229

This question is the direct analogon to Class type check with TypeScript

I need to find out at runtime if a variable of type any implements an interface. Here's my code:

interface A{
    member:string;
}

var a:any={member:"foobar"};

if(a instanceof A) alert(a.member);

If you enter this code in the typescript playground, the last line will be marked as an error, "The name A does not exist in the current scope". But that isn't true, the name does exist in the current scope. I can even change the variable declaration to var a:A={member:"foobar"}; without complaints from the editor. After browsing the web and finding the other question on SO I changed the interface to a class but then I can't use object literals to create instances.

I wondered how the type A could vanish like that but a look at the generated javascript explains the problem:

var a = {
    member: "foobar"
};
if(a instanceof A) {
    alert(a.member);
}

There is no representation of A as an interface, therefore no runtime type checks are possible.

I understand that javascript as a dynamic language has no concept of interfaces. Is there any way to type check for interfaces?

The typescript playground's autocompletion reveals that typescript even offers a method implements. How can I use it ?

  • 3
    JavaScript has no concept of interfaces, but that isn't because it is a dynamic language. It's because interfaces aren't implemented yet. – trusktr Feb 16 '17 at 1:53
  • Yes, but you can use class instead interface. See this example. – Alexey Baranoshnikov Dec 17 '18 at 11:22

12 Answers 12

166

You can achieve what you want without the instanceof keyword as you can write custom type guards now:

interface A{
    member:string;
}

function instanceOfA(object: any): object is A {
    return 'member' in object;
}

var a:any={member:"foobar"};

if (instanceOfA(a)) {
    alert(a.member);
}

Lots of Members

If you need to check a lot of members to determine whether an object matches your type, you could instead add a discriminator. The below is the most basic example, and requires you to manage your own discriminators... you'd need to get deeper into the patterns to ensure you avoid duplicate discriminators.

interface A{
    discriminator: 'I-AM-A';
    member:string;
}

function instanceOfA(object: any): object is A {
    return object.discriminator === 'I-AM-A';
}

var a:any = {discriminator: 'I-AM-A', member:"foobar"};

if (instanceOfA(a)) {
    alert(a.member);
}
  • 53
    "There is no way to runtime check an interface." There is, they just haven't implemented it yet for whatever reason. – trusktr Feb 16 '17 at 1:54
  • 6
    And if the interface has 100 members, you need to check all 100? Foobar. – Jenny O'Reilly Nov 24 '17 at 10:43
  • 2
    You could add a discriminator to your object rather than check all 100... – Fenton Nov 24 '17 at 11:03
  • 4
    this discriminator paradigm (as written here) doesn't support extending interfaces. A derived interface would return false if checking if it is an instanceOf a base interface. – Aaron May 17 '18 at 15:20
  • 1
    @Fenton Perhaps I don't know enough about this, but suppose you had an interface B that extends interface A, you'd want isInstanceOfA(instantiatedB) to return true, but you'd want isInstanceOfB(instantiatedA) to return false. For the latter to occur, wouldn't the discriminator of B have to not be 'I-AM-A'? – Aaron May 18 '18 at 17:12
69

In TypeScript 1.6, user-defined type guard will do the job.

interface Foo {
    fooProperty: string;
}

interface Bar {
    barProperty: string;
}

function isFoo(object: any): object is Foo {
    return 'fooProperty' in object;
}

let object: Foo | Bar;

if (isFoo(object)) {
    // `object` has type `Foo`.
    object.fooProperty;
} else {
    // `object` has type `Bar`.
    object.barProperty;
}

And just as Joe Yang mentioned: since TypeScript 2.0, you can even take the advantage of tagged union type.

interface Foo {
    type: 'foo';
    fooProperty: string;
}

interface Bar {
    type: 'bar';
    barProperty: number;
}

let object: Foo | Bar;

// You will see errors if `strictNullChecks` is enabled.
if (object.type === 'foo') {
    // object has type `Foo`.
    object.fooProperty;
} else {
    // object has type `Bar`.
    object.barProperty;
}

And it works with switch too.

  • This looks rather curious. Apparently there is some kind of meta-information available. Why expose it with this type-guard syntax. Due to which constraints does "object is interface" next to a function work, as opposed to isinstanceof ? More precisely, could you use "object is interface" in the if statements directly ? But in any case, very interesting syntax, +1 from me. – lhk Dec 25 '15 at 8:36
  • 1
    @lhk No there isn't such a statement, it's more like a special type that tells how should a type be narrowed inside conditional branches. Due to the "scope" of TypeScript, I believe there won't be such a statement even in the future. Another different between object is type and object instanceof class is that, type in TypeScript is structural, it cares only the "shape" instead of where did an object get the shape from: a plain object or an instance of a class, it doesn't matter. – vilicvane Dec 26 '15 at 9:29
  • 2
    Just to clear a misconception this answer can create: there's no meta information to deduct object type or its interface during runtime. – mostruash Mar 30 '16 at 22:09
  • @mostruash Yep, the second half of the answer won't work at runtime even though it compiles. – trusktr Feb 16 '17 at 1:58
  • 3
    Oh, but, this must assume that at runtime these objects will have been created with a type property. In that case it works. That example doesn't show this fact. – trusktr Feb 16 '17 at 2:00
35

typescript 2.0 introduce tagged union

Typescript 2.0 features

interface Square {
    kind: "square";
    size: number;
}

interface Rectangle {
    kind: "rectangle";
    width: number;
    height: number;
}

interface Circle {
    kind: "circle";
    radius: number;
}

type Shape = Square | Rectangle | Circle;

function area(s: Shape) {
    // In the following switch statement, the type of s is narrowed in each case clause
    // according to the value of the discriminant property, thus allowing the other properties
    // of that variant to be accessed without a type assertion.
    switch (s.kind) {
        case "square": return s.size * s.size;
        case "rectangle": return s.width * s.height;
        case "circle": return Math.PI * s.radius * s.radius;
    }
}
  • I am using 2.0 beta but tagged union does not work. <TypeScriptToolsVersion>2.0</TypeScriptToolsVersion> – Makla Aug 10 '16 at 10:40
  • Compiled with nightly build, but intellisense does not work. It also list errors: Property width/size/... does not exists on Type 'Square | Rectangle | Circle in case statement. But it compiles. – Makla Aug 10 '16 at 11:12
  • 8
    This is really just using a discriminator. – Erik Philips Apr 16 '18 at 20:28
26

How about User-Defined Type Guards? https://www.typescriptlang.org/docs/handbook/advanced-types.html

interface Bird {
    fly();
    layEggs();
}

interface Fish {
    swim();
    layEggs();
}

function isFish(pet: Fish | Bird): pet is Fish { //magic happens here
    return (<Fish>pet).swim !== undefined;
}

// Both calls to 'swim' and 'fly' are now okay.

if (isFish(pet)) {
    pet.swim();
}
else {
    pet.fly();
}
  • 3
    This is my favorite answer - similar to stackoverflow.com/a/33733258/469777 but without magic strings that may break due to things like minification. – Stafford Williams Sep 26 '16 at 9:17
  • 1
    This did not work for me for some reason but (pet as Fish).swim !== undefined; did. – CyberMew Jul 9 at 3:05
14

It's now possible, I just released an enhanced version of the TypeScript compiler that provides full reflection capabilities. You can instantiate classes from their metadata objects, retrieve metadata from class constructors and inspect interface/classes at runtime. You can check it out here

Usage example:

In one of your typescript files, create an interface and a class that implements it like the following:

interface MyInterface {
    doSomething(what: string): number;
}

class MyClass implements MyInterface {
    counter = 0;

    doSomething(what: string): number {
        console.log('Doing ' + what);
        return this.counter++;
    }
}

now let's print some the list of implemented interfaces.

for (let classInterface of MyClass.getClass().implements) {
    console.log('Implemented interface: ' + classInterface.name)
}

compile with reflec-ts and launch it:

$ node main.js
Implemented interface: MyInterface
Member name: counter - member kind: number
Member name: doSomething - member kind: function

See reflection.d.ts for Interface meta-type details.

UPDATE: You can find a full working example here

  • 7
    downvoted cos I thought this was stupid, but then paused for a second, looked at your github page and saw it was kept up to date and well documented so upvoted instead :-) I still can't justify using it myself right now just for implements but wanted to recognize your commitment and didn't want to be mean :-) – Simon_Weaver Aug 23 '16 at 9:34
  • 3
    Actually, the main purpose I see of this reflection features is to create better IoC frameworks like the ones the Java world already has since long time (Spring is the first and most important one). I firmly believe that TypeScript can become one of the best development tools of the future and reflection is one of the features it really needs. – pcan Aug 24 '16 at 10:11
  • 4
    ...uh, so what, we have to roll these compiler "enhancements" into any future build of Typescript? This is effectively a fork of Typescript, not Typescript itself, right? If so, this isn't a feasible long-term solution. – dudewad Dec 7 '16 at 21:01
  • 1
    @dudewad as said in many other topics, this is a temporary solution. We are waiting compiler extensibility through transformers. Please see related issues in the official TypeScript repo. Furthermore, all the widely adopted strong-typed languages have reflection, and I think TypeScript should have it too. And like me, many other users think so. – pcan Dec 7 '16 at 21:28
  • yeah its not that I don't agree -- I want this too. Just, spinning up a custom compiler... doesnt that mean the next patch of Typescript needs to get ported? If you're upkeeping it then kudos. Just seems like a lot of work. Not knocking it. – dudewad Dec 7 '16 at 22:23
7

Here's another option: the module ts-interface-builder provides a build-time tool that converts a TypeScript interface into a runtime descriptor, and ts-interface-checker can check if an object satisfies it.

For OP's example,

interface A {
  member: string;
}

You'd first run ts-interface-builder which produces a new concise file with a descriptor, say, foo-ti.ts, which you can use like this:

import fooDesc from './foo-ti.ts';
import {createCheckers} from "ts-interface-checker";
const {A} = createCheckers(fooDesc);

A.check({member: "hello"});           // OK
A.check({member: 17});                // Fails with ".member is not a string" 

You can create a one-liner type-guard function:

function isA(value: any): value is A { return A.test(value); }
6

same as above where user-defined guards were used but this time with an arrow function predicate

interface A {
  member:string;
}

const check = (p: any): p is A => p.hasOwnProperty('member');

var foo: any = { member: "foobar" };
if (check(foo))
    alert(foo.member);
5

I would like to point out that TypeScript does not provide a direct mechanism for dynamically testing whether an object implements a particular interface.

Instead, TypeScript code can use the JavaScript technique of checking whether an appropriate set of members are present on the object. For example:

var obj : any = new Foo();

if (obj.someInterfaceMethod) {
    ...
}
  • 4
    what if you have a complex shape? you would not want to hardcode every single property at each level of depth – Tom Jul 4 '18 at 23:57
  • @Tom I guess you can pass (as a second parameter to the checker function) a run-time value or example/exemplar -- i.e. an object of the interface which you want. Then, instead of hard-coding code, you write any example of the interface which you want ... and write some one-time object-comparison code (using e.g. for (element in obj) {}) to verify that the two objects have the similar elements of similar types. – ChrisW May 8 at 13:11
3

TypeGuards

interface MyInterfaced {
    x: number
}

function isMyInterfaced(arg: any): arg is MyInterfaced {
    return arg.x !== undefined;
}

if (isMyInterfaced(obj)) {
    (obj as MyInterfaced ).x;
}
  • 2
    the "arg is MyInterfaced" is an interesting annotation. What happens if that fails ? Looks like a compile time interface check - which would be just what I wanted in the first place. But if the compiler checks the parameters, why have a function body at all. And if such a check is possible, why move it to a separate function. – lhk Jun 28 '17 at 10:50
  • 1
    @lhk just read typescript documentation about type guards... typescriptlang.org/docs/handbook/advanced-types.html – Dmitry Matveev Jun 28 '17 at 21:13
0

Because the type is unknown at run-time, I wrote code as follows to compare the unknown object, not against a type, but against an object of known type:

  1. Create a sample object of the right type
  2. Specify which of its elements are optional
  3. Do a deep compare of your unknown object against this sample object

Here's the (interface-agnostic) code I use for the deep compare:

function assertTypeT<T>(loaded: any, wanted: T, optional?: Set<string>): T {
  // this is called recursively to compare each element
  function assertType(found: any, wanted: any, keyNames?: string): void {
    if (typeof wanted !== typeof found) {
      throw new Error(`assertType expected ${typeof wanted} but found ${typeof found}`);
    }
    switch (typeof wanted) {
      case "boolean":
      case "number":
      case "string":
        return; // primitive value type -- done checking
      case "object":
        break; // more to check
      case "undefined":
      case "symbol":
      case "function":
      default:
        throw new Error(`assertType does not support ${typeof wanted}`);
    }
    if (Array.isArray(wanted)) {
      if (!Array.isArray(found)) {
        throw new Error(`assertType expected an array but found ${found}`);
      }
      if (wanted.length === 1) {
        // assume we want a homogenous array with all elements the same type
        for (const element of found) {
          assertType(element, wanted[0]);
        }
      } else {
        // assume we want a tuple
        if (found.length !== wanted.length) {
          throw new Error(
            `assertType expected tuple length ${wanted.length} found ${found.length}`);
        }
        for (let i = 0; i < wanted.length; ++i) {
          assertType(found[i], wanted[i]);
        }
      }
      return;
    }
    for (const key in wanted) {
      const expectedKey = keyNames ? keyNames + "." + key : key;
      if (typeof found[key] === 'undefined') {
        if (!optional || !optional.has(expectedKey)) {
          throw new Error(`assertType expected key ${expectedKey}`);
        }
      } else {
        assertType(found[key], wanted[key], expectedKey);
      }
    }
  }

  assertType(loaded, wanted);
  return loaded as T;
}

Below is an example of how I use it.

In this example I expect the JSON contains an array of tuples, of which the second element is an instance of an interface called User (which has two optional elements).

TypeScript's type-checking will ensure that my sample object is correct, then the assertTypeT function checks that the unknown (loaded from JSON) object matches the sample object.

export function loadUsers(): Map<number, User> {
  const found = require("./users.json");
  const sample: [number, User] = [
    49942,
    {
      "name": "ChrisW",
      "email": "example@example.com",
      "gravatarHash": "75bfdecf63c3495489123fe9c0b833e1",
      "profile": {
        "location": "Normandy",
        "aboutMe": "I wrote this!\n\nFurther details are to be supplied ..."
      },
      "favourites": []
    }
  ];
  const optional: Set<string> = new Set<string>(["profile.aboutMe", "profile.location"]);
  const loaded: [number, User][] = assertTypeT(found, [sample], optional);
  return new Map<number, User>(loaded);
}

You could invoke a check like this in the implementation of a user-defined type guard.

0

Based on Fenton's answer, here's my implementation of a function to verify if a given object has the keys an interface has, both fully or partially.

Depending on your use case, you may also need to check the types of each of the interface's properties. The code below doesn't do that.

function implementsTKeys<T>(obj: any, keys: (keyof T)[]): obj is T {
    if (!obj || !Array.isArray(keys)) {
        return false;
    }

    const implementKeys = keys.reduce((impl, key) => impl && key in obj, true);

    return implementKeys;
}

Example of usage:

interface A {
    propOfA: string;
    methodOfA: Function;
}

let objectA: any = { propOfA: '' };

// Check if objectA partially implements A
let implementsA = implementsTKeys<A>(objectA, ['propOfA']);

console.log(implementsA); // true

objectA.methodOfA = () => true;

// Check if objectA fully implements A
implementsA = implementsTKeys<A>(objectA, ['propOfA', 'methodOfA']);

console.log(implementsA); // true

objectA = {};

// Check again if objectA fully implements A
implementsA = implementsTKeys<A>(objectA, ['propOfA', 'methodOfA']);

console.log(implementsA); // false, as objectA now is an empty object
0
export interface ConfSteps {
    group: string;
    key: string;
    steps: string[];
}
private verify(): void {
    const obj = `{
      "group": "group",
      "key": "key",
      "steps": [],
      "stepsPlus": []
    } `;
    if (this.implementsObject<ConfSteps>(obj, ['group', 'key', 'steps'])) {
      console.log(`Implements ConfSteps: ${obj}`);
    }
  }
private objProperties: Array<string> = [];

private implementsObject<T>(obj: any, keys: (keyof T)[]): boolean {
    JSON.parse(JSON.stringify(obj), (key, value) => {
      this.objProperties.push(key);
    });
    for (const key of keys) {
      if (!this.objProperties.includes(key.toString())) {
        return false;
      }
    }
    this.objProperties = null;
    return true;
  }
  • While this code may answer the question, providing additional context regarding why and/or how this code answers the question improves its long-term value. – xiawi 2 days ago

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.