Interface type check with Typescript

Question

This question is the direct analogon to Class type check in 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 ?

Answer 1

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);
}

Answer 2

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.

Answer 3

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();
}

Answer 4

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;
    }
}

Answer 5

Type guards in Typescript:

TS has type guards for this purpose. They define it in the following manner:

Some expression that performs a runtime check that guarantees the type in some scope.

This basically means that the TS compiler can narrow down the type to a more specific type when it has sufficient information. For example:

function foo (arg: number | string) {
    if (typeof arg === 'number') {
        // fine, type number has toFixed method
        arg.toFixed()
    } else {
        // Property 'toFixed' does not exist on type 'string'. Did you mean 'fixed'?
        arg.toFixed()
        // TSC can infer that the type is string because 
        // the possibility of type number is eliminated at the if statement
    }
}

To come back to your question, we can also apply this concept of type guards to objects in order to determine their type. To define a type guard for objects, we need to define a function whose return type is a type predicate. For example:

interface Dog {
    bark: () => void;
}

// The function isDog is a user defined type guard
// the return type: 'pet is Dog' is a type predicate, 
// it determines whether the object is a Dog
function isDog(pet: object): pet is Dog {
  return (pet as Dog).bark !== undefined;
}

const dog: any = {bark: () => {console.log('woof')}};

if (isDog(dog)) {
    // TS now knows that objects within this if statement are always type Dog
    // This is because the type guard isDog narrowed down the type to Dog
    dog.bark();
}

Answer 6

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

Answer 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); }

Answer 8

Approaching 9 years since OP, and this problem remains. I really REALLY want to love Typescript. And usually I succeed. But its loopholes in type safety is a foul odor that my pinched nose can't block.

My goto solutions aren't perfect. But my opinion is they are better than most of the more commonly prescribed solutions. Discriminators have proven to be a bad practice because they limit scalability and defeat the purpose of type safety altogether. My 2 prettiest butt-ugly solutions are, in order:

Class Decorator: Recursively scans the typed object's members and computes a hash based on the symbol names. Associates the hash with the type name in a static KVP property. Include the type name in the hash calculation to mitigate risk of ambiguity with ancestors (happens with empty subclasses). Pros: It's proven to be the most trustworthy. It is also provides very strict enforcements. This is also similar to how other high-level languages natively implement polymorphism. Howbeit, the solution requires much further extension in order to be truly polymorphic. Cons: Anonymous/JSON objects have to be rehashed with every type check, since they have no type definitions to associate and statically cache. Excessive stack overhead results in significant performance bottlenecks in high load scenarios. Can be mitigated with IoC containers, but that can also be undesirable overhead for small apps with no other rationale. Also requires extra diligence to apply the decorator to every object requiring it.

Cloning: Very ugly, but can be beneficial with thoughtful strategies. Create a new instance of the typed object and reflexively copy the top-level member assignments from the anonymous object. Given a predetermined standard for passage, you can simultaneously check and clone-cast to types. Something akin to "tryParse" from other languages. Pros: In certain scenarios, resource overhead can be mitigated by immediately using the converted "test" instance. No additional diligence required for decorators. Large amount of flexibility tolerances. Cons: Memory leaks like a flour sifter. Without a "deep" clone, mutated references can break other components not anticipating the breach of encapsulation. Static caching not applicable, so operations are executed on each and every call--objects with high quantities of top-level members will impact performance. Developers who are new to Typescript will mistake you for a junior due to not understanding why you've written this kind of pattern.

All totalled: I don't buy the "JS doesn't support it" excuse for Typescript's nuances in polymorphism. Transpilers are absolutely appropriate for that purpose. To treat the wounds with salt: it comes from Microsoft. They've solved this same problem many years ago with great success: .Net Framework offered a robust Interop API for adopting backwards compatibility with COM and ActiveX. They didn't try to transpile to the older runtimes. That solution would have been much easier and less messy for a loose and interpreted language like JS...yet they cowered out with the fear of losing ground to other supersets. Using the very shortcomings in JS that was meant to be solved by TS, as a malformed basis for redefining static typed Object-Oriented principle is--well--nonsense. It smacks against the volumes of industry-leading documentation and specifications which have informed high-level software development for decades.

Answer 9

In my opinion this is the best approach; attach a "Fubber" symbol to the interfaces. It is MUCH faster to write, MUCH faster for the JavaScript engine than a type guard, supports inheritance for interfaces and makes type guards easy to write if you need them.

This is the purpose for which ES6 has symbols.

Interface

// Notice there is no naming conflict, because interfaces are a *type*
export const IAnimal = Symbol("IAnimal"); 
export interface IAnimal {
  [IAnimal]: boolean; // the fubber
}

export const IDog = Symbol("IDog");
export interface IDog extends IAnimal {
  [IDog]: boolean;
}

export const IHound = Symbol("IDog");
export interface IHound extends IDog {
  // The fubber can also be typed as only 'true'; meaning it can't be disabled.
  [IDog]: true;
  [IHound]: boolean;
}

Class

import { IDog, IAnimal } from './interfaces';
class Dog implements IDog {
  // Multiple fubbers to handle inheritance:
  [IAnimal] = true;
  [IDog] = true;
}

class Hound extends Dog implements IHound {
  [IHound] = true;
}

Testing

This code can be put in a type guard if you want to help the TypeScript compiler.

import { IDog, IAnimal } from './interfaces';

let dog = new Dog();

if (dog instanceof Hound || dog[IHound]) {
  // false
}
if (dog[IAnimal]?) {
  // true
}

let houndDog = new Hound();

if (houndDog[IDog]) {
  // true
}

if (dog[IDog]?) {
  // it definitely is a dog
}

Answer 10

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) {
    ...
}

Answer 11

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);

Answer 12

TypeGuards

interface MyInterfaced {
    x: number
}

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

if (isMyInterfaced(obj)) {
    (obj as MyInterfaced ).x;
}

Answer 13

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

Answer 14

I found an example from @progress/kendo-data-query in file filter-descriptor.interface.d.ts

Checker

declare const isCompositeFilterDescriptor: (source: FilterDescriptor | CompositeFilterDescriptor) => source is CompositeFilterDescriptor;

Example usage

const filters: Array<FilterDescriptor | CompositeFilterDescriptor> = filter.filters;

filters.forEach((element: FilterDescriptor | CompositeFilterDescriptor) => {
    if (isCompositeFilterDescriptor(element)) {
        // element type is CompositeFilterDescriptor
    } else {
        // element type is FilterDescriptor
    }
});

Answer 15

I knew I'd stumbled across a github package that addressed this properly, and after trawling through my search history I finally found it. Check out typescript-is - though it requires your code to be compiled using ttypescript (I am currently in the process of bullying it into working with create-react-app, will update on the success/failure later), you can do all sorts of crazy things with it. The package is also actively maintained, unlike ts-validate-type.

You can check if something is a string or number and use it as such, without the compiler complaining:

import { is } from 'typescript-is';

const wildString: any = 'a string, but nobody knows at compile time, because it is cast to `any`';

if (is<string>(wildString)) { // returns true
    // wildString can be used as string!
} else {
    // never gets to this branch
}

if (is<number>(wildString)) { // returns false
    // never gets to this branch
} else {
    // Now you know that wildString is not a number!
}

You can also check your own interfaces:

import { is } from 'typescript-is';

interface MyInterface {
    someObject: string;
    without: string;
}

const foreignObject: any = { someObject: 'obtained from the wild', without: 'type safety' };

if (is<MyInterface>(foreignObject)) { // returns true
    const someObject = foreignObject.someObject; // type: string
    const without = foreignObject.without; // type: string
}

Answer 16

You can validate a TypeScript type at runtime using ts-validate-type, like so (does require a Babel plugin though):

const user = validateType<{ name: string }>(data);

Answer 17

Type guards in Typescript using Reflect

Here is an example of a type guard from my Typescript game engine

 export interface Start {
    /**
     * Start is called on the frame when a script is enabled just before any of the Update methods are called the first time.
     */
     start(): void
 }


/**
  * User Defined Type Guard for Start
  */
 export const implementsStart = (arg: any): arg is Start => {
     return Reflect.has(arg, 'start')
 } 


 /**
  * Example usage of the type guard
  */

 start() {
    this.components.forEach(component => {
        if (implementsStart(component)) {
            component.start()
        }  

    })
}

Answer 18

Sample Code Link

function instanceOf<T>(data: any, key: string): data is T {
  return key in data;
}

interface Product {}

interface SubscriptionProduct extends Product {
  subscriptionDetails: {};
}

interface GiftProduct extends Product {
  giftDetails: {};
}

interface RewardProduct extends Product {
  rewardDetails: {};
}

function instanceOf<T>(data: any, key: string): data is T {
  return key in data;
}

const purchaseProduct = (product: Product) => {
    if (instanceOf<SubscriptionProduct>(product, 'subscriptionDetails')) {
        console.log('SubscriptionProduct');
    } else if (instanceOf<GiftProduct>(product, 'giftDetails')) {
        console.log('GiftProduct');
    } else if (instanceOf<RewardProduct>(product, 'rewardDetails')) {
        console.log('RewardProduct');
    } else {
        console.log('Product');
    }
};

// Print
purchaseProduct({subscriptionDetails:{}});
purchaseProduct({giftDetails:{}});
purchaseProduct({rewardDetails:{}});
purchaseProduct({});

Answer 19

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;
  }

Answer 20

Another solution could be something similar what is used in case of HTMLIFrameElement interface. We can declare a variable with the same name by creating an object by the interface if we know that there is an implementation for it in another module.

declare var HTMLIFrameElement: {
    prototype: HTMLIFrameElement;
    new(): HTMLIFrameElement;
};

So in this situation

interface A {
    member:string;
}

declare var A : {
    prototype: A;
    new(): A;
};

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

should work fine

Answer 21

Not tested...

interface MySuperInterface {}

interface myInterface extends MySuperInterface {
    myObjectVariable: any
}

if ((myObject as MyInterface).myObjectVariable !== undefined)

Answer 22

This answer is very simple. However, this solution is at least possible (though not always ideal) in maybe 3/4 of the cases. So, in other words, this is probably relevant to whomever is reading this.

Let's say I have a very simple function that needs to know a parameter's interface type:

const simpleFunction = (canBeTwoInterfaces: interfaceA | interface B) => { 
  // if interfaceA, then return canBeTwoInterfaces.A
  // if interfaceB, then return canBeTwoInterfaces.B
}

The answers that are getting the most upvotes tend to be using "function checking". i.e.,

const simpleFunction = (canBeTwoInterfaces: interfaceA | interface B) => { 
  if (canBeTwoInterfaces.onlyExistsOnInterfaceA) return canBeTwoInterfaces.A
  else return canBeTwoInterfaces.B
}

However, in the codebase I'm working with, the interfaces I'm needing to check mostly consist optional parameters. Plus, someone else on my team might suddently change the names names without me knowing. If this sounds like the codebase you're working in, then the function below is much safer.

Like I said earlier, this might strike many as being a very obvious thing to do. Nonetheless, it is not obvious to know when and where to apply a given solution, regardless of whether it happens to be a brutally simple one like below.

This is what I would do:

const simpleFunction = (
  canBeTwoInterfaces: interfaceA | interface B,
  whichInterfaceIsIt: 'interfaceA' | 'interfaceB'
) => { 
  if (whichInterfaceIsIt === 'interfaceA') return canBeTwoInterface.A
  else return canBeTwoInterfaces.B
}

Answer 23

You can also send multiple inputs to child components, having one be a discriminator, and the other being the actual data, and checking the discriminator in the child component like this:

@Input() data?: any;
@Input() discriminator?: string;

ngOnInit(){
    if(this.discriminator = 'InterfaceAName'){
      //do stuff
    }
    else if(this.discriminator = 'InterfaceBName'){
      //do stuff
    }
}

Obviously you can move this into wherever it is applicable to use, like an ngOnChanges function or a setter function, but the idea still stands. I would also recommend trying to tie an ngModel to the input data if you want a reactive form. You can use these if statements to set the ngModel based on the data being passed in, and reflect that in the html with either:

<div [(ngModel)]={{dataModel}}>
    <div *ngFor="let attr of (data | keyvalue)">
        <!--You can use attr.key and attr.value in this situation to display the attributes of your interface, and their associated values from the data -->
    </div>
</div>

Or This Instead:

<div *ngIf = "model == 'InterfaceAName'">
    <div>Do This Stuff</div>
</div>
<div *ngIf= "model == 'IntefaceBName'">
    <div>Do this instead</div>
</div>

(You can use attr.key and attr.value in this situation to display the attributes of your interface, and their associated values from the data)

I know the question is already answered, but I thought this might be useful for people trying to build semi-ambiguous angular forms. You can also use this for angular material modules (dialog boxes for example), by sending in two variables through the data parameter--one being your actual data, and the other being a discriminator, and checking it through a similar process. Ultimately, this would allow you to create one form, and shape the form around the data being flowed into it.

Answer 24

The premise of the question is that interface should provide runtime identification of what objects implement a given interface. But that's not how Interface has been designed in TypeScript because, as both the OP and others have said, Interfaces simply do not exist at runtime. The implications of that design choice is that at runtime, interfaces are no more than a collection of JavaScript object properties.

To do a runtime check, you can do the hacky thing of checking for the individual members in the interface:

interface A{
    member:string;
}

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

This is essentially what a lot of the proposed workarounds, including type guards, boil down to. This has obvious limitation when there are multiple members in the interface (should I check for them all? should I define an interface identifier/discriminator property?) and will in some cases require additional type checks on the members to pass the TS compiler's type checker. (E.g., another interface might implement member as number).

If the idea is to allow objects to exhibit behavior depending on what interfaces are present, then a better pattern is to use a base interface with a common method (or methods) to trigger behavior and then extend the base interface to add specialized properties and/or methods. Extending the OPs example:

interface A { //Base interface that all objects in the collection will implement
    talk():string
}

interface B extends A { //Specialized interface
    member: string
}

var a:A = {
    talk() {return 'got no member'}
}

var b:B = {
    member: 's',
    talk() {return 'my member is '+this.member}
}

for(let item of [a,b]) { //We can now loop over both object types and get the relevant response
    console.log(item, item.talk());
}

The point being that implementations of either interface are forced to implement a talk method with a common spec, which is enforced by the type checker. The compiler's type checking becomes increasingly valuable as the interfaces grow in complexity.

The biggest weakness of TypeScript's Interface is the lack of default implementations. You can fake it by defining a default object implementation of the interface and copying from it, like var defaultA = {talk() {'no member'}}; var a = {...defaultA}, but it would be much cleaner if it was possible to specify the defaults in the interface definition.

With many objects implementing the same interfaces, it is better to implement them as classes using the implements keyword in a class definition, which typically improves memory usage and performance. It also allows for multiple inheritance of interfaces and is another way to populate default behavior for objects.

Answer 25

Working with string literals is difficult because if you want to refactor you method or interface names then it could be possible that your IDE don't refactor these string literals. I provide you mine solution which works if there is at least one method in the interface

export class SomeObject implements interfaceA {
  public methodFromA() {}
}

export interface interfaceA {
  methodFromA();
}

Check if object is of type interface:

const obj = new SomeObject();
const objAsAny = obj as any;
const objAsInterfaceA = objAsAny as interfaceA;
const isObjOfTypeInterfaceA = objAsInterfaceA.methodFromA != null;
console.log(isObjOfTypeInterfaceA)

Note: We will get true even if we remove 'implements interfaceA' because the method still exists in the SomeObject class

Answer 26

Simple workaround solution having the same drawbacks as the selected solution, but this variant catches JS errors, only accepts objects as parameter, and has a meaningful return value.

interface A{
    member:string;
}

const implementsA = (o: object): boolean => {
    try {
        return 'member' in o;
    } catch (error) {
        return false;
    }
}

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

implementsA(a) && console.log("a implements A");
// implementsA("str"); // causes TS transpiler error

Answer 27

I know the question is a bit old, but just my 50 cents. This worked for me:

const container: Container = icc.controlComponent as unknown as Container;
if (container.getControlComponents) {
    this.allControlComponents.push(...container.getControlComponents());
}

Container is the interface, and icc.controlComponent is the object I wanted to check, and getControlComponents is a method from Container interface.

Answer 28

TypeScript works only in compile-time, but instanceof is a runtime thing. You can't use on a type, because types doesn't exist in javascript.

You can use a validator library like zod. Then, you can infer the ("TypeScript") type of the object and validate it with zod.

Per example,

import { z } from 'zod';

export const ItemSchema = z.object({
  name: z.string(),
  description: z.string(),
  productServiceId: z.number().optional(),
});

export type Item = z.infer<typeof ItemSchema>;

const validateItems = (items: Item[]) => {
    const ItemSchemaArray = z.array(ItemSchema);
    ItemSchemaArray.parse(items);
};

Answer 29

Here's the solution I came up with using classes and lodash: (it works!)

// TypeChecks.ts
import _ from 'lodash';

export class BakedChecker {
    private map: Map<string, string>;

    public constructor(keys: string[], types: string[]) {
        this.map = new Map<string, string>(keys.map((k, i) => {
            return [k, types[i]];
        }));
        if (this.map.has('__optional'))
            this.map.delete('__optional');
    }

    getBakedKeys() : string[] {
        return Array.from(this.map.keys());
    }

    getBakedType(key: string) : string {
        return this.map.has(key) ? this.map.get(key) : "notfound";
    }
}

export interface ICheckerTemplate {
    __optional?: any;
    [propName: string]: any;
}

export function bakeChecker(template : ICheckerTemplate) : BakedChecker {
    let keys = _.keysIn(template);
    if ('__optional' in template) {
        keys = keys.concat(_.keysIn(template.__optional).map(k => '?' + k));
    }
    return new BakedChecker(keys, keys.map(k => {
        const path = k.startsWith('?') ? '__optional.' + k.substr(1) : k;
        const val = _.get(template, path);
        if (typeof val === 'object') return val;
        return typeof val;
    }));
}

export default function checkType<T>(obj: any, template: BakedChecker) : obj is T {
    const o_keys = _.keysIn(obj);
    const t_keys = _.difference(template.getBakedKeys(), ['__optional']);
    return t_keys.every(tk => {
        if (tk.startsWith('?')) {
            const ak = tk.substr(1);
            if (o_keys.includes(ak)) {
                const tt = template.getBakedType(tk);
                if (typeof tt === 'string')
                    return typeof _.get(obj, ak) === tt;
                else {
                    return checkType<any>(_.get(obj, ak), tt);
                }
            }
            return true;
        }
        else {
            if (o_keys.includes(tk)) {
                const tt = template.getBakedType(tk);
                if (typeof tt === 'string')
                    return typeof _.get(obj, tk) === tt;
                else {
                    return checkType<any>(_.get(obj, tk), tt);
                }
            }
            return false;
        }
    });
}

custom classes:

// MyClasses.ts

import checkType, { bakeChecker } from './TypeChecks';

class Foo {
    a?: string;
    b: boolean;
    c: number;

    public static _checker = bakeChecker({
        __optional: {
            a: ""
        },
        b: false,
        c: 0
    });
}

class Bar {
    my_string?: string;
    another_string: string;
    foo?: Foo;

    public static _checker = bakeChecker({
        __optional: {
            my_string: "",
            foo: Foo._checker
        },
        another_string: ""
    });
}

to check the type at runtime:

if (checkType<Bar>(foreign_object, Bar._checker)) { ... }

Answer 30

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": "[email protected]",
      "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.