "this.inherited()" only in | ||||
* complex cases. | ||||
* | ||||
* This method cannot me called from automatically chained | ||||
* constructors including the case of a special (legacy) | ||||
* constructor chaining. It cannot be called from chained methods. | ||||
* | ||||
* If "this.inherited()" cannot find the next-in-chain method, it | ||||
* does nothing and returns "undefined". The last method in chain | ||||
* can be a default method implemented in Object, which will be | ||||
* called last. | ||||
* | ||||
* If "name" is specified, it is assumed that the method that | ||||
* received "args" is the parent method for this call. It is looked | ||||
* up in the chain list and if it is found the next-in-chain method | ||||
* is called. If it is not found, the first-in-chain method is | ||||
* called. | ||||
* | ||||
* If "name" is not specified, it will be derived from the calling | ||||
* method (using a methoid property "nom"). | ||||
*/ | ||||
inherited<U>(args: IArguments, newArgs?: any[]): U; | ||||
inherited(args: IArguments, newArgs?: true): Function | void; | ||||
inherited<U>(name: string, args: IArguments, newArgs?: any[]): U; | ||||
inherited(name: string, args: IArguments, newArgs?: true): Function | void; | ||||
/** | ||||
* Returns a super method. | ||||
* | ||||
* This method is a convenience method for "this.inherited()". | ||||
* It uses the same algorithm but instead of executing a super | ||||
* method, it returns it, or "undefined" if not found. | ||||
*/ | ||||
getInherited(args: IArguments): Function | void; | ||||
getInherited(name: string, args: IArguments): Function | void; | ||||
/** | ||||
* Checks the inheritance chain to see if it is inherited from this class. | ||||
* | ||||
* This method is used with instances of classes produced with | ||||
* declare() to determine of they support a certain interface or | ||||
* not. It models "instanceof" operator. | ||||
*/ | ||||
isInstanceOf(cls: any): boolean; | ||||
} | ||||
interface DeclareConstructor<T> { | ||||
new(...args: any[]): T & DeclareCreatedObject; | ||||
prototype: T; | ||||
/** | ||||
* Adds all properties and methods of source to constructor's | ||||
* prototype, making them available to all instances created with | ||||
* constructor. This method is specific to constructors created with | ||||
* declare(). | ||||
* | ||||
* Adds source properties to the constructor's prototype. It can | ||||
* override existing properties. | ||||
* | ||||
* This method is similar to dojo.extend function, but it is specific | ||||
* to constructors produced by declare(). It is implemented | ||||
* using dojo.safeMixin, and it skips a constructor property, | ||||
* and properly decorates copied functions. | ||||
*/ | ||||
extend<U>(source: U): DeclareConstructor<T & U>; | ||||
/** | ||||
* Create a subclass of the declared class from a list of base classes. | ||||
* | ||||
* Create a constructor using a compact notation for inheritance and | ||||
* prototype extension. | ||||
* | ||||
* Mixin ancestors provide a type of multiple inheritance. | ||||
* Prototypes of mixin ancestors are copied to the new class: | ||||
* changes to mixin prototypes will not affect classes to which | ||||
* they have been mixed in. | ||||
*/ | ||||
createSubclass<U, V, X>(mixins: [DeclareConstructor<U>, DeclareConstructor<V>], props: X): DeclareConstructor<T & U & V & X>; | ||||
createSubclass<U, V>(mixins: [DeclareConstructor<U>], props: V): DeclareConstructor<T & U & V>; | ||||
createSubclass<U, V>(mixins: DeclareConstructor<U>, props: V): DeclareConstructor<T & U & V>; | ||||
createSubclass<U>(mixins: [DeclareConstructor<U>]): DeclareConstructor<T & U>; | ||||
createSubclass<U>(mixins: DeclareConstructor<U>): DeclareConstructor<T & U>; | ||||
createSubclass<U>(mixins: any, props: U): DeclareConstructor<T & U>; | ||||
} | ||||
interface Declare { | ||||
<A, B, C, D>(superClass: [DeclareConstructor<A>, DeclareConstructor<B>, DeclareConstructor<C>, DeclareConstructor<D>]): DeclareConstructor<A & B & C & D>; | ||||
<A, B, C>(superClass: [DeclareConstructor<A>, DeclareConstructor<B>, DeclareConstructor<C>]): DeclareConstructor<A & B & C>; | ||||
<A, B>(superClass: [DeclareConstructor<A>, DeclareConstructor<B>]): DeclareConstructor<A & B>; | ||||
<A>(superClass: DeclareConstructor<A> | [DeclareConstructor<A>]): DeclareConstructor<A>; | ||||
<A, B, C, D, E>(superClass: [DeclareConstructor<A>, DeclareConstructor<B>, DeclareConstructor<C>, DeclareConstructor<D>], props: E): DeclareConstructor<A & B & C & D & E>; | ||||
<A, B, C, D>(superClass: [DeclareConstructor<A>, DeclareConstructor<B>, DeclareConstructor<C>], props: D): DeclareConstructor<A & B & C & D>; | ||||
<A, B, C>(superClass: [DeclareConstructor<A>, DeclareConstructor<B>], props: C): DeclareConstructor<A & B & C>; | ||||
<A, B>(superClass: DeclareConstructor<A> | [DeclareConstructor<A>], props: B): DeclareConstructor<A & B>; | ||||
<A, B, C, D>(className: string, superClass: [DeclareConstructor<A>, DeclareConstructor<B>, DeclareConstructor<C>, DeclareConstructor<D>]): DeclareConstructor<A & B & C & D>; | ||||
<A, B, C>(className: string, superClass: [DeclareConstructor<A>, DeclareConstructor<B>, DeclareConstructor<C>]): DeclareConstructor<A & B & C>; | ||||
<A, B>(className: string, superClass: [DeclareConstructor<A>, DeclareConstructor<B>]): DeclareConstructor<A & B>; | ||||
<A>(className: string, superClass: DeclareConstructor<A> | [DeclareConstructor<A>]): DeclareConstructor<A>; | ||||
<A, B, C, D, E>(className: string, superClass: [DeclareConstructor<A>, DeclareConstructor<B>, DeclareConstructor<C>, DeclareConstructor<D>], props: E): DeclareConstructor<A & B & C & D & E>; | ||||
<A, B, C, D>(className: string, superClass: [DeclareConstructor<A>, DeclareConstructor<B>, DeclareConstructor<C>], props: D): DeclareConstructor<A & B & C & D>; | ||||
<A, B, C>(className: string, superClass: [DeclareConstructor<A>, DeclareConstructor<B>], props: C): DeclareConstructor<A & B & C>; | ||||
<A, B>(className: string, superClass: DeclareConstructor<A> | [DeclareConstructor<A>], props: B): DeclareConstructor<A & B>; | ||||
<A>(className: string, superClass: any, props: A): DeclareConstructor<A>; | ||||
(className: string, superClass: any): DeclareConstructor<any>; | ||||
<A>(superClass: any, props: A): DeclareConstructor<A>; | ||||
(superClass: any): DeclareConstructor<any>; | ||||
/** | ||||
* Mix in properties skipping a constructor and decorating functions | ||||
* like it is done by declare(). | ||||
*/ | ||||
safeMixin<A, B>(target: A, source: B): A & B; | ||||
} | ||||
} | ||||
declare const declare: declare.Declare; | ||||
export = declare; | ||||