Constructor Pattern

This is a class-based creational design pattern. Constructors are special functions that can be used to instantiate new objects with methods and properties defined by that function.

It is not one of the classic design patterns. In fact, it is more of a basic language construct than a pattern in most object-oriented languages. But in JavaScript, objects can be created on the fly without any constructor functions or “class” definition. Therefore, I think it is important to lay down the foundation for other patterns to come with this simple one.

Constructor pattern is one of the most commonly used patterns in JavaScript for creating new objects of a given kind.

In this example, we define a Hero class with attributes like name and specialAbility and methods like getDetails . Then, we instantiate an object IronMan by invoking the constructor method with the new keyword passing in the values for the respective attributes as arguments.

Constructor Pattern

Factory Pattern

Factory pattern is another class-based creational pattern. In this, we provide a generic interface that delegates the responsibility of object instantiation to its subclasses.

This pattern is frequently used when we need to manage or manipulate collections of objects that are different yet have many similar characteristics.

In this example, we create a factory class named BallFactory that has a method that takes in parameters, and, depending on the parameters, it delegates the object instantiation responsibility to the respective class. If the type parameter is "football" or "soccer" object instantiation is handled by Football class, but if it is "basketball" object instantiation is handled by Basketball class.

Factory Pattern

Prototype Pattern

This pattern is an object-based creational design pattern. In this, we use a sort of a “skeleton” of an existing object to create or instantiate new objects.

This pattern is specifically important and beneficial to JavaScript because it utilizes prototypal inheritance instead of a classic object-oriented inheritance. Hence, it plays to JavaScript’s strength and has native support.

In this example, we have a car object that we use as the prototype to create another object myCar with JavaScript’s Object.create feature and define an extra property owner on the new object.

Prototype Pattern

Singleton Pattern

Singleton is a special creational design pattern in which only one instance of a class can exist. It works like this — if no instance of the singleton class exists then a new instance is created and returned, but if an instance already exists, then the reference to the existing instance is returned.

A perfect real-life example would be that of mongoose (the famous Node.js ODM library for MongoDB). It utilizes the singleton pattern.

In this example, we have a Database class that is a singleton. First, we create an object mongo by using the new operator to invoke the Database class constructor. This time an object is instantiated because none already exists. The second time, when we create the mysql object, no new object is instantiated but instead, the reference to the object that was instantiated earlier, i.e. the mongo object, is returned.

Singleton Pattern

Adapter Pattern

This is a structural pattern where the interface of one class is translated into another. This pattern lets classes work together that could not otherwise because of incompatible interfaces.

This pattern is often used to create wrappers for new refactored APIs so that other existing old APIs can still work with them. This is usually done when new implementations or code refactoring (done for reasons like performance gains) result in a different public API, while the other parts of the system are still using the old API and need to be adapted to work together.

In this example, we have an old API, i.e. OldCalculator class, and a new API, i.e. NewCalculator class. The OldCalculator class provides an operation method for both addition and subtraction, while the NewCalculator provides separate methods for addition and subtraction. The Adapter class CalcAdapter wraps the NewCalculator to add the operation method to the public-facing API while using its own addition and subtraction implementation under the hood.

Adapter Pattern

Composite Pattern

This is a structural design pattern that composes objects into tree-like structures to represent whole-part hierarchies. In this pattern, each node in the tree-like structure can be either an individual object or a composed collection of objects. Regardless, each node is treated uniformly.

A Multi-level Menu Structure

It is a bit complex to visualize this pattern. The easiest way to think about this is with the example of a multi-level menu. Each node can be a distinct option, or it can be a menu itself, which has multiple options as its child. A node component with children is a composite component, while a node component without any child is a leaf component.

In this example, we create a base class of Component that implements the common functionalities needed and abstracts the other methods needed. The base class also has a static method that utilises recursion to traverse a composite tree structure made with its subclasses. Then we create two subclasses extending the base class — Leaf that does not have any children and Composite that can have children—and hence have methods handling adding, searching, and removing child functionalities. The two subclasses are used to create a composite structure—a tree, in this case.

Composite Pattern

Decorator Pattern

This is also a structural design pattern that focuses on the ability to add behaviour or functionalities to existing classes dynamically. It is another viable alternative to sub-classing.

The decorator type behaviour is very easy to implement in JavaScript because JavaScript allows us to add methods and properties to object dynamically. The simplest approach would be to just add a property to an object, but it will not be efficiently reusable.

In fact, there is a proposal to add decorators to the JavaScript language. Take a look at Addy Osmani’s post about decorators in JavaScript.

If you want to read about the proposal itself, feel free.

In this example, we create a Book class. We further create two decorator functions that accept a book object and return a “decorated” book object — giftWrap that adds one new attribute and one new function and hardbindBook that adds one new attribute and edits the value of one existing attribute.

Decorator Pattern

Façade Pattern

This is a structural design pattern that is widely used in the JavaScript libraries. It is used to provide a unified and simpler, public-facing interface for ease of use that shields away from the complexities of its consisting subsystems or subclasses.

The use of this pattern is very common in libraries like jQuery.

In this example, we create a public facing API with the class ComplaintRegistry . It exposes only one method to be used by the client, i.e. registerComplaint . It internally handles instantiating required objects of either ProductComplaint or ServiceComplaint based on the type argument. It also handles all the other complex functionalities like generating a unique ID, storing the complaint in memory, etc. But, all these complexities are hidden away using the façade pattern.

Facade Pattern

Flyweight Pattern

This is a structural design pattern focused on efficient data sharing through fine-grained objects. It is used for efficiency and memory conservation purposes.

This pattern can be used for any kind of caching purposes. In fact, modern browsers use a variant of a flyweight pattern to prevent loading the same images twice.

In this example, we create a fine-grained flyweight class Icecream for sharing data regarding ice-cream flavours and a factory class IcecreamFactory to create those flyweight objects. For memory conservation, the objects are recycled if the same object is instantiated twice. This is a simple example of flyweight implementation.

Flyweight Pattern

Proxy Pattern

This is a structural design pattern that behaves exactly as its name suggests. It acts as a surrogate or placeholder for another object to control access to it.

It is usually used in situations in which a target object is under constraints and may not be able to handle all its responsibilities efficiently. A proxy, in this case, usually provides the same interface to the client and adds a level of indirection to support controlled access to the target object to avoid undue pressure on it.

The proxy pattern can be very useful when working with network request-heavy applications to avoid unnecessary or redundant network requests.

In this example, we will use two new ES6 features, Proxy and Reflect. A Proxy object is used to define custom behaviour for fundamental operations of a JavaScript object (remember, function and arrays are also object in JavaScript). It is a constructor method that can be used to create a Proxy object. It accepts a target object that is to be proxied and a handler object that will define the necessary customisation. The handler object allows for defining some trap functions like get , set , has , apply , etc. that are used to add custom behaviour attached to their usage. Reflect , on the other hand, is a built-in object that provides similar methods that are supported by the handler object of Proxy as static methods on itself. It is not a constructor; its static methods are used for intercept-able JavaScript operations.

Now, we create a function that can be thought of as a network request. We named it as networkFetch . It accepts a URL and responds accordingly. We want to implement a proxy where we only get the response from the network if it is not available in our cache. Otherwise, we just return a response from the cache.

The cache global variable will store our cached responses. We create a proxy named proxiedNetworkFetch with our original networkFetch as the target and use apply method in our handler object to proxy the function invocation. The apply method gets passed on the target object itself. This value as thisArg and the arguments are passed to it in an array-like structure args .

We check if the passed url argument is in the cache. If it exists in the cache, we return the response from there, never invoking the original target function. If it does not, then we use the Reflect.apply method to invoke the target function with thisArg (although it’s not of any significance in our case here) and the arguments it passed.

Proxy Pattern

Chain of Responsibility Pattern

This is a behavioural design pattern that provides a chain of loosely coupled objects. Each of these objects can choose to act on or handle the request of the client.

A good example of the chain of responsibility pattern is the event bubbling in DOM in which an event propagates through a series of nested DOM elements, one of which may have an “event listener” attached to listen to and act on the event.

In this example, we create a class CumulativeSum , which can be instantiated with an optional initialValue . It has a method add that adds the passed value to the sum attribute of the object and returns the object itself to allow chaining of add method calls.

This is a common pattern that can be seen in jQuery as well, where almost any method call on a jQuery object returns a jQuery object so that method calls can be chained together.

Chain of Responsibility Pattern

Command Pattern

This is a behavioural design pattern that aims to encapsulate actions or operations as objects. This pattern allows loose coupling of systems and classes by separating the objects that request an operation or invoke a method from the ones that execute or process the actual implementation.

The clipboard interaction API somewhat resembles the command pattern. If you are a Redux user, you have already come across the command pattern. The actions that allow the awesome time-travel debugging feature are nothing but encapsulated operations that can be tracked to redo or undo operations. Hence, time-travelling made possible.

In this example, we have a class called SpecialMath that has multiple methods and a Command class that encapsulates commands that are to be executed on its subject, i.e. an object of the SpecialMath class. The Command class also keeps track of all the commands executed, which can be used to extend its functionality to include undo and redo type operations.

Command Pattern

Iterator Pattern

It is a behavioural design pattern that provides a way to access the elements of an aggregate object sequentially without exposing its underlying representation.

Iterators have a special kind of behaviour where we step through an ordered set of values one at a time by calling next() until we reach the end. The introduction of Iterator and Generators in ES6 made the implementation of the iterator pattern extremely straightforward.

We have two examples below. First, one IteratorClass uses iterator spec, while the other one iteratorUsingGenerator uses generator functions.

The Symbol.iterator ( Symbol —a new kind of primitive data type) is used to specify the default iterator for an object. It must be defined for a collection to be able to use the for...of looping construct. In the first example, we define the constructor to store some collection of data and then define Symbol.iterator , which returns an object with next method for iteration.

For the second case, we define a generator function passing it an array of data and returning its elements iteratively using next and yield . A generator function is a special type of function that works as a factory for iterators and can explicitly maintain its own internal state and yield values iteratively. It can pause and resume its own execution cycle.

Iterator Pattern

Mediator Pattern

It is a behavioural design pattern that encapsulates how a set of objects interact with each other. It provides the central authority over a group of objects by promoting loose coupling, keeping objects from referring to each other explicitly.

In this example, we have TrafficTower as Mediator that controls the way Airplane objects interact with each other. All the Airplane objects register themselves with a TrafficTower object, and it is the mediator class object that handles how an Airplane object receives coordinates data of all the other Airplane objects.

Mediator Pattern

Observer Pattern

It is a crucial behavioural design pattern that defines one-to-many dependencies between objects so that when one object (publisher) changes its state, all the other dependent objects (subscribers) are notified and updated automatically. This is also called PubSub (publisher/subscribers) or event dispatcher/listeners pattern. The publisher is sometimes called the subject, and the subscribers are sometimes called observers.

Chances are, you’re already somewhat familiar with this pattern if you have used addEventListener or jQuery’s . on to write even-handling code. It has its influences in Reactive Programming (think RxJS) as well.

In the example, we create a simple Subject class that has methods to add and remove objects of Observer class from subscriber collection. Also, a fire method to propagate any changes in the Subject class object to the subscribed Observers. The Observer class, on the other hand, has its internal state and a method to update its internal state based on the change propagated from the Subject it has subscribed to.

Observer Pattern

State Pattern

It is a behavioural design pattern that allows an object to alter its behaviour based on changes to its internal state. The object returned by a state pattern class seems to change its class. It provides state-specific logic to a limited set of objects in which each object type represents a particular state.

We will take a simple example of a traffic light to understand this pattern. The TrafficLight class changes the object it returns based on its internal state, which is an object of Red , Yellow , or Green class.

State Pattern

Strategy Pattern

It is a behavioural design pattern that allows encapsulation of alternative algorithms for a particular task. It defines a family of algorithms and encapsulates them in such a way that they are interchangeable at runtime without client interference or knowledge.

In the example below, we create a class Commute for encapsulating all the possible strategies for commuting to work. Then, we define three strategies namely Bus , PersonalCar , and Taxi . Using this pattern we can swap the implementation to use for the travel method of the Commute object at runtime.

Strategy Pattern

Template Pattern

This is a behavioural design pattern based on defining the skeleton of the algorithm or implementation of an operation, but deferring some steps to subclasses. It lets subclasses redefine certain steps of an algorithm without changing the algorithm’s outward structure.

In this example, we have a Template class Employee that implements work method partially. It is for the subclasses to implement responsibilities method to make it work as a whole. We then create two subclasses Developer and Tester that extend the template class and implement the required method to fill the implementation gap.

Template Pattern

Conclusion

Design patterns are crucial to software engineering and can be very helpful in solving common problems. But this is a very vast subject, and it is simply not possible to include everything about them in a short piece. Therefore, I made the choice to shortly and concisely talk only about the ones I think can be really handy in writing modern JavaScript. To dive deeper, I suggest you take a look at these books: