The programming language TypeScript is based on JavaScript, which is strongly typed, object-oriented and compiled. The language is improved with tools like static typing, classes, and interfaces, which aid in early error detection and make JavaScript more manageable. A feature of TypeScript is the ability to enforce the types of indexed members of an object, and this process is also known as index signing.
An index signature is a set of key-value pairs that describe the many properties an object may have. Specify the type of the property name and the type of the property value using values and keys respectively. To enforce the kind of an object's properties, users can take advantage of TypeScript's index signing feature.
Index signatures can effectively enforce certain object properties, but can also make code difficult to understand and maintain. Therefore, it is very important to only use index signatures when necessary.
grammar
let objectName: {
[key: string]: string
}
In the above syntax, 'objectName' is the name of our object, and we force the key to be of type string and the value to be string.
Example 1
In this example, we have two interfaces, Person and PhoneBook. The Person interface defines the structure of a person object, including two attributes: name (string) and age (number). The PhoneBook interface defines an index signature, using the string type as the key and the Person interface as the value. This means that any object that implements the PhoneBook interface can only have properties whose key type is String and whose value type is Person.
Then we defined a variable phoneBook, of type PhoneBook, and assigned an empty object. Then we add some entries to the phonebook where the keys should be names and the values should be Person objects. Finally, we verify through the console log that if we try to put any other type of variable besides the above type, the compiler will report an error.
// Person interface
interface Person {
name: string
age: number
}
// PhoneBook interface
interface PhoneBook {
[key: string]: Person
}
let phoneBook: PhoneBook = {}
phoneBook['Person 1'] = { name: 'ABC', age: 30 }
phoneBook['Person 2'] = { name: 'XYZ', age: 25 }
phoneBook['Person 3'] = { name: 'MNO', age: 10 }
console.log(phoneBook)
When compiling, it will generate the following JavaScript code −
var phoneBook = {};
phoneBook['Person 1'] = { name: 'ABC', age: 30 };
phoneBook['Person 2'] = { name: 'XYZ', age: 25 };
phoneBook['Person 3'] = { name: 'MNO', age: 10 };
console.log(phoneBook);
Output
The above code will produce the following output -
{ 'Person 1': { name: 'ABC', age: 30 },
'Person 2': { name: 'XYZ', age: 25 },
'Person 3': { name: 'MNO', age: 10 } }
Example 2
In this example, we have an interface Product, which defines the structure of a product object with two properties: name (string) and price (number). Then we have another interface ShoppingCart which represents an index signature using a numeric type as the key and the Product interface as the value. Any object that implements the ShoppingCart interface can only have properties with a key type of Number and a value type of Product.
Then we define a variable cart of type ShoppingCart and assign an empty object to it. Then we add some entries to the shopping cart where the key should be the product id and the value should be the product object. We can see that the items are added to the cart correctly, if the value is not of type Product or the product object is missing any of the properties defined in the Product interface, an error will occur.
interface Product {
name: string
price: number
}
// ShoppingCart interface
interface ShoppingCart {
[key: number]: Product
}
let cart: ShoppingCart = {}
cart[1] = { name: 'Shirt', price: 20 }
cart[2] = { name: 'Pants', price: 30 }
cart[3] = { name: 'Shoes', price: 40 }
console.log(cart[1])
console.log(cart[2])
console.log(cart[3])
When compiled, it will generate the following JavaScript code −
var cart = {};
cart[1] = { name: 'Shirt', price: 20 };
cart[2] = { name: 'Pants', price: 30 };
cart[3] = { name: 'Shoes', price: 40 };
console.log(cart[1]);
console.log(cart[2]);
console.log(cart[3]);
Output
The above code will produce the following output -
{ name: 'Shirt', price: 20 }
{ name: 'Pants', price: 30 }
{ name: 'Shoes', price: 40 }
These examples illustrate how to use index signatures to enforce an object's property types. Index signatures are a powerful feature that can help you write more robust and maintainable code, but it's important to use them wisely and only when necessary.
The above is the detailed content of How to enforce type for indexed members of Typescript objects. For more information, please follow other related articles on the PHP Chinese website!
From Websites to Apps: The Diverse Applications of JavaScriptApr 22, 2025 am 12:02 AMJavaScript is widely used in websites, mobile applications, desktop applications and server-side programming. 1) In website development, JavaScript operates DOM together with HTML and CSS to achieve dynamic effects and supports frameworks such as jQuery and React. 2) Through ReactNative and Ionic, JavaScript is used to develop cross-platform mobile applications. 3) The Electron framework enables JavaScript to build desktop applications. 4) Node.js allows JavaScript to run on the server side and supports high concurrent requests.
Python vs. JavaScript: Use Cases and Applications ComparedApr 21, 2025 am 12:01 AMPython is more suitable for data science and automation, while JavaScript is more suitable for front-end and full-stack development. 1. Python performs well in data science and machine learning, using libraries such as NumPy and Pandas for data processing and modeling. 2. Python is concise and efficient in automation and scripting. 3. JavaScript is indispensable in front-end development and is used to build dynamic web pages and single-page applications. 4. JavaScript plays a role in back-end development through Node.js and supports full-stack development.
The Role of C/C in JavaScript Interpreters and CompilersApr 20, 2025 am 12:01 AMC and C play a vital role in the JavaScript engine, mainly used to implement interpreters and JIT compilers. 1) C is used to parse JavaScript source code and generate an abstract syntax tree. 2) C is responsible for generating and executing bytecode. 3) C implements the JIT compiler, optimizes and compiles hot-spot code at runtime, and significantly improves the execution efficiency of JavaScript.
JavaScript in Action: Real-World Examples and ProjectsApr 19, 2025 am 12:13 AMJavaScript's application in the real world includes front-end and back-end development. 1) Display front-end applications by building a TODO list application, involving DOM operations and event processing. 2) Build RESTfulAPI through Node.js and Express to demonstrate back-end applications.
JavaScript and the Web: Core Functionality and Use CasesApr 18, 2025 am 12:19 AMThe main uses of JavaScript in web development include client interaction, form verification and asynchronous communication. 1) Dynamic content update and user interaction through DOM operations; 2) Client verification is carried out before the user submits data to improve the user experience; 3) Refreshless communication with the server is achieved through AJAX technology.
Understanding the JavaScript Engine: Implementation DetailsApr 17, 2025 am 12:05 AMUnderstanding how JavaScript engine works internally is important to developers because it helps write more efficient code and understand performance bottlenecks and optimization strategies. 1) The engine's workflow includes three stages: parsing, compiling and execution; 2) During the execution process, the engine will perform dynamic optimization, such as inline cache and hidden classes; 3) Best practices include avoiding global variables, optimizing loops, using const and lets, and avoiding excessive use of closures.
Python vs. JavaScript: The Learning Curve and Ease of UseApr 16, 2025 am 12:12 AMPython is more suitable for beginners, with a smooth learning curve and concise syntax; JavaScript is suitable for front-end development, with a steep learning curve and flexible syntax. 1. Python syntax is intuitive and suitable for data science and back-end development. 2. JavaScript is flexible and widely used in front-end and server-side programming.
Python vs. JavaScript: Community, Libraries, and ResourcesApr 15, 2025 am 12:16 AMPython and JavaScript have their own advantages and disadvantages in terms of community, libraries and resources. 1) The Python community is friendly and suitable for beginners, but the front-end development resources are not as rich as JavaScript. 2) Python is powerful in data science and machine learning libraries, while JavaScript is better in front-end development libraries and frameworks. 3) Both have rich learning resources, but Python is suitable for starting with official documents, while JavaScript is better with MDNWebDocs. The choice should be based on project needs and personal interests.
Hot AI Tools
Undresser.AI Undress
AI-powered app for creating realistic nude photos
AI Clothes Remover
Online AI tool for removing clothes from photos.
Undress AI Tool
Undress images for free
Clothoff.io
AI clothes remover
Video Face Swap
Swap faces in any video effortlessly with our completely free AI face swap tool!
Hot Article
Hot Tools
MantisBT
Mantis is an easy-to-deploy web-based defect tracking tool designed to aid in product defect tracking. It requires PHP, MySQL and a web server. Check out our demo and hosting services.
Dreamweaver Mac version
Visual web development tools
SublimeText3 Mac version
God-level code editing software (SublimeText3)
PhpStorm Mac version
The latest (2018.2.1) professional PHP integrated development tool
WebStorm Mac version
Useful JavaScript development tools
