Introduction Excellent new feature in JavaScript ES2020

Introduction Excellent new feature in JavaScript ES2020

New JavaScript Features Coming in ES2020 That You Can Use Now

New JavaScript Features Coming in ES2020 That You Can Use Now

In this series, we’re going to show the EcmaScript features from 2015 to today.

  • ES2015 aka ES6
  • ES2016 aka ES7
  • ES2017 aka ES8
  • ES2018 aka ES9
  • ES2019 aka ES10
  • ES2020 aka ES11
Introduction

ES2020 is the version of ECMAScript corresponding to the year 2020. This version doesn’t include as many new features as those that appeared in ES6 (2015). However, some useful features have been incorporated.

This article introduces the features provided by ES2020 in easy code examples. In this way, you can quickly understand the new features without the need for a complex explanation.

Of course, it’s necessary to have a basic knowledge of JavaScript to fully understand the best ones introduced.

The new JavaScriptfeatures in ES2020 are:

➡️ String.prototype.matchAll
➡️ import()
➡️ BigInt
➡️ Promise.allSettled
➡️ globalThis
➡️ for-in mechanics
➡️ Optional Chaining
➡️ Nullish coalescing Operator

String.protype.matchAll

The matchAll() method returns an iterator of all results matching a string against a regular expression, including capturing groups.

Dynamic Import

Dynamic import() returns a promise for the module namespace object of the requested module. Therefore, imports can now be assigned to a variable using async/await.

BigInt — Arbitrary Precision Integers

BigInt is the seventh primitive type, and it’s an arbitrary-precision integer. The variables can now represent 253 numbers and not just max out at 9007199254740992.

Promise.allSettled

Promise.allSettled returns a promise that’s fulfilled with an array of promise state snapshots, but only after all the original promises have settled; i.e. become either fulfilled or rejected.

We say that a promise is settled if it is not pending; i.e. if it’s either fulfilled or rejected.

Standardized globalThis object

The global this was not standardized before ES10.
In production code you would “standardize” it across multiple platforms on your own by writing this monstrosity:

For-in Mechanics

ECMA-262 leaves the order of for (a in b) almost totally unspecified, but real engines tend to be consistent in at least some cases.

Historical efforts to get consensus on a complete specification of the order of for-in have repeatedly failed. This in part because all engines have their own idiosyncratic implementations that are the result of a great deal of work and that they don’t really want to revisit.

In conclusion, the different engines have agreed on how properties are iterated when using the for (a in b) control structure so that the behavior is standardized.

Nullish Coalescing Operator

When performing property accesses, it’s often desired to provide a default value if the result of that property access is null or undefined. At present, a typical way to express this intent in JavaScript is by using the || operator.

This works well for the common case of null and undefined values, but there are a number of falsy values that might produce surprising results.

The nullary coalescing operator is intended to handle these cases better and serve as an equality check against nullary values (null or undefined). If the expression at the left-hand side of the ?? operator evaluates to undefined or null, its right-hand side is returned.

Optional Chaining

When looking for a property value that’s deep in a tree-like structure, one often has to check whether intermediate nodes exist.

The Optional Chaining Operator allows developers to handle many of those cases without repeating themselves and/or assigning intermediate results in temporary variables.

Also, many API return either an object or null/undefined, and one may want to extract a property from the result only when it’s not null:

When some value other than undefined is desired for the missing case, this can usually be handled with the Nullish coalescing operator:

Conclusion

JavaScript is a live language, and that’s something very healthy for web development. Since the appearance of ES6 in 2015, we’re living a vibrant evolution in the language. In this post, we’ve reviewed the features that arise in ES2020.

Although many of these features may not be essential for the development of your web application, they’re giving possibilities that could be achieved before with tricks or a lot of verbosity.

Thank you for reading !

JavaScript ES6 Classes

JavaScript ES6 Classes

An exciting new construct that was introduced in the ES6 specification is the ES6 classes. If you're a Javascript developer, you will be aware that Javascript follows prototypal inheritance and sometimes it can get a little messy. However, with ES6 classes the syntax is simpler and much more intuitive.

An exciting new construct that was introduced in the ES6 specification is the ES6 classes. If you're a Javascript developer, you will be aware that Javascript follows prototypal inheritance and sometimes it can get a little messy. However, with ES6 classes the syntax is simpler and much more intuitive.

Classes are a fundamental part of object oriented programming (OOP). They define “blueprints” for real-world object modeling and organize code into logical, reusable parts. Classes share many similarities with regular objects. They have their own constructor functions, properties, and methods. In this tutorial, we’ll demonstrate how to create and work with ES6 classes.

Creating a class

You can create a class using the class keyword:

class Person{

  constructor(name, age) {

    this.name = name

    this.age = age

  }

}



let person = new Person("Sam", 30)



person.name

//returns 'Sam'



person.age

//returns 30

Notice how we define our Person class with a constructor() function taking two arguments name and age. Using the this keyword, we set the name and age properties based on the provided arguments. Remember that the constructor function is called whenever we create a new instance of the Person class.

Similar to objects, we can read class properties using dot notation so that person.name returns Sam.

Defining properties and methods

You can define properties and methods for a class the same way you do for regular objects:

class Person{

  constructor(name, age) {

    this.name = name

    this.age = age

  }



  sayName() {

    console.log("My name is " + this.name)

  }

}



let person = new Person('Tim', 40)



person.sayName()

//logs 'My name is Tim'



person.location = 'London'



person.location

//returns 'London'

Notice how we define a sayName() function within our Person class definition. Once we create a new instance of Person, we can call the method via person.sayName().

You can also add properties and methods on the fly. You’ll notice that while the location property isn’t defined in our constructor function, we can still dynamically add it later on for the person instance. Remember that if we created a new instance of Person, it would not have a location property because that property is not defined in the class definition. Only properties and methods that we explicitly define will be shared by all instances of the class.

Static functions

You can use the static keyword to make class methods static. A static method acts on the class itself, not on instances of the class:

class Person{

  constructor(name, age) {

    this.name = name

    this.age = age

  }



  static describe(){

    console.log("This is a person.")

  }



  sayName() {

    console.log("My name is " + this.name)

  }

}



Person.describe()

//logs 'This is a person.'

Notice how static methods operate on the class itself and not an instance of the class. We didn’t have to create a new Person to call the static method.

Static methods are useful for common or shared class functionality. In this case, the describe() method is used to describe what the Person class is. It will apply to every instance of Person. This is why we make it a static method.

Class Inheritance

Inheritance allows you to create new classes based off existing ones. These new classes “inherit” the methods and properties of their parent. They can also override or extend the parent:

class Person{

  constructor(name, age) {

    this.name = name

    this.age = age

  }


  static describe(){

    console.log("This is a person.")

  }


  sayName() {

    console.log("My name is " + this.name)

  }

}



class Programmer extends Person {

  sayName(){

    console.log("My name is " + this.name + " and I am a programmer!")

  }

}



let averageJoe = new Person('Todd', 40)

let programmer = new Programmer('Sam', 33)



averageJoe.sayName()


//logs 'My name is Todd'


programmer.sayName()


//logs 'My name is Sam and I am a programmer!'

Using the extends keyword, we can create a new class sharing the same characteristics as Person. Notice how we override the sayName() method with a new definition for the Programmer class. Apart from overriding this method, everything else remains the same for both Person and Programmer.

Using super

The super keyword allows a child class to invoke parent class properties and methods.

class Person{

  constructor(name, age) {

    this.name = name

    this.age = age

  }



  static describe(){

    console.log("This is a person.")

  }



  sayName() {

    console.log("My name is " + this.name)

  }

}





class Programmer extends Person {

  sayName(){

    super.sayName()

    console.log("My name is " + this.name + " and I am a programmer!")

  }

}



let averageJoe = new Person('Todd', 40)

let programmer = new Programmer('Sam', 33)



programmer.sayName()



//logs 'My name is Sam'

//logs 'My name is Sam and I am a programmer!'

Notice how we call super.sayName() in the Programmer implementation of sayName(). While this invokes the parent implementation of super.sayName(), the name property still references the Programmer class.

Conclusion

Classes facilitate object oriented programming in JavaScript. While regular objects provide similar functionality, classes provide the extra advantage of inheritance and static methods.

Linked Lists in JavaScript With ES6

Linked Lists in JavaScript With ES6

Linked Lists in JavaScript with ES6.This series is about data structure implementation in JavaScript using the ES6 specification.. Let's see how to make a singly linked list in Javascript… ... list in Javascript. We'll be using ES6 syntax throughout.

This is a continuation of a previous piece where we digested all surrounding concepts, pros and cons, Big O time complexity, real use cases, linked-list mainly operations, and all that kind of theory. If you have not read it yet, I recommend you read it first.

This series is about data structure implementation in JavaScript using the ES6 specification.

The aim of this second piece is to walk through the implementation of a linked list. Actually, the two pieces enclose a linked list itself since the prior piece is pointing to this one.

The Node Class

In the next code, we’re going to define our Node class with its constructor. Remember, the node is the basic building block to store the data and the next pointer.

This class will have to handle the node creation. Every time the class is instantiated, the constructor has the responsibility to initialize the two properties: data and next.


Node Class

Now the challenge is to create the next four nodes (just nodes creation, not how to connect them).


Linked List

Basically, we have to instantiate the Node class four times in order to create the four nodes.


Creating Nodes

At this point, we don’t care about the second parameter. Why? Because at this moment, we’re just learning how to create the node without having to worry about how they’ll be connecting together.

How Can We Connect the Nodes?

In the prior code, we just created nodes independently. Now is time to learn how to connect them to form the linked list.


Connecting nodes

We have defined the Node class. Next is to define a new class that will handle the nextpointer property and the main operations in the linked list. Let’s create the LinkedList class.


Linked List Class

In the above code, we have just defined a class called LinkedList with its constructor. This has the work of initializing the headproperty, to store the first node,and size, to keep track of the size of the linked list.

Next is to offer the ability to insert to the head, to the tail, or at any random position in the list.

Inserting Into the Head


Inserting to head

We have just created a simple method to add nodes to the head of the linked list. We are passing down to it the dataparameter and setting a value for the this.head property creating a new instance of the Node class.

Let’s do some tests of its implementation so far and see the results.

The output will be:


Linked list output

Inserting at the Tail

We just learned how to add nodes to the head. It’s time to know how to add nodes to the tail.


Inserting at the tail

In the aboveinsertToTail function, we are passing down the data parameter, and then we created a new instance of the Node class. After that, we are checking if the head is empty. If so, the head itself will be set to the new node we have just after created. Otherwise, set the tail with the head and then loop through the linked list to find the tail and update the tail’s next pointer.

Inserting at Random Position

Finally, we are going to see how to insert a new node in the linked list at a given random position. For this, we have to traverse the list until we find the desired position.

Inserting at a given random position

Now we are going to test this function using the next tests.

The output will be as below. As you can see, at the given index, the node (600) was added at the second index of the list.

The Whole Code

class Node {
  constructor(data, next = null) {
    this.data = data;
    this.next = next;
  }
}

//Let's create four nodes
let node1 = new Node(5);
let node2 = new Node(10);
let node3 = new Node(20);
let node4 = new Node(1);

//connecting nodes
node1.next = node2;
node2.next = node3;
node3.next = node4;

//LinkedList Class
class LinkedList {
  constructor() {
    this.head = null; //first node of the Linked List
    this.size = 0; //Track size of the linked list
  }
  //Insert to head
  insertToHead(data) {
    this.head = new Node(data, this.head);
    this.size++;
  }

  //Insert into the tail
  insertToTail(data) {
    const node = new Node(data);
    let tail = null;
    //if empty, make it head
    if (!this.head) {
      this.head = node;
    } else {
      tail = this.head;
      while (tail.next) {
        tail = tail.next;
      }
      tail.next = node;
    }
    this.size++;
  }

  //Insert at random position
  insertAt(data, index) {
    //if it's empty
    if (!this.head) {
      this.head = new Node(data);
      return;
    }
    //if it needs add to the front of the list
    if (index === 0) {
      this.insertToHead(data); //reuse insertToHead function
      return;
    }
    let node = new Node(data);
    let current, previous;
    let count = 0;
    // current will be first
    current = this.head;
    while (count < index) {
      previous = current;
      count++;
      current = current.next;
    }
    node.next = current;
    previous.next = node;
    this.size++;
  }
}

const linkedList = new LinkedList();
linkedList.insertToHead(100);
linkedList.insertToHead(200);
linkedList.insertToHead(300);
linkedList.insertToTail(400);
linkedList.insertAt(600, 2);

console.table(linkedList);

LinkedList.js

I hope you have gained more knowledge about data structure and especially with Linked list. That’s all for now.

Thanks for reading!

An Introduction to JavaScript ES6 Proxies

An Introduction to JavaScript ES6 Proxies

Proxy is one of the most overlooked concepts introduced in ES6 version of JavaScript, but ES6 proxies bound to come in handy at some point in your future.

Proxy is one of the most overlooked concepts introduced in the ES6 version of JavaScript.

Admittedly, it isn’t particularly useful on a day-to-day basis, but it is bound to come in handy at some point in your future.

The basics

The Proxy object is used to define a custom behavior for fundamental operations such as property lookup, assignment, and function invocation.

The most basic example of a proxy would be:

const obj = {
 a: 1,
 b: 2,
};

const proxiedObj = new Proxy(obj, {
 get: (target, propertyName) => {
   // get the value from the "original" object
   const value = target[propertyName];

   if (!value && value !== 0) {
     console.warn('Trying to get non-existing property!');

     return 0;
   }

   // return the incremented value
   return value + 1;
 },
 set: (target, key, value) => {
   // decrement each value before saving
   target[key] = value - 1;

   // return true to indicate successful operation
   return true;
 },
});

proxiedObj.a = 5;

console.log(proxiedObj.a); // -> incremented obj.a (5)
console.log(obj.a); // -> 4

console.log(proxiedObj.c); // -> 0, logs the warning (the c property doesn't exist)

We have intercepted the default behavior of both get and set operations by defining the handlers with their respective names in the object provided to the proxy constructor. Now each get operation will return the incremented value of the property, while set will decrement the value before saving it in the target object.

What’s important to remember with proxies is that once a proxy is created, it should be the only way to interact with the object.

Different kinds of traps

There are many traps (handlers that intercept the object’s default behavior) aside from get and set, but we won’t be using any of them in this article. With that being said, if you are interested in reading more about them, here’s the documentation.

Having fun

Now that we know how proxies work, let’s have some fun with them.

Observing object’s state

As it has been stated before it is very easy to intercept operations with proxies. To observe an object’s state is to be notified every time there’s an assignment operation.

const observe = (object, callback) => {
 return new Proxy(object, {
   set(target, propKey, value) {
     const oldValue = target[propKey];
   
     target[propKey] = value;

     callback({
       property: propKey,
       newValue: value,
       oldValue,
     });

     return true;
   }
 });
};

const a = observe({ b: 1 }, arg => {
 console.log(arg);
});

a.b = 5; // -> logs from the provided callback: {property: "b", oldValue: 1, newValue: 5}

And that’s all we have to do — invoke the provided callback every time the set handler is fired.

As an argument to the callback, we provide an object with three properties: the name of the changed property, the old value, and the new value.

Prior to executing the callback, we assign the new value in the target object so the assignment actually takes place. We have to return true to indicate that the operation has been successful; otherwise, it would throw a TypeError.

Here’s a live example.

Validating properties on set

If you think about it, proxies are a good place to implement validation — they are not tightly coupled with the data itself. Let’s implement a simple validation proxy.

As in the previous example, we have to intercept the set operation. We would like to end up with the following way of declaring data validation:

const personWithValidation = withValidation(person, {
 firstName: [validators.string.isString(), validators.string.longerThan(3)],
 lastName: [validators.string.isString(), validators.string.longerThan(7)],
 age: [validators.number.isNumber(), validators.number.greaterThan(0)]
});

In order to achieve this, we define the withValidation function like so:

const withValidation = (object, schema) => {
 return new Proxy(object, {
   set: (target, key, value) => {
     const validators = schema[key];

     if (!validators || !validators.length) {
       target[key] = value;

       return true;
     }

     const shouldSet = validators.every(validator => validator(value));

     if (!shouldSet) {
       // or get some custom error
       return false;
     }

     target[key] = value;
     return true;
   }
 });
};

First we check whether or not there are validators in the provided schema for the property that is currently being assigned — if there aren’t, there is nothing to validate and we simply assign the value.

If there are indeed validators defined for the property, we assert that all of them return true before assigning. Should one of the validators return false, the whole set operation returns false, causing the proxy to throw an error.

The last thing to do is to create the validators object.

const validators = {
 number: {
   greaterThan: expectedValue => {
     return value => {
       return value > expectedValue;
     };
   },
   isNumber: () => {
     return value => {
       return Number(value) === value;
     };
   }
 },
 string: {
   longerThan: expectedLength => {
     return value => {
       return value.length > expectedLength;
     };
   },
   isString: () => {
     return value => {
       return String(value) === value;
     };
   }
 }
};

The validators object contains validation functions grouped by the type they should validate. Each validator on invocation takes the necessary arguments, like validators.number.greaterThan(0), and returns a function. The validation happens in the returned function.

We could extend the validation with all kinds of amazing features, such as virtual fields or throwing errors from inside the validator to indicate what went wrong, but that would make the code less readable and is outside the scope of this article.

Here’s a live example.

Making code lazy

For the final — and hopefully most interesting — example, let’s create a proxy that makes all the operations lazy.

Here’s a very simple class called Calculator, which contains a few basic arithmetic operations.

class Calculator {
 add(a, b) {
   return a + b;
 }

 subtract(a, b) {
   return a - b;
 }

 multiply(a, b) {
   return a * b;
 }

 divide(a, b) {
   return a / b;
 }
}

Now normally, if we ran the following line:

new Calculator().add(1, 5) // -> 6

The result would be 6.

The code is executed on the spot. What we would like is to have the code wait for the signal to be run, like a run method. This way the operation will be postponed until it is needed — or not executed at all if there is never a need.

So the following code, instead of 6, would return the instance of the Calculator class itself:

lazyCalculator.add(1, 5) // -> Calculator {}

Which would give us another nice feature: method chaining.

lazyCalculator.add(1, 5).divide(10, 10).run() // -> 1

The problem with that approach is that in divide, we have no clue of what the result of add is, which makes it kind of useless. Since we control the arguments, we can easily provide a way to make the result available through a previously defined variable — $, for example.

lazyCalculator.add(5, 10).subtract($, 5).multiply($, 10).run(); // -> 100

$ here is just a constant Symbol. During execution, we dynamically replace it with the result returned from the previous method.

const $ = Symbol('RESULT_ARGUMENT');

Now that we have a fair understanding of what do we want to implement, let’s get right to it.

Let’s create a function called lazify. The function creates a proxy that intercepts the get operation.

function lazify(instance) {
 const operations = [];

 const proxy = new Proxy(instance, {
   get(target, propKey) {
     const propertyOrMethod = target[propKey];

     if (!propertyOrMethod) {
       throw new Error('No property found.');
     }

     // is not a function
     if (typeof propertyOrMethod !== 'function') {
       return target[propKey];
     }

     return (...args) => {
       operations.push(internalResult => {
         return propertyOrMethod.apply(
           target,
           [...args].map(arg => (arg === $ ? internalResult : arg))
         );
       });

       return proxy;
     };
   }
 });

 return proxy;
}

Inside the get trap, we check whether or not the requested property exists; if it doesn’t, we throw an error. If the property is not a function, we return it without doing anything.

Proxies don’t have a way of intercepting method calls. Instead, they are treating them as two operations: the get operation and a function invocation. Our get handler has to act accordingly.

Now that we are sure the property is a function, we return our own function, which acts as a wrapper. When the wrapper function is executed, it adds yet another new function to the operations array. The wrapper function has to return the proxy to make it possible to chain methods.

Inside the function provided to the operations array, we execute the method with the arguments provided to the wrapper. The function is going to be called with the result argument, allowing us to replace all the $ with the result returned from the previous method.

This way we delay the execution until requested.

Now that we have built the underlying mechanism to store the operations, we need to add a way to run the functions — the .run() method.

This is fairly easy to do. All we have to do is check whether the requested property name equals run. If it does, we return a wrapper function (since run acts as a method). Inside the wrapper, we execute all the functions from the operations array.

The final code looks like this:

const executeOperations = (operations, args) => {
 return operations.reduce((args, method) => {
   return [method(...args)];
 }, args);
};

const $ = Symbol('RESULT_ARGUMENT');

function lazify(instance) {
 const operations = [];

 const proxy = new Proxy(instance, {
   get(target, propKey) {
     const propertyOrMethod = target[propKey];

     if (propKey === 'run') {
       return (...args) => {
         return executeOperations(operations, args)[0];
       };
     }

     if (!propertyOrMethod) {
       throw new Error('No property found.');
     }

     // is not a function
     if (typeof propertyOrMethod !== 'function') {
       return target[propKey];
     }

     return (...args) => {
       operations.push(internalResult => {
         return propertyOrMethod.apply(
           target,
           [...args].map(arg => (arg === $ ? internalResult : arg))
         );
       });

       return proxy;
     };
   }
 });

 return proxy;
}

The executeOperations function takes an array of functions and executes them one by one, passing the result of the previous one to the invocation of the next one.

And now for the final example:

const lazyCalculator = lazify(new Calculator());

const a = lazyCalculator
 .add(5, 10)
 .subtract($, 5)
 .multiply($, 10);

console.log(a.run()); // -> 100

If you are interested in adding more functionality I have added a few more features to the lazify function — asynchronous execution, custom method names, and a possibility to add custom functions through the .chain() method. Both versions of the lazify function are available in the live example.

Summary

Now that you have seen proxies in action, I hope that you could find a good use for them in your own codebase.

Proxies have many more interesting uses than those covered here, such as implementing negative indices and catching all the nonexistent properties in an object. Be careful, though: proxies are a bad choice when performance is an important factor.