Maison > Article > interface Web > Maîtriser les tableaux JavaScript : techniques, bonnes pratiques et utilisations avancées
const name = ["Sakib", "Arif", "Fatema"];
Les tableaux sont une structure de données fondamentale en JavaScript (et dans de nombreux autres langages de programmation) pour plusieurs raisons :
Organiser les données : les tableaux vous permettent de stocker plusieurs valeurs dans une seule variable, ce qui facilite la gestion des collections de données. Par exemple, si vous devez conserver une liste de noms d'utilisateurs, vous pouvez tous les stocker dans un tableau.
Accès indexé : les tableaux offrent un moyen pratique d'accéder aux éléments à l'aide d'index. Cela facilite la récupération ou la modification d'éléments spécifiques en fonction de leur position.
Itérer efficacement : JavaScript propose diverses méthodes pour itérer sur des tableaux, telles que for, forEach, map, filter et réduire. Ces méthodes vous permettent de traiter chaque élément d'un tableau avec un minimum de code.
Redimensionnement dynamique : les tableaux en JavaScript sont dynamiques, ce qui signifie qu'ils peuvent augmenter ou diminuer en taille selon les besoins. Vous n'avez pas besoin de spécifier la taille à l'avance, ce qui ajoute de la flexibilité dans la façon dont vous gérez les données.
Méthodes intégrées : les tableaux JavaScript sont livrés avec un riche ensemble de méthodes intégrées pour manipuler et interroger les données. Des méthodes telles que push, pop, shift, unshift, splice, slice et bien d'autres simplifient les tâches courantes.
Gestion polyvalente des données : les tableaux peuvent contenir différents types de données, notamment des nombres, des chaînes, des objets et même d'autres tableaux. Cette polyvalence rend les baies adaptées à un large éventail d'applications.
Performances améliorées : les tableaux sont optimisés pour les performances dans les moteurs JavaScript, ce qui les rend efficaces pour les tâches qui impliquent un traitement et une manipulation séquentielles de données.
Prise en charge des fonctions d'ordre supérieur : les tableaux JavaScript sont conçus pour fonctionner de manière transparente avec des fonctions d'ordre supérieur, ce qui peut conduire à un code plus expressif et concis. Des fonctions telles que cartographier, filtrer et réduire permettent de puissantes transformations et agrégations de données.
En résumé, les tableaux sont essentiels pour organiser, accéder et manipuler des collections de données de manière efficace et flexible en JavaScript.
Syntaxe
const array_name = [item1, item2, ...];
Les espaces et les sauts de ligne ne sont pas importants. Une déclaration peut s'étendre sur plusieurs lignes :
const developer = [ "Fatema", "Sakib", "Riaz" ];
Vous pouvez également créer un tableau, puis fournir les éléments :
const man = []; cars[0]= "Abdur Rahman"; cars[1]= "Riyaz Khan"; cars[2]= "Jumman KL";
Utilisation du mot-clé JavaScript new
const man = new Array("Saabid", "Fatema", "Rukhsana");
Accès aux éléments du tableau
Vous accédez à un élément du tableau en vous référant au numéro d'index :
const man = ["Fatema", "Sakib", "Ayesha"]; let car = cars[0];
const fruits = ["Banana", "Orange", "Apple", "Mango"]; document.getElementById("demo").innerHTML = fruits.toString();
Convertir un tableau en chaîne en JavaScript est une opération courante, et il existe plusieurs méthodes pour y parvenir, chacune répondant à des besoins différents. Voici les méthodes les plus couramment utilisées :
La méthode join() combine tous les éléments d'un tableau en une seule chaîne, avec un séparateur spécifié entre les éléments.
const fruits = ['apple', 'banana', 'cherry']; const result = fruits.join(', '); // 'apple, banana, cherry' console.log(result);
La méthode toString() convertit un tableau en chaîne, en utilisant des virgules pour séparer les éléments.
const numbers = [1, 2, 3, 4]; const result = numbers.toString(); // '1,2,3,4' console.log(result);
Vous pouvez utiliser le constructeur String() pour convertir un tableau en chaîne. Cette approche est similaire à toString() mais peut être plus explicite dans certains contextes.
const boolArray = [true, false, true]; const result = String(boolArray); // 'true,false,true' console.log(result);
Pour un formatage personnalisé, vous pouvez utiliser des littéraux de modèle pour convertir un tableau en chaîne.
const colors = ['red', 'green', 'blue']; const result = `${colors[0]}, ${colors[1]}, ${colors[2]}`; // 'red, green, blue' console.log(result);
Pour plus de contrôle sur la conversion, surtout si vous devez formater chaque élément, vous pouvez utiliser map() en combinaison avec join().
const numbers = [1, 2, 3]; const result = numbers.map(num => `Number ${num}`).join(' | '); // 'Number 1 | Number 2 | Number 3' console.log(result);
let a = [1, 12, 13, 14, 6, 8,9, 5, 11, 7, 10, 15, 2, 3, 4, 22, 44, 33]; console.log(a);
let a = [1, 12, 13, 14, 6, 8,9, 5, 11, 7, 10, 15, 2, 3, 4, 22, 44, 33]; document.getElementById("demo").innerHTML = a;
Accessing the full contents of an array in JavaScript can be done in various ways depending on the context and the goal. Here are several methods to access and work with all elements of an array:
You can access individual elements of an array directly using their indices. For example, to access the first element, you use index 0.
const fruits = ['apple', 'banana', 'cherry']; console.log(fruits[0]); // 'apple' console.log(fruits[1]); // 'banana' console.log(fruits[2]); // 'cherry'
You can use loops to iterate through each element of the array. Here are a few common looping methods:
The traditional for loop gives you control over the index and can be useful for tasks like modifying elements based on their position.
const numbers = [10, 20, 30]; for (let i = 0; i < numbers.length; i++) { console.log(numbers[i]); // 10, 20, 30 }
The forEach() method executes a provided function once for each array element.
const colors = ['red', 'green', 'blue']; colors.forEach(color => { console.log(color); // 'red', 'green', 'blue' });
The for...of loop provides a more modern and readable way to iterate through array elements.
const fruits = ['apple', 'banana', 'cherry']; for (const fruit of fruits) { console.log(fruit); // 'apple', 'banana', 'cherry' }
The map() method creates a new array with the results of calling a provided function on every element.
const numbers = [1, 2, 3]; const doubled = numbers.map(num => num * 2); console.log(doubled); // [2, 4, 6]
Array destructuring allows you to unpack elements from arrays into distinct variables.
const [first, second, third] = ['apple', 'banana', 'cherry']; console.log(first); // 'apple' console.log(second); // 'banana' console.log(third); // 'cherry'
To quickly view the entire array, you can use console.log().
const array = [1, 2, 3, 4, 5]; console.log(array); // [1, 2, 3, 4, 5]
Convert the entire array to a comma-separated string.
const array = [1, 2, 3, 4]; console.log(array.toString()); // '1,2,3,4'
Similar to toString(), but you can specify a separator.
const array = [1, 2, 3, 4]; console.log(array.join(' - ')); // '1 - 2 - 3 - 4'
Use the spread operator to create a new array or pass the array elements to a function.
const numbers = [1, 2, 3]; const newNumbers = [...numbers]; console.log(newNumbers); // [1, 2, 3]
const man = ["Fatema", "CSE", "UU", 24]; console.log(man);
In JavaScript, arrays are indeed a type of object. This concept is fundamental to understanding how arrays work in JavaScript. Here’s a deeper look into why arrays are considered objects and how that impacts their behavior:
Inheritance from Object: Arrays in JavaScript inherit from the Object prototype, which means they have all the properties and methods of objects. This includes methods like hasOwnProperty(), toString(), and others.
Prototype Chain: Arrays have their own prototype chain that extends from Array.prototype, which is itself an object. This prototype chain provides arrays with their specific methods, like push(), pop(), map(), and more.
const arr = [1, 2, 3]; console.log(arr.constructor === Array); // true console.log(arr instanceof Object); // true console.log(arr instanceof Array); // true
const fruits = ['apple', 'banana']; console.log(fruits.length); // 2 fruits.push('cherry'); console.log(fruits.length); // 3
const arr = ['a', 'b', 'c']; console.log(arr[0]); // 'a'
Enumerability: Arrays have numeric indices and are often used in scenarios where the order of elements is important. Objects use string keys and are typically used for key-value pairs where the order is less significant.
Prototype Methods: Arrays come with a set of methods specific to array manipulation, such as concat(), slice(), and reduce(). Objects have methods and properties from Object.prototype, such as hasOwnProperty().
const obj = { a: 1, b: 2 }; console.log(Object.keys(obj)); // ['a', 'b'] const arr = [1, 2, 3]; console.log(arr.map(x => x * 2)); // [2, 4, 6]
const arr = [1, 2, 3]; arr.customProperty = 'value'; console.log(arr.customProperty); // 'value'
const numbers = [1, 2, 3]; numbers.forEach(num => console.log(num)); // 1 2 3
Use Cases: Arrays are best used when you need to store ordered collections of data and perform operations that involve sequence and index-based access. Objects are more suited for storing data with named properties where the order is not a priority.
Performance: Arrays can be optimized for sequential access and manipulation due to their special handling in JavaScript engines. Objects are optimized for key-based access.
The length property in JavaScript is a special property found on arrays and strings, and it plays a crucial role in managing collections of data. Here's a comprehensive overview of how the length property works:
The length property of an array returns the number of elements in the array. It is a dynamic property that automatically updates when elements are added or removed from the array.
const fruits = ['apple', 'banana', 'cherry']; console.log(fruits.length); // 3
const numbers = [1, 2, 3]; numbers.push(4); console.log(numbers.length); // 4
const numbers = [1, 2, 3]; numbers.pop(); console.log(numbers.length); // 2
const numbers = [1, 2, 3, 4, 5]; numbers.length = 3; console.log(numbers); // [1, 2, 3] numbers.length = 5; console.log(numbers); // [1, 2, 3, <2 empty items>]
The length property of a string returns the number of characters in the string.
const message = 'Hello, World!'; console.log(message.length); // 13
const arr = [1, , 3]; console.log(arr.length); // 3
Here, arr has a length of 3, but only two indices (0 and 2) have values. The index 1 is "empty" but still counts towards the length.
const arr = ['a', 'b', 'c']; for (let i = 0; i < arr.length; i++) { console.log(arr[i]); // 'a', 'b', 'c' }
function validatePassword(password) { return password.length >= 8; }
const arr = [1, 2, 3]; arr.length = 5; // Adds two empty slots
Adding elements to an array in JavaScript can be done using several methods, depending on where you want to add the elements and how you want to manipulate the array. Here’s a detailed look at the various techniques for adding elements to arrays:
The push() method adds one or more elements to the end of an array and returns the new length of the array.
const fruits = ['apple', 'banana']; fruits.push('cherry'); // Adds 'cherry' to the end console.log(fruits); // ['apple', 'banana', 'cherry']
The unshift() method adds one or more elements to the beginning of an array and returns the new length of the array.
const fruits = ['banana', 'cherry']; fruits.unshift('apple'); // Adds 'apple' to the beginning console.log(fruits); // ['apple', 'banana', 'cherry']
The splice() method can add elements at any position in the array. It can also be used to remove elements.
const fruits = ['apple', 'cherry']; fruits.splice(1, 0, 'banana'); // At index 1, remove 0 elements, add 'banana' console.log(fruits); // ['apple', 'banana', 'cherry']
The spread operator (...) allows you to add elements from one array into another array. This is particularly useful for combining arrays.
const fruits = ['apple', 'banana']; const moreFruits = ['cherry', 'date']; const allFruits = [...fruits, ...moreFruits]; console.log(allFruits); // ['apple', 'banana', 'cherry', 'date']
The concat() method creates a new array by combining multiple arrays or values.
const fruits = ['apple', 'banana']; const moreFruits = ['cherry', 'date']; const allFruits = fruits.concat(moreFruits); console.log(allFruits); // ['apple', 'banana', 'cherry', 'date']
You can use array destructuring with the spread operator to add elements to specific positions in an array.
const fruits = ['apple', 'date']; const newFruits = ['banana', ...fruits, 'cherry']; console.log(newFruits); // ['banana', 'apple', 'date', 'cherry']
You can use splice() to insert multiple elements at a specific index.
const numbers = [1, 2, 5]; numbers.splice(2, 0, 3, 4); // Insert 3 and 4 at index 2 console.log(numbers); // [1, 2, 3, 4, 5]
When using length to add elements, be aware that it will add empty slots.
const arr = [1, 2, 3]; arr.length = 5; // Adds two empty slots console.log(arr); // [1, 2, 3, <2 empty items>]
Nested arrays and objects in JavaScript are powerful features that allow you to create complex data structures. These can be used to represent multi-dimensional data, hierarchies, or any scenario where data is organized in layers.
A nested array is an array that contains other arrays as its elements. This can be useful for representing matrices, grids, or hierarchical data.
const matrix = [ [1, 2, 3], [4, 5, 6], [7, 8, 9] ]; // Accessing elements console.log(matrix[0][0]); // 1 console.log(matrix[1][2]); // 6 // Iterating through a nested array for (const row of matrix) { for (const value of row) { console.log(value); } }
A nested object is an object that contains other objects as its properties. This is useful for representing hierarchical data or entities with multiple attributes.
const person = { name: 'John Doe', age: 30, address: { street: '123 Main St', city: 'Anytown', zipCode: '12345' }, hobbies: ['reading', 'gaming'] }; // Accessing nested properties console.log(person.address.street); // '123 Main St' console.log(person.hobbies[1]); // 'gaming' // Iterating through a nested object for (const key in person) { if (typeof person[key] === 'object' && !Array.isArray(person[key])) { console.log(`Nested object ${key}:`); for (const subKey in person[key]) { console.log(` ${subKey}: ${person[key][subKey]}`); } } else { console.log(`${key}: ${person[key]}`); } }
You can combine arrays and objects to create more complex structures. For example, you might have an array of objects, where each object contains nested arrays or other objects.
const classRoom = [ { name: 'Math', students: [ { name: 'Alice', score: 95 }, { name: 'Bob', score: 88 } ] }, { name: 'Science', students: [ { name: 'Charlie', score: 92 }, { name: 'David', score: 85 } ] } ]; // Accessing data console.log(classRoom[0].students[1].name); // 'Bob' console.log(classRoom[1].students[0].score); // 92 // Iterating through the combined structure for (const subject of classRoom) { console.log(`Subject: ${subject.name}`); for (const student of subject.students) { console.log(` Student: ${student.name}, Score: ${student.score}`); } }
Accessing: Use dot notation or bracket notation for objects, and indices for arrays.
Updating: Assign new values to nested properties or elements.
person.address.city = 'New City'; // Update a nested property classRoom[0].students[0].score = 97; // Update a nested element
person.phone = '555-5555'; // Add a new property classRoom.push({ name: 'History', students: [] }); // Add a new subject
delete person.phone; // Remove a nested property classRoom[1].students.splice(1, 1); // Remove a student
Data Representation: Represent complex data structures such as configuration settings, hierarchical data (e.g., organizational charts), and multi-dimensional datasets.
APIs and Databases: Often used in API responses and database queries to represent complex records.
Form Data: Useful for handling nested form data, such as forms with sections or groups of fields.
JavaScript arrays come with a rich set of built-in methods that help you manipulate and interact with array data. These methods can be broadly categorized into several types, including those for modifying arrays, accessing elements, and iterating over elements. Here’s a comprehensive overview of common array methods:
const fruits = ['apple', 'banana']; fruits.push('cherry'); // ['apple', 'banana', 'cherry']
const fruits = ['apple', 'banana', 'cherry']; const lastFruit = fruits.pop(); // 'cherry'
const fruits = ['banana', 'cherry']; fruits.unshift('apple'); // ['apple', 'banana', 'cherry']
const fruits = ['apple', 'banana', 'cherry']; const firstFruit = fruits.shift(); // 'apple'
const fruits = ['apple', 'banana', 'cherry']; fruits.splice(1, 1, 'blueberry'); // ['apple', 'blueberry', 'cherry']
const fruits = ['apple', 'banana', 'cherry']; const index = fruits.indexOf('banana'); // 1
const fruits = ['apple', 'banana', 'cherry']; const hasBanana = fruits.includes('banana'); // true
const numbers = [1, 2, 3, 4]; const firstEven = numbers.find(num => num % 2 === 0); // 2
const numbers = [1, 2, 3, 4]; const index = numbers.findIndex(num => num % 2 === 0); // 1
const fruits = ['apple', 'banana', 'cherry']; fruits.forEach(fruit => console.log(fruit));
const numbers = [1, 2, 3]; const doubled = numbers.map(num => num * 2); // [2, 4, 6]
const numbers = [1, 2, 3, 4]; const evens = numbers.filter(num => num % 2 === 0); // [2, 4]
const numbers = [1, 2, 3, 4]; const sum = numbers.reduce((acc, num) => acc + num, 0); // 10
const numbers = [1, 2, 3, 4]; const product = numbers.reduceRight((acc, num) => acc * num, 1); // 24
const numbers = [1, 2, 3, 4]; const hasEven = numbers.some(num => num % 2 === 0); // true
const numbers = [2, 4, 6]; const allEven = numbers.every(num => num % 2 === 0); // true
const numbers = [4, 2, 3, 1]; numbers.sort(); // [1, 2, 3, 4]
const numbers = [4, 2, 3, 1]; numbers.sort((a, b) => a - b); // [1, 2, 3, 4]
const numbers = [1, 2, 3]; numbers.reverse(); // [3, 2, 1]
const arr1 = [1, 2]; const arr2 = [3, 4]; const combined = arr1.concat(arr2); // [1, 2, 3, 4]
const numbers = [1, 2, 3, 4]; const sliced = numbers.slice(1, 3); // [2, 3]
const numbers = [1, 2, 3, 4]; numbers.splice(2, 1, 'a', 'b'); // [1, 2, 'a', 'b', 4]
const numbers = [1, 2, 3]; const str = numbers.toString(); // '1,2,3'
const numbers = [1, 2, 3]; const str = numbers.join('-'); // '1-2-3'
JavaScript arrays come with various methods for searching and locating elements. These methods can be used to find specific values, check for the presence of elements, or retrieve indexes. Here's a detailed overview of the key array search methods:
The indexOf() method returns the first index at which a given element can be found, or -1 if the element is not found.
const fruits = ['apple', 'banana', 'cherry']; const index = fruits.indexOf('banana'); // 1 const notFound = fruits.indexOf('orange'); // -1
Syntax: array.indexOf(searchElement, fromIndex)
The includes() method determines whether an array contains a certain element and returns true or false.
const fruits = ['apple', 'banana', 'cherry']; const hasBanana = fruits.includes('banana'); // true const hasOrange = fruits.includes('orange'); // false
Syntax: array.includes(searchElement, fromIndex)
The find() method returns the first element in the array that satisfies a provided testing function. If no elements satisfy the testing function, it returns undefined.
const numbers = [4, 9, 16, 25]; const firstEven = numbers.find(num => num % 2 === 0); // 4 const noMatch = numbers.find(num => num > 30); // undefined
Syntax: array.find(callback(element, index, array), thisArg)
The findIndex() method returns the index of the first element in the array that satisfies a provided testing function. If no elements satisfy the testing function, it returns -1.
const numbers = [4, 9, 16, 25]; const index = numbers.findIndex(num => num % 2 === 0); // 0 const noMatchIndex = numbers.findIndex(num => num > 30); // -1
Syntax: array.findIndex(callback(element, index, array), thisArg)
The some() method tests whether at least one element in the array passes the provided testing function. It returns true if any elements pass the test, otherwise false.
const numbers = [1, 2, 3, 4]; const hasEven = numbers.some(num => num % 2 === 0); // true const allEven = numbers.some(num => num % 2 === 0 && num > 5); // false
Syntax: array.some(callback(element, index, array), thisArg)
The every() method tests whether all elements in the array pass the provided testing function. It returns true if all elements pass the test, otherwise false.
const numbers = [2, 4, 6]; const allEven = numbers.every(num => num % 2 === 0); // true const notAllEven = numbers.every(num => num > 3); // false
Syntax: array.every(callback(element, index, array), thisArg)
The filter() method creates a new array with all elements that pass the test implemented by the provided function.
const numbers = [1, 2, 3, 4, 5]; const evens = numbers.filter(num => num % 2 === 0); // [2, 4]
Syntax: array.filter(callback(element, index, array), thisArg)
The findLast() method returns the last element in the array that satisfies a provided testing function. If no elements satisfy the testing function, it returns undefined. Note that this method is experimental and may not be supported in all environments.
const numbers = [4, 9, 16, 25]; const lastEven = numbers.findLast(num => num % 2 === 0); // 16
Syntax: array.findLast(callback(element, index, array), thisArg)
The findLastIndex() method returns the index of the last element in the array that satisfies a provided testing function. If no elements satisfy the testing function, it returns -1. Note that this method is experimental and may not be supported in all environments.
const numbers = [4, 9, 16, 25]; const lastEvenIndex = numbers.findLastIndex(num => num % 2 === 0); // 2
Syntax: array.findLastIndex(callback(element, index, array), thisArg)
Sorting arrays in JavaScript can be done using the sort() method. This method allows you to arrange elements in an array according to a specified order. By default, the sort() method sorts the elements as strings, but you can provide a custom comparison function to sort elements in different ways.
The sort() method sorts the elements of an array in place and returns the sorted array.
const fruits = ['banana', 'apple', 'cherry']; fruits.sort(); console.log(fruits); // ['apple', 'banana', 'cherry']
To sort elements in a specific order, you need to pass a comparison function to sort(). The comparison function takes two arguments (let's call them a and b) and returns:
By default, the sort() method converts numbers to strings and sorts them lexicographically. To sort numbers correctly, provide a comparison function that performs numerical comparisons.
const numbers = [10, 5, 100, 1]; numbers.sort((a, b) => a - b); // Ascending order console.log(numbers); // [1, 5, 10, 100] numbers.sort((a, b) => b - a); // Descending order console.log(numbers); // [100, 10, 5, 1]
Strings are sorted lexicographically (dictionary order) by default. For case-insensitive sorting, you can convert strings to the same case (e.g., lowercase) in the comparison function.
const words = ['banana', 'Apple', 'cherry']; words.sort((a, b) => a.localeCompare(b)); // Case-sensitive console.log(words); // ['Apple', 'banana', 'cherry'] words.sort((a, b) => a.toLowerCase().localeCompare(b.toLowerCase())); // Case-insensitive console.log(words); // ['Apple', 'banana', 'cherry']
To sort an array of objects, use a comparison function that compares the desired properties of the objects.
const people = [ { name: 'John', age: 30 }, { name: 'Jane', age: 25 }, { name: 'Mike', age: 35 } ]; // Sort by age people.sort((a, b) => a.age - b.age); console.log(people); // [ { name: 'Jane', age: 25 }, { name: 'John', age: 30 }, { name: 'Mike', age: 35 } ] // Sort by name people.sort((a, b) => a.name.localeCompare(b.name)); console.log(people); // [ { name: 'Jane', age: 25 }, { name: 'John', age: 30 }, { name: 'Mike', age: 35 } ]
When sorting multi-dimensional arrays (arrays of arrays), provide a comparison function that compares the relevant elements.
const matrix = [ [1, 4], [3, 2], [5, 0] ]; // Sort by the first element of each sub-array matrix.sort((a, b) => a[0] - b[0]); console.log(matrix); // [ [1, 4], [3, 2], [5, 0] ] // Sort by the second element of each sub-array matrix.sort((a, b) => a[1] - b[1]); console.log(matrix); // [ [5, 0], [3, 2], [1, 4] ]
JavaScript's sort() method is stable in modern environments, meaning that elements with equal values retain their relative order. However, this is not guaranteed in all JavaScript engines, so if stability is crucial, consider using a custom stable sorting algorithm or library.
The localeCompare() method can be useful for sorting strings in a locale-aware manner, accounting for different cultural sorting rules.
const words = ['résumé', 'resume', 'apple']; words.sort((a, b) => a.localeCompare(b, 'en', { sensitivity: 'base' })); console.log(words); // ['apple', 'resume', 'résumé']
JavaScript provides several methods for iterating over arrays, allowing you to execute a function on each element or transform the array in various ways. Here’s a comprehensive overview of the array iteration methods available in JavaScript:
The forEach() method executes a provided function once for each array element. It does not return a value and cannot be stopped or broken out of early.
const fruits = ['apple', 'banana', 'cherry']; fruits.forEach(fruit => console.log(fruit)); // Output: // apple // banana // cherry
Syntax: array.forEach(callback(element, index, array), thisArg)
The map() method creates a new array with the results of calling a provided function on every element in the original array. It’s used for transforming elements.
const numbers = [1, 2, 3, 4]; const doubled = numbers.map(num => num * 2); console.log(doubled); // [2, 4, 6, 8]
Syntax: array.map(callback(element, index, array), thisArg)
The filter() method creates a new array with all elements that pass the test implemented by the provided function. It is used for selecting elements that meet certain criteria.
const numbers = [1, 2, 3, 4, 5]; const evens = numbers.filter(num => num % 2 === 0); console.log(evens); // [2, 4]
Syntax: array.filter(callback(element, index, array), thisArg)
The reduce() method applies a function against an accumulator and each element in the array to reduce it to a single value, such as a sum or a concatenated string.
const numbers = [1, 2, 3, 4]; const sum = numbers.reduce((acc, num) => acc + num, 0); console.log(sum); // 10
Syntax: array.reduce(callback(accumulator, currentValue, index, array), initialValue)
The reduceRight() method is similar to reduce(), but it processes the array from right to left.
const numbers = [1, 2, 3, 4]; const product = numbers.reduceRight((acc, num) => acc * num, 1); console.log(product); // 24
Syntax: array.reduceRight(callback(accumulator, currentValue, index, array), initialValue)
The some() method tests whether at least one element in the array passes the test implemented by the provided function. It returns true if at least one element passes the test, otherwise false.
const numbers = [1, 2, 3, 4]; const hasEven = numbers.some(num => num % 2 === 0); console.log(hasEven); // true
Syntax: array.some(callback(element, index, array), thisArg)
The every() method tests whether all elements in the array pass the test implemented by the provided function. It returns true if all elements pass the test, otherwise false.
const numbers = [2, 4, 6]; const allEven = numbers.every(num => num % 2 === 0); console.log(allEven); // true
Syntax: array.every(callback(element, index, array), thisArg)
The find() method returns the first element in the array that satisfies the provided testing function. If no elements satisfy the testing function, it returns undefined.
const numbers = [4, 9, 16, 25]; const firstEven = numbers.find(num => num % 2 === 0); console.log(firstEven); // 4
Syntax: array.find(callback(element, index, array), thisArg)
The findIndex() method returns the index of the first element in the array that satisfies the provided testing function. If no elements satisfy the testing function, it returns -1.
const numbers = [4, 9, 16, 25]; const index = numbers.findIndex(num => num % 2 === 0); console.log(index); // 0
Syntax: array.findIndex(callback(element, index, array), thisArg)
The for...of loop provides a clean syntax for iterating over iterable objects like arrays. It is especially useful for looping through array values.
const fruits = ['apple', 'banana', 'cherry']; for (const fruit of fruits) { console.log(fruit); } // Output: // apple // banana // cherry
The for...in loop iterates over the enumerable properties of an object. When used with arrays, it iterates over array indices, not values. It is generally not recommended for arrays, as it is intended for objects.
const fruits = ['apple', 'banana', 'cherry']; for (const index in fruits) { console.log(index); // 0, 1, 2 }
The flatMap() method first maps each element using a mapping function, then flattens the result into a new array. This is useful for when you need to map and then flatten the results in one go.
const numbers = [1, 2, 3]; const flattened = numbers.flatMap(num => [num, num * 2]); console.log(flattened); // [1, 2, 2, 4, 3, 6]
Syntax: array.flatMap(callback(element, index, array), thisArg)
In JavaScript, const is a keyword used to declare variables that are intended to remain constant—i.e., their references cannot be reassigned. However, this does not mean the value or object they point to is immutable. For arrays declared with const, the array itself cannot be reassigned, but its elements can still be modified.
Here's a more detailed look at using const with arrays:
When you declare an array with const, you are creating a constant reference to that array. This means you cannot reassign the array to a different value or array, but you can still modify its elements or its structure (such as adding or removing elements).
const fruits = ['apple', 'banana', 'cherry']; // Valid: modifying elements fruits[0] = 'blueberry'; // ['blueberry', 'banana', 'cherry'] fruits.push('date'); // ['blueberry', 'banana', 'cherry', 'date'] console.log(fruits); // Invalid: reassigning the array fruits = ['kiwi', 'mango']; // TypeError: Assignment to constant variable.
Even though you cannot reassign the const array, you can use array methods to modify its contents:
const numbers = [1, 2, 3]; numbers.push(4); // [1, 2, 3, 4] numbers.unshift(0); // [0, 1, 2, 3, 4]
const colors = ['red', 'green', 'blue']; colors.pop(); // ['red', 'green'] colors.shift(); // ['green']
const animals = ['cat', 'dog', 'bird']; animals[1] = 'fish'; // ['cat', 'fish', 'bird']
Methods that modify the array in place are allowed:
const numbers = [3, 1, 4, 1, 5]; numbers.sort(); // [1, 1, 3, 4, 5]
const letters = ['a', 'b', 'c']; letters.reverse(); // ['c', 'b', 'a']
const fruits = ['apple', 'banana', 'cherry']; fruits.splice(1, 1, 'blueberry', 'date'); // ['apple', 'blueberry', 'date', 'cherry']
If you need an immutable array, where changes to the array are not allowed, you need to use additional techniques or libraries to achieve this. JavaScript itself does not provide immutable arrays directly.
For example, you could use libraries like Immutable.js for immutability:
import { List } from 'immutable'; const immutableList = List([1, 2, 3]); const newList = immutableList.push(4); // Returns a new List: List [ 1, 2, 3, 4 ] console.log(immutableList); // List [ 1, 2, 3 ]
JavaScript provides a wide range of operations and methods to handle arrays, including creation, manipulation, searching, and iteration. Here's a summary of the most common array operations:
Wenn Sie diese Vorgänge verstehen und effektiv nutzen, können Sie Arrays in JavaScript effizienter und flexibler verwalten und bearbeiten.
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