You will discover the solutions to the following questions and how to transfer/share data from the child component to the parent component in this walkthrough.

• @Output: What is it?
• An Event Emitter: What Is It?

  

What is @Output?
@Output decorator is used to share the data from the child component to the parent component.

What is an event emitter?
An event emitter is used to create custom events for AngularComponent. Mainly, the event emitter is used to pass data from a child component to a parent component using the @output decorator.

In short, sending data to the parent is publishing /emitting the vent, and the parent component listens the same.

Send Data from Child to Parent Component
Create an Angular Project called “AnguWalk” using the following CLI command.

Command
ng new AnguWalk

Example

Move the cursor to inside the project folder and open Visual Studio code.

Command
cd anguwalk <enter>
code . <enter>

Example

Note. Visual studio code will get started only if your system is configured with path and settings.
Now, we are going to Create a child component to issue the default city value.

Command
ng g c childdefacity

Open the childdefacity.component.ts file and update the following code.
import { Component, EventEmitter, OnInit, Output } from '@angular/core';

@Component({
  selector: 'app-childdefacity',
  standalone: true,
  imports: [],
  templateUrl: './childdefacity.component.html',
  styleUrls: ['./childdefacity.component.css']
})
export class ChilddefacityComponent implements OnInit {
  defaultcity: string = "Shirdi";
  @Output() updatecity = new EventEmitter<string>();
  ngOnInit(): void {}
  SendToParent() {
    this.updatecity.emit(this.defaultcity);
  }
}

Open the childdefacity.component.html file and update the following code.
<p>Child Component Content --> childdefacity works!</p>
<button type="button" style="font-size: xx-large;" (click)="SendToParent()">Send Default City</button>

Open the app.component.ts file and update the following code.
import { Component, NgModule, OnInit } from '@angular/core';
import { FormsModule } from '@angular/forms';
import { CommonModule } from '@angular/common';
import { RouterOutlet } from '@angular/router';
import { ChilddefacityComponent } from './childdefacity/childdefacity.component';
declare function HelloMsg(arg: any): void;
@Component({
  selector: 'app-root',
  standalone: true,
  imports: [RouterOutlet, FormsModule, CommonModule, ChilddefacityComponent],
  templateUrl: './app.component.html',
  styleUrls: ['./app.component.css']
})
export class AppComponent {
  parentdefacity: string = '';
  txtFullname: string = '';
  txtCityname: string = '';

  getdata(defacity: string) {
    this.txtCityname = defacity;
    // alert(this.txtCityname);
  }
  formpro(form: any) {
    alert('submit');
    console.log(form);
    console.log(this.txtCityname);
    console.log(this.txtFullname);
  }
}

Open the app.component.ts file and update the following code.
import { Component, NgModule, OnInit } from '@angular/core';
import { FormsModule } from '@angular/forms';
import { CommonModule } from '@angular/common';
import { RouterOutlet } from '@angular/router';
import { ChilddefacityComponent } from './childdefacity/childdefacity.component';
declare function HelloMsg(arg: any): void;
@Component({
  selector: 'app-root',
  standalone: true,
  imports: [RouterOutlet, FormsModule, CommonModule, ChilddefacityComponent],
  templateUrl: './app.component.html',
  styleUrl: './app.component.css'
})
export class AppComponent {
  parentdefacity: string = "";
  txtFullname: string = "";
  txtCityname: string = "";

  getdata(defacity: string) {
    this.txtCityname = defacity;
    // alert(this.txtCityname);
  }
  formpro(form: any) {
    alert("submit");
    console.log(form);
    console.log(this.txtCityname);
    console.log(this.txtFullname);
  }
}

Open the app.component.html file and update the following code.
<router-outlet />

<form #contForm="ngForm" (ngSubmit)="formpro(contForm.value)">
  <table>
    <tr>
      <td>Fullname</td>
      <td>
        <input
          type="text"
          id="txtFullname"
          style="font-size: xx-large;"
          name="txtFullname"
          [(ngModel)]="txtFullname">
      </td>
    </tr>

    <tr>
      <td>City</td>
      <td>
        <input
          type="text"
          id="txtCity"
          style="font-size: xx-large;"
          name="txtCity"
          [(ngModel)]="txtCityname">
      </td>
    </tr>

    <tr>
      <td colspan="2">
        <app-childdefacity (updatecity)="getdata($event)"></app-childdefacity>
      </td>
    </tr>

    <tr>
      <td colspan="2">
        <button type="submit" style="font-size: xx-large;">Submit</button>
      </td>
    </tr>
  </table>
</form>

OUTPUT

React and Angular are two of the most widely used front-end frameworks for creating contemporary online apps. Both are supported by sizable groups and have distinct advantages, yet they serve varying needs and tastes. We'll go over the main distinctions between Angular and React in this post to assist you in choosing the right framework for your project.

Overview

1. React
   • Developed by: Facebook
   • Initial Release: 2013
   • Type: JavaScript library for building user interfaces, primarily focused on rendering UI components.
   • Learning Curve: Moderate
   • Main Concept: React is centered around components and follows a unidirectional data flow.
2. Angular
   • Developed by: Google
   • Initial Release: 2016 (as Angular 2, the complete rewrite of AngularJS)
   • Type: Full-fledged framework for building web applications.
   • Learning Curve: Steep
   • Main Concept: Angular is an opinionated framework that provides a comprehensive solution for building large-scale applications, including built-in features like routing, state management, and HTTP services.

Architecture

1. React
   • Component-Based: React is all about components. Each piece of UI is a component that can manage its state and be reused throughout the application.
   • Virtual DOM: React uses a virtual DOM to optimize rendering performance. When the state of a component changes, React updates the virtual DOM and then efficiently updates the real DOM.
   • Flexibility: React offers flexibility by allowing developers to choose their own libraries for routing, state management, and other needs. This makes React a "view library" rather than a full-fledged framework.
2. Angular
   • MVC Architecture: Angular follows the Model-View-Controller (MVC) pattern, which helps in separating the concerns of data (Model), UI (View), and logic (Controller).
   • Real DOM: Unlike React, Angular directly interacts with the real DOM, which can impact performance in complex applications. However, Angular mitigates this with its change detection mechanism.
   • Built-In Features: Angular comes with a range of built-in features like form validation, HTTP client, routing, and RxJS for reactive programming. This makes Angular a complete solution for building applications without relying on external libraries.

Performance

1. React
   • Virtual DOM: React’s virtual DOM significantly improves performance by minimizing the number of direct manipulations to the real DOM.
   • Component Reusability: React’s component-based architecture promotes reusability, which can lead to better performance in large applications.
   • Bundle Size: React itself is relatively lightweight, but depending on the additional libraries you use, the bundle size can grow.
2. Angular
   • Change Detection: Angular’s change detection mechanism can sometimes lead to performance bottlenecks in large applications, but it also provides tools like OnPush strategy and NgZone to optimize performance.
   • Ahead-of-Time (AOT) Compilation: Angular’s AOT compilation improves performance by compiling the application during the build process, reducing the load time.
   • Built-In Features: While Angular’s rich feature set can impact performance, the framework’s ability to optimize these features mitigates the impact.

Learning Curve

1. React
   • JSX: React uses JSX, a syntax extension that allows you to write HTML within JavaScript. While some developers find JSX intuitive, others might find it challenging initially.
   • Flexibility: React’s flexibility means you need to learn how to integrate and use various libraries for routing, state management, etc., which can be both an advantage and a challenge.
   • Documentation and Community: React has extensive documentation and a large community, making it easier to find resources, tutorials, and third-party libraries.
2. Angular
   • Steep Learning Curve: Angular has a steeper learning curve due to its complexity and the number of built-in features you need to understand.
   • TypeScript: Angular is built with TypeScript, a statically typed superset of JavaScript. While this adds benefits like better tooling and error checking, it also requires learning TypeScript if you’re not already familiar with it.
   • Comprehensive Framework: Angular’s opinionated nature means that once you learn the Angular way of doing things, you have a powerful set of tools at your disposal.

Ecosystem and Community

1. React
   • Ecosystem: React has a rich ecosystem with numerous libraries for state management (Redux, MobX), routing (React Router), and more. The flexibility to choose different tools gives developers more control over their stack.
   • Community: React has a large and active community, contributing to a vast array of plugins, tools, and resources.
2. Angular
   • Ecosystem: Angular has a more integrated ecosystem. Many features that require third-party libraries in React are built into Angular, such as routing, HTTP services, and form handling.
   • Community: Angular also has a large community, but it is more centralized around the official Angular resources, documentation, and Google-backed initiatives.

Use Case
React

1. When to Use React
   • You need flexibility in choosing libraries and tools.
   • You prefer a simple, component-based architecture.
   • You are building a project where performance and simplicity are key.
2. Popular Use Cases
   • Single-page applications (SPAs)
   • Static sites with dynamic components
   • Dashboards and data visualization tools

Angular

1. When to Use Angular
   • You are building a large-scale, enterprise-level application.
   • You need a framework with a comprehensive set of tools and built-in features.
   • You prefer an opinionated framework that guides architectural decisions.
2. Popular Use Cases
   • Complex, enterprise-level applications
   • Applications requiring robust form handling and validation
   • Real-time applications with complex state management

Conclusion
The skills of your team and the needs of your project will determine which of React and Angular is best. React is an excellent option for projects where you want more control over the architecture because of its simplicity and versatility. In contrast, Angular offers a feature-rich, opinionated framework right out of the box, making it perfect for enterprise-level apps.

Both Angular and React are effective front-end development tools, and knowing the advantages and disadvantages of each will help you choose wisely for your upcoming project.

In Angular, component routing is usually done via the Router service. This allows you to call or go to a component from another component. Here's how you can make this happen. In the Router Module, define routes. The first step is to configure your routes in your AppRoutingModule (or any other defined routing module). Describe the pathways and the matching parts.

import { NgModule } from '@angular/core';
import { RouterModule, Routes } from '@angular/router';
import { ComponentA } from './component-a/component-a.component';
import { ComponentB } from './component-b/component-b.component';

const routes: Routes = [
  { path: 'component-a', component: ComponentA },
  { path: 'component-b', component: ComponentB },
  // Add more routes as needed
];

@NgModule({
  imports: [RouterModule.forRoot(routes)],
  exports: [RouterModule]
})
export class AppRoutingModule { }

Use RouterLink in Templates
You can navigate to another component using the RouterLink directive in your template (HTML) of the first component.
<!-- component-a.component.html -->
<a [routerLink]="['/component-b']">Go to Component B</a>

Navigate Programmatically Using the Router
You can also navigate programmatically using the Angular Router in your component's TypeScript file.
import { Component } from '@angular/core';
import { Router } from '@angular/router';

@Component({
  selector: 'app-component-a',
  templateUrl: './component-a.component.html',
  styleUrls: ['./component-a.component.css']
})
export class ComponentA {

  constructor(private router: Router) { }

  goToComponentB() {
    this.router.navigate(['/component-b']);
  }
}

In HTML template
<!-- component-a.component.html -->
<button (click)="goToComponentB()">Go to Component B</button>

Outlet to Render Routed Components
Ensure you have a <router-outlet></router-outlet> in your main HTML template (e.g., app.component.html) where the routed components will be displayed.
<!-- app.component.html -->
<router-outlet></router-outlet>

Lazy Loading (Optional)
If you want to load a module lazily, define your route like this.
const routes: Routes = [
  {
    path: 'component-b',
    loadChildren: () =>
      import('./component-b/component-b.module')
        .then(m => m.ComponentBModule)
  }
];

Summary

• RouterLink: For navigation within the template.
• Router.navigate: For programmatic navigation within the component's TypeScript file.
• Router Outlet: Acts as a placeholder in the template where routed components are displayed.

This setup allows you to call or navigate between components effectively in Angular.

Increasing the speed and smoothness of an application requires performance tuning. To aid in this, Angular, a well-liked framework for creating online applications, has introduced the @defer directive. Both load times and user experience are enhanced. We'll explain the @defer directive, its operation, and how you can use it to improve your Angular apps in this blog post.

@defer: What is it?

Using an Angular condition, the @defer directive allows you to load specific portions of a template only when needed. This can improve the efficiency of your program by only rendering components when required. For instance, it can load and display material only after the user presses a button or until a certain portion of the screen is visible. In this manner, your software loads faster and more effectively because it just loads what is needed.

Syntax
@defer () {
} @placeholder () {
} @loading () {
} @error {
}

@defer Directive
This is used to delay the loading of a template fragment until certain conditions are met.
on <trigger>: Specifies an event that triggers the deferred loading. Here is one simple example of on viewport trigger

@defer (on viewport) {
  <component />
}

(on viewport) specifies that the deferred rendering should happen when the element comes into the viewport.

when <condition>: Defines the condition that needs to be true before the template is loaded.
prefetch on <trigger>: Optionally, you can prefetch the content based on a trigger.
prefetch when <condition>: Optionally, you can prefetch the content when a certain condition is true.

@placeholder Directive
This defines what should be shown while the deferred content is being loaded.

@loading Directive
This defines the content to be shown while the deferred content is actually loading.

@error Directive
This defines what should be shown if there's an error during the loading process.

In short, this syntax lets you control when different parts of your Angular template appear and what to show while you’re waiting, depending on different conditions and triggers.

Benefits of Using @defer directive

• Faster Loading: By delaying less important content, your app loads quicker and feels smoother to use.
• Better User Experience: Users see the key parts of your app right away, while the less important stuff loads in the background, so the app stays responsive.
• Efficient Use of Resources: By waiting to display parts of your app that aren’t needed right away, you free up your browser’s resources, making everything run more smoothly.

Summary
The @defer directive in Angular helps make your app run better and faster. It allows you to delay loading some parts of your app until they're really needed. This way, your app stays quick and responsive, even if it has a lot of data or complex tasks. Using @defer can make your app perform better and provide a smoother experience for users.

Please let me know in the comments area if you have any questions.

One of the most useful features of an Angular application is the ability to manage route access with Angular Guards. They aid in application security by deciding whether or not a user can access a specific route. An in-depth explanation of angular guards, including their types, applications, and real-world examples, will be given in this article.

Angular Guard Types
Angular offers five different kinds of guards.

• CanActivate: Ascertains the possibility of activating a route.
• CanActivateChild: Ascertains whether it is possible to activate a child route.   
• CanDeactivate: Ascertains if deactivating a route is possible.
• Before a route is activated, resolve pre-fetches of data.
• Checks whether a module can be loaded slowly using the CanLoad function.

Angular can do more with routing than just rendering components. Large-scale applications can work and perform much better with advanced routing systems. I'll go over some of the more intricate features of Angular's Router here, such as nested routes, route guards, and lazy loading.

1. Lazy Loading
Lazy loading is a technique to load JavaScript components asynchronously when they are needed rather than loading everything upfront. This is particularly useful for large applications with numerous features, reducing the initial load time and improving performance. To implement lazy loading in Angular, you can define routes to load modules only when they are accessed.

Example
Suppose you have a feature module named AdminModule which you want to load only when needed. First, you'll need to create a routing module for AdminModule.

// admin-routing.module.ts
import { NgModule } from '@angular/core';
import { Routes, RouterModule } from '@angular/router';
import { AdminComponent } from './admin/admin.component';
const routes: Routes = [
  { path: '', component: AdminComponent }
];
@NgModule({
  imports: [RouterModule.forChild(routes)],
  exports: [RouterModule]
})
export class AdminRoutingModule { }

Then, update the main routing module to lazy load AdminModule.
// app-routing.module.ts
import { NgModule } from '@angular/core';
import { Routes, RouterModule } from '@angular/router';
const routes: Routes = [
  { path: 'admin', loadChildren: () => import('./admin/admin.module').then(m => m.AdminModule) }
];
@NgModule({
  imports: [RouterModule.forRoot(routes)],
  exports: [RouterModule]
})
export class AppRoutingModule { }

2. Route Guards
Route guards are useful for granting or restricting access to certain routes based on specific conditions, such as user authentication or authorization. Angular provides several types of route guards including CanActivate, CanActivateChild, CanDeactivate, and Resolve.

Example
Here’s how you can use a CanActivate guard to prevent access to a route for unauthenticated users.

First, implement the CanActivate interface.
// auth.guard.ts
import { Injectable } from '@angular/core';
import { CanActivate, Router, ActivatedRouteSnapshot, RouterStateSnapshot } from '@angular/router';
import { AuthService } from './auth.service';
@Injectable({
  providedIn: 'root'
})
export class AuthGuard implements CanActivate {
  constructor(private authService: AuthService, private router: Router) {}
  canActivate(
    next: ActivatedRouteSnapshot,
    state: RouterStateSnapshot): boolean {
    if (this.authService.isLoggedIn()) {
      return true;
    } else {
      this.router.navigate(['/login']);
      return false;
    }
  }
}

Then, apply the guard to a route:
// app-routing.module.ts
import { AuthGuard } from './auth.guard';
const routes: Routes = [
  { path: 'secure', component: SecureComponent, canActivate: [AuthGuard] }
];

3. Nested Routes
Nested routes, or child routes, help in organizing complex structures where a component has its own sub-routes. It is typically used in dashboard layouts where different sections have their own sub-navigation.

Example
// app-routing.module.ts
const routes: Routes = [
  {
    path: 'dashboard',
    component: DashboardComponent,
    children: [
      { path: 'reports', component: ReportsComponent },
      { path: 'analytics', component: AnalyticsComponent }
    ]
  }
];

In this configuration, navigating to /dashboard/reports and /dashboard/analytics will render ReportsComponent and AnalyticsComponent within the DashboardComponent.

Summary
Advanced routing mechanisms in Angular provide powerful tools for optimizing app performance and enhancing security. By implementing lazy loading, you can decrease initial load times. Route guards enforce security protocols by controlling access to routes. Nested routes allow for a more organized application structure, catering to complex user interfaces. Together, these features enable developers to build robust, efficient, and secure applications.

Sanitization in Angular is an essential component of web development that guards against Cross-Site Scripting (XSS) assaults, ensuring the security of the application. Angular comes with built-in capabilities to sanitize data before it's rendered in the application, shielding it from malicious scripts and safeguarding users.

Recognizing XSS and the Sanitization Need
When a hacker inserts malicious scripts into content from an unreliable source, it's known as an XSS assault. These scripts have the ability to run in the user's browser and may steal information or carry out unauthorized tasks. Angular sanitizes inputs prior to binding them to the DOM in order to reduce these dangers. The integrated sanitization feature of Angular verifies that user data is free of dangerous information.

How Angular Handles Sanitization?
Angular sanitizes data automatically in templates for certain contexts.

• HTML: When binding data to HTML, Angular sanitizes it to prevent the injection of malicious HTML.
• Styles: Angular ensures that style bindings are safe.
• URLs: URL bindings are sanitized to avoid malicious links.
• Resource URLs: When loading resources, Angular ensures URLs are safe.

Using Angular's DomSanitizer
For cases where you need to allow specific trusted content, Angular provides the DomSanitizer service. This service allows you to mark content as safe explicitly.

Example. Using DomSanitizer
Let's create an example where we use DomSanitizer to handle potentially unsafe HTML content safely.

Step 1. Set Up the Angular Project
Create a new Angular project if you don't have one already.

Step 2. Create a Component
Generate a new component for our example.

Step 3. Implement Sanitization in the Component
Modify the safe-content.component.ts to use DomSanitizer.
import { Component } from '@angular/core';
import { DomSanitizer, SafeHtml } from '@angular/platform-browser';

@Component({
  selector: 'app-safe-content',
  templateUrl: './safe-content.component.html',
  styleUrls: ['./safe-content.component.css']
})
export class SafeContentComponent {
  public trustedHtml: SafeHtml;

  constructor(private sanitizer: DomSanitizer) {
    const potentiallyUnsafeHtml = `<div style="color: red;">This is safe content</div>`;
    this.trustedHtml = this.sanitizer.bypassSecurityTrustHtml(potentiallyUnsafeHtml);
  }
}

In this example, we use bypassSecurityTrustHtml to mark the HTML content as safe explicitly.

Step 4. Display the Content in the Template
Modify safe-content.component.html to display the sanitized HTML content.
<div [innerHtml]="trustedHtml"></div>

Step 5. Use the Component in Your App
Include the SafeContentComponent in your app.component.html
<app-safe-content></app-safe-content>

Step 6. Run the Application
Run your Angular application to see the sanitized content in action.

Conclusion
Web security requires sanitization, and Angular offers powerful tools for managing it. Through the use of DomSanitizer and Angular's automated sanitization, developers can guarantee that their apps are safe from cross-site scripting (XSS) threats while maintaining flexibility in content rendering. Building dependable and safe online apps requires an understanding of and adherence to Angular sanitization procedures.

You may handle user-generated content in your Angular applications safely by following the instructions in this article. This will guarantee that your application is secure and that the data of your users is safeguarded.

There are multiple processes involved in creating a comprehensive AngularJS to-do list application. I'll walk you through every step of the process here, including adding, modifying, and removing jobs along with the relevant warnings and duplicate value checking.

A List of Tasks in AngularJS
Install the AngularJS application in step 1.

Make the index.html HTML file
<!DOCTYPE html>
<html lang="en">
<head>
    <meta charset="UTF-8">
    <title>AngularJS To-Do List</title>
    <link rel="stylesheet" href="styles.css">
    <script src="https://ajax.googleapis.com/ajax/libs/angularjs/1.8.2/angular.min.js"></script>
    <script src="app.js"></script>
</head>
<body ng-app="todoApp" ng-controller="todoController">
    <div class="container">
        <h1>To-Do List</h1>
        <div class="input-group">
            <input type="text" ng-model="newTask" placeholder="Add a new task" class="form-control">
            <button ng-click="addTask()" class="btn btn-primary">Add Task</button>
        </div>
        <div ng-if="alertMessage" class="alert" ng-class="{'alert-success': alertType=='success', 'alert-danger': alertType=='danger'}">
            {{ alertMessage }}
        </div>
        <ul class="list-group">
            <li ng-repeat="task in tasks" class="list-group-item">
                <span ng-if="!task.editing">{{ task.name }}</span>
                <input type="text" ng-if="task.editing" ng-model="task.name" class="form-control">
                <button ng-if="!task.editing" ng-click="editTask(task)" class="btn btn-warning btn-sm">Edit</button>
                <button ng-if="task.editing" ng-click="saveTask(task)" class="btn btn-success btn-sm">Save</button>
                <button ng-click="deleteTask(task)" class="btn btn-danger btn-sm">Delete</button>
            </li>
        </ul>
    </div>
</body>
</html>

Create the AngularJS file (app.js)
var app = angular.module('todoApp', []);
app.controller('todoController', function($scope) {
    $scope.tasks = [];
    $scope.alertMessage = '';
    $scope.alertType = '';
    $scope.addTask = function() {
        if (!$scope.newTask) {
            $scope.showAlert('Task cannot be empty', 'danger');
            return;
        }
        if ($scope.tasks.some(task => task.name === $scope.newTask)) {
            $scope.showAlert('Task already exists', 'danger');
            return;
        }
        $scope.tasks.push({ name: $scope.newTask, editing: false });
        $scope.newTask = '';
        $scope.showAlert('Task added successfully', 'success');
    };
    $scope.editTask = function(task) {
        task.editing = true;
    };
    $scope.saveTask = function(task) {
        if (!$scope.tasks.some(t => t !== task && t.name === task.name)) {
            task.editing = false;
            $scope.showAlert('Task edited successfully', 'success');
        } else {
            $scope.showAlert('Duplicate task name', 'danger');
        }
    };
    $scope.deleteTask = function(task) {
        var index = $scope.tasks.indexOf(task);
        if (index > -1) {
            $scope.tasks.splice(index, 1);
            $scope.showAlert('Task deleted successfully', 'success');
        }
    };
    $scope.showAlert = function(message, type) {
        $scope.alertMessage = message;
        $scope.alertType = type;
        setTimeout(function() {
            $scope.$apply(function() {
                $scope.alertMessage = '';
            });
        }, 3000);
    };
});

Create a CSS file (styles.css) for styling
body {
    font-family: Arial, sans-serif;
    margin: 20px;
}
.container {
    max-width: 600px;
    margin: auto;
}
.input-group {
    display: flex;
    margin-bottom: 20px;
}
.form-control {
    flex: 1;
    padding: 10px;
    font-size: 16px;
}
.btn {
    padding: 10px 20px;
    font-size: 16px;
    cursor: pointer;
}
.list-group {
    list-style-type: none;
    padding: 0;
}
.list-group-item {
    display: flex;
    justify-content: space-between;
    padding: 10px;
    background-color: #f9f9f9;
    margin-bottom: 5px;
    border: 1px solid #ddd;
}
.alert {
    padding: 10px;
    margin-bottom: 20px;
}
.alert-success {
    background-color: #d4edda;
    border-color: #c3e6cb;
    color: #155724;
}
.alert-danger {
    background-color: #f8d7da;
    border-color: #f5c6cb;
    color: #721c24;
}

Explanation of the Code
HTML Structure

• The HTML file sets up the structure of the To-Do list application.
• It includes an input field for new tasks, a button to add tasks, and a list to display tasks.
• Each task can be edited or deleted.

AngularJS Controller (app.js)

• The todoController manages the tasks array and handles adding, editing, and deleting tasks.
• The addTask function checks for duplicate tasks and alerts the user if a task already exists.
• The editTask function enables editing mode for a task.
• The saveTask function saves the edited task and checks for duplicate names.
• The deleteTask function removes a task from the list.
• The showAlert function displays an alert message for 3 seconds.

Styling (styles.css)

• The CSS file styles the To-Do list application, including the input field, buttons, list items, and alert messages.

By following these steps, you can create a fully functional To-Do list application in AngularJS with features like adding, editing, deleting tasks, and handling duplicate tasks with appropriate alerts.

With the help of Angular's robust data binding capability, developers can synchronize data between the model and the view. Data binding is one of the ways that Angular enables communication between components and the DOM.

An outline of the primary Angular data binding types can be found here.

1. The use of interpolation
You can insert expressions between the double curly braces ({{ }}) by using interpolation. Data from the component is usually displayed to the view via this.

Usage: {{ expression }}

Example
<button (click)="onClick()">Click me</button>

2. Property Binding
Property binding allows you to bind data from the component to the property of an HTML element or directive. This helps in setting element properties based on component data.
    Usage: [property]="expression"
    Example
   <img [src]="imageUrl">

3. Event Binding
Event binding allows you to respond to user events such as clicks, key presses, and mouse movements. It binds a DOM event to a method in the component.
    Usage: (event)="handler"
    Example

    <button (click)="onClick()">Click me</button>

4. Two-Way Data Binding
Two-way data binding combines property binding and event binding to synchronize data between the model and the view. Angular provides the ngModel directive to facilitate two-way data binding.

    Usage: [(ngModel)]="property"
    Example

    <input [(ngModel)]="name">
    <p>Hello, {{ name }}!</p>

5. Detailed Explanation and Examples
Interpolation: Interpolation evaluates an expression in the context of the current data-bound component. It is useful for embedding dynamic values into the HTML.
Example

    export class AppComponent {
      title = 'Hello, Angular!';
    }

<h1>{{ title }}</h1>

6. Property Binding
Property binding is used to set a property of a view element. It is a one-way data-binding from the component to the view.
Example
export class AppComponent {
  imageUrl = 'https://angular.io/assets/images/logos/angular/angular.svg';
}

<img [src]="imageUrl">

7. Event Binding
Event binding listens to events such as keystrokes, mouse movements, clicks, and touches. When the event is triggered, it calls the specified method in the component.
Example
export class AppComponent {
  onClick() {
    console.log('Button clicked!');
  }
}

<button (click)="onClick()">Click me</button>

8. Two-Way Data Binding
Two-way data binding allows for the automatic synchronization of data between the model and the view. The ngModel directive simplifies this by updating the model whenever the input value changes and updating the input value when the model changes.

Example
import { Component } from '@angular/core';
@Component({
  selector: 'app-root',
  template: `
    <input [(ngModel)]="name">
    <p>Hello, {{ name }}!</p>
  `
})
export class AppComponent {
  name: string = '';
}

Conclusion
Data binding in Angular facilitates seamless communication between the template (view) and the component (model). It simplifies the process of displaying data, responding to user input, and keeping the view and model synchronized. For more detailed information, you can refer to the official Angular documentation on data binding: Angular Data Binding​​​​​.

Angular apps frequently have to deal with intricate data binding and frequent updates, which, if not done correctly, can cause performance problems. The OnPush change detection mechanism is a potent tool for performance optimization. In order to assist you in integrating OnPush into your Angular projects, this article explains what it is, how it functions, and offers useful examples.

OnPush change detection: what is it?

When an event, such user input, an HTTP request, or a timer, happens, every component in Angular employs the Default change detection technique by default, which involves checking for changes. Performance bottlenecks may result from this, particularly in large applications.

Performance is enhanced by the OnPush change detection approach, which looks for changes only when:

• The input attributes of the component alter.
• The component experiences the triggering of an event.

By using OnPush, you can reduce the number of checks Angular performs, making your application more efficient.
Implementing OnPush change detection

To implement the OnPush strategy, you need to modify the ChangeDetectionStrategy property of your component's decorator. Here's how you can do it:

Step 1. Import ChangeDetectionStrategy and ChangeDetectorRef
import { Component, ChangeDetectionStrategy, ChangeDetectorRef } from '@angular/core';

Step 2. Set ChangeDetectionStrategy to OnPush
@Component({
  selector: 'app-example',
  templateUrl: './example.component.html',
  styleUrls: ['./example.component.css'],
  changeDetection: ChangeDetectionStrategy.OnPush
})
export class ExampleComponent {
  constructor(private cdr: ChangeDetectorRef) {}
  // Component logic here
}

Step 3. Manage Component Updates
Since OnPush only checks for changes when inputs change, or events occur, you need to handle updates explicitly. For instance, if you update a component's state based on an asynchronous operation, you should manually mark the component for check:
import { Component, ChangeDetectionStrategy, ChangeDetectorRef } from '@angular/core';

@Component({
  selector: 'app-example',
  templateUrl: './example.component.html',
  styleUrls: ['./example.component.css'],
  changeDetection: ChangeDetectionStrategy.OnPush
})
export class ExampleComponent {
  data: any;

  constructor(private cdr: ChangeDetectorRef) {}

  updateData(newData: any) {
    this.data = newData;
    this.cdr.markForCheck(); // Explicitly mark for check
  }
}

Practical Example
Here's a complete example demonstrating the OnPush strategy
import { Component, ChangeDetectionStrategy, ChangeDetectorRef, Input, OnInit } from '@angular/core';
@Component({
  selector: 'app-example',
  template: `
    <div>
      <h1>{{title}}</h1>
      <button (click)="fetchData()">Fetch Data</button>
      <p *ngIf="data">{{data}}</p>
    </div>
  `,
  changeDetection: ChangeDetectionStrategy.OnPush
})
export class ExampleComponent implements OnInit {
  @Input() title: string;
  data: string;
  constructor(private cdr: ChangeDetectorRef) {}
  ngOnInit(): void {
    // Initialization logic here
  }
  fetchData(): void {
    // Simulate an async operation
    setTimeout(() => {
      this.data = 'New Data Loaded';
      this.cdr.markForCheck(); // Explicitly mark for check
    }, 2000);
  }
}

Benefits of OnPush Change Detection

• Improved Performance: Reduces unnecessary checks, leading to better performance.
• Predictable Change Detection: This makes it easier to reason about when and why Angular checks for changes.
• Efficient Resource Usage: Decreases CPU usage and enhances overall application responsiveness.

Conclusion
Using the OnPush change detection strategy in Angular is a powerful way to optimize your application's performance. By explicitly managing when Angular checks for changes, you can ensure that your application runs more efficiently, especially as it grows in complexity. Implement OnPush in your Angular projects today to experience these performance benefits firsthand.