So far in this series, we've covered the underlying web components standards, the legacy-browser polyfills, and their implementation with vanilla javascript and a wide variety of different helper libraries.

Today, we're going to review some pernicious myths about web components and their use which seem to have cropped up lately. Many of these misconceptions are understandable, considering how young the technology is, and how the shift from the v0 web components spec to v1 with its wide adoption has changed the landscape considerably, and for the better.

Let's shine a little light on the web's own component model and learn how they make development easier and improve the experience of users, developers, and managers.

Myth: Web Components Aren't Supported By Browsers

Sometimes a picture is worth 1024 words:





This screenshot was taken from https://webcomponents.org with Firefox version 65.0.1 in February 2019. It shows that all major browsers support web components specifications, with Edge soon-to-deliver support sans-polyfills. (Web Components can also be made to be supported down to IE11, but you shouldn't do that)



But isn't the proof of the pudding in the eating... or... the proof of the platform API in the deploying? If web components were not supported, we wouldn't expect to see them in the wild, and certainly not in use by large teams. However: Twitter, GitHub, dev.to, McDonalds, Salesforce, ING (PDF link), SAP, and many others all use web components in public-facing, core-business pages. In my day job at Forter, we use web components. In fact, in 2018, 10% of all reported Chrome page loads used web components.

Clearly, web components are not just a potentially-interesting future technology. They are in use, by you and users like you, on the web today.

Myth: Web Components Can't Accept Complex Data

I've seen the claim recently that web components are limited to accepting their data as strings, and therefore can't take complex objects. This misconception is particularly insidious because, like any good lie, it's half true. This misguided notion stems from a fundamental misunderstanding of the DOM and how it works.

Here follows a brief review. Feel free to Skip it if you're OK with DOM vs. HTML / attrs vs. props.

<input id= "text-input" placeholder= "Enter Your Text" />

HTML Elements and attributes are part of the HTML specification, and roughly form the D part of the DOM or Document Object Model. In the example above the <input> element has two attributes, id with the value "text-input" and placeholder with the value "Enter Your Text". Since HTML documents are by definition strings and only strings, both the attribute names and their values are strings and only strings.

When the browser parses a document, it creates JavaScript objects corresponding to each HTML element, initializing some of that object's properties with the values found at the corresponding attributes. This tree of objects comprises the OM in DOM . Properties exist on JavaScript objects.

Here's a pseudocode example of the DOM node for our input:

Object HTMLInputElement { tagName : ' INPUT ' , placeholder : ' Enter Your Text ' , id : ' text-input ' ... }

Strictly speaking, elements can have attributes but they can't have properties, because elements are part of a document, not a DOM tree. What I mean by that is that the DOM for a given page is not the same as the HTML for that page; rather, the DOM is derived from the HTML document.

You can inspect any DOM node's properties in the dev tools elements/inspector panel. Chrome shows all DOM properties in the properties tab (look next to CSS rules), Firefox shows them under the Show DOM Properties context menu. You could also evaluate $0 while inspecting a node, or use the DOM APIs, e.g. document.querySelector('my-element').someProp ;

In the case of our fledgling input, the DOM object's id property is text-input .

const input = document . getElementById ( ' text-input ' ); console . log ( input . id ); // 'text-input' console . log ( input . getAttribute ( ' id ' )); // 'text-input' input . id = ' by-property ' ; console . log ( input . getAttribute ( ' id ' )); // 'by-property' input . setAttribute ( ' id ' , ' by-attribute ' ); console . log ( input . id ); // 'by-attribute'

For many attribute/property pairs, changes to one are reflected in the other, but not for all of them. For example, an HTMLInputElement 's value property represents the current value, whereas the value attribute only represents the initial value.



Back to our story

It seems some developers have reasoned thus:

Attributes can only be strings HTML elements only have attributes and no properties Custom Elements are HTML elements Therefore web components can only accept strings in attributes

This reasoning would hold in a world where everyone disables JavaScript 100% of the time, but we don't live in such a world. In our world, the DOM is a rich and well-utilized part of the web platform.

Custom Elements are indeed HTML elements tied to the document, but they are also DOM nodes, swinging from the branches of the DOM tree. They can have semantic string attributes, but they can also accept complex nested data as properties, using JavaScript and the DOM.

Here's an example of how you might accomplish that using only the DOM API:

const input = document . createElement ( ' country-input ' ); input . countries = [ { name : ' Afghanistan ' , dialCode : ' +93 ' , countryCode : ' AF ' }, { name : ' Albania ' , dialCode : ' +355 ' , countryCode : ' AL ' }, /* ... */ ];

So - do web components only accept strings? Poppycock! Balderdash! Flimshaw! The full expressive power of the DOM is available to your custom elements from day one.

And if you think you're limited to using the bare DOM APIs to set those properties... think again!

Myth: Web Components Have No Way Of Templating

Like the previous myth, this misconception has one foot in the truth. The most widely adopted web component spec is the <template> element, used for efficient static templating, and it's available across all evergreen browsers. The type of templating I want to talk about in this post uses what you might call "dynamic templates" or templates with variable parts.

<template id= "person-template" > <figure> <img alt= "{{picture.alt}}" src= "{{picture.src}}" /> <figcaption> {{name}} </figcaption> </figure> </template>

We'll start by discussing some proposed features, then show some examples you can run today.

Template Instantiation is a proposed web components spec that offers a future means to define DOM templates with slots for dynamic content. It will hopefully soon let us write declarative templates for our custom elements. The following maquette illustrates how that might look in practice:

<template type= "with-for-each" id= "list" > <ul> {{foreach items}} <li class= {{ type }} data-value= {{value}} > {{label}} </li> {{/foreach}} </ul> </template> <script> const list = document . getElementById ( ' list ' ); customElements . define ( ' awesome-web-components ' , class extends HTMLElement { # items = [ { type : ' description ' , value : ' awesome ' , label : " Awesome!! " }, { type : ' technology ' , value : ' web-components ' , label : " Web Components!! " } ]; template = list . createInstance ({ items : this . # items }); constructor () { super (); this . attachShadow ({ mode : ' open ' }); this . shadowRoot . appendChild ( this . template ); } set items ( items ) { this . # items = items ; this . template . update ( items ); } get items () { return this . # items ; } }); </script>

Note, I'm purposefully handwaving over the implementation of with-for-each here. This example is only to whet the appetite. See the proposal for more.

Template Instantiation will be hella-useful when it lands, but at the moment, we need to rely on libraries.

Does that mean that web components have no way of templating? Preposterous! There are a variety of approaches and libraries available, from lit-html, HyperHTML, or hybrids; to slim.js or svelte, and more.

A few examples to illustrate the point:

Templating with lit-html

import { LitElement , html } from ' lit-element ' ; const itemTemplate = ({ value , label , type }) => html ` <li class= ${ type } data-value= ${ value } > ${ label } </li>` customElements . define ( ' awesome-web-components ' , class extends LitElement { items = [ /* ... */ ] render () { return html `<ul> ${ items . map ( itemTemplate )} </ul>` ; } });

Templating with hybrids

import { define , html } from ' hybrids ' ; const itemTemplate = ({ value , label , type }) => html ` <li class= ${ type } data-value= ${ value } > ${ label } </li>` ; define ( ' awesome-web-components ' , { items : { get : () => [ /*...*/ ] }, render : ({ items }) => html `<ul> ${ items . map ( itemTemplate )} </ul>` });

Templating with Slim.js

import { Slim } from ' slim-js ' ; import { tag , template } from ' slim-js/Decorators ' ; import ' slim-js/directives/repeat.js ' @ tag ( ' awesome-web-components ' ) @ template ( ` <ul> <li s:repeat="items as item" bind:class="item.type" bind:data-value="item.value"> {{ item.label }} </li> </ul>` ) class MyTag extends Slim { onBeforeCreated () { this . items = [ /*...*/ ] } }

Templating with Svelte

<ul> {#each items as item} <li class= "{item.type}" data-value= "{item.value}" > {item.label} </li> {/each} </ul> <script> export default { data () { return { items : [ /*...*/ ] } } } </script>

It's worth mentioning at this point that some of these examples illustrate approaches that use build-time transpilation to render your templates (svelte in particular). But you aren't limited to that; hybrids, lit-element, and others run dynamic templates in the browser. You could paste the lit-element example (with some small modifications to resolve bare module specifiers) into the browser console and it would work.

With many of the various templating methods, you can also declaratively pass complex data as properties:

import { html } from ' lit-html ' ; const propPassingTemplate = html ` <takes-complex .data= ${{ like : { aTotal : [ ' boss ' ] } }}></takes-complex>` ;

So, can you write dynamic, declarative templates? Web components offer a straightforward templating story, without the hard requirement of a transpilation step. Moreover, there are plenty of different opinionated approaches in the ecosystem with more appearing as these standards gain notoriety.

Myth: Web Components Can't be Server-Side-Rendered

Server-side rendering is a technique whereby client-side javascript (or something like it) is executed on the server when a request comes in, generating an initial response containing content that would otherwise be unavailable until the aforementioned client-side code was downloaded, parsed, and executed. There are, generally speaking, two reasons why you would implement server-side rendering:

To make your app's pages indexable by search engines that might not run JavaScript To reduce the time to first contentful paint

Can you accomplish these goals in a web-components app? Indubitably.

You can use Google's puppeteer (which runs headless Chrome or Firefox on your server) to render the contents of your components for the sake of web crawlers. The inimitable captaincodeman has a fully-realized example of SSR -for- SEO written in Go.

So there are ways to run your custom elements-based client side JS on the server for SEO purposes. What about reducing load times?

Well, it seems that the jury is out regarding whether or not running your templates server-side is faster in the first place. If the goal is to reduce FCP times, you might instead opt to calculate your data at request time, while factoring your client-side app with a lightweight static app shell. In this flavour of SSR, you have some server-side code which computes an initial state, à la this example from an Apollo Elements GraphQL app:

async function ssr ( file , client ) { // Instantiate a version of the client-side JS on the server. const cache = new InMemoryCache (); const link = new SchemaLink ({ schema : server . schema , context }); const client = new ApolloClient ({ cache , link , ssrMode : true }); // Calculate the initial app state. await client . query ({ query : initialQuery }); const serializedState = JSON . stringify ( client . extract ()); // Inject said state into the app with a static `<script>` tag const dom = await JSDOM . fromFile ( file ); const script = dom . window . document . createElement ( ' script ' ); script . innerHTML = `window.__APOLLO_STATE__ = ${ serializedState } ` ; dom . window . document . head . append ( script ); // Send the modified index.html to the client return dom . serialize (); } app . get ( /^ (?! .* (\.) | ( graphi ? ql ) .* ) / , async function sendSPA ( req , res ) { // SSR All the Things const index = path . resolve ( ' public ' , ' index.html ' ); const body = await ssr ( index , client ); // 👯‍♀️👯‍♂️ res . send ( body ); });

Doing the same for a different state container like redux is left as an exercise for the reader. (or, like... google it)

You'll note that none of this code is specific to web components or any specific templating library. When your components upgrade and connect to their state container, they'll get their properties and render according to whatever the implementation.

There's a lot more to say on this issue, and the story will only improve in the near term, as the lit-html team have prioritized work on SSR for 2019. I don't mind telling you, dear reader, that I'm not an expert. Give Trey Shugart, Kevin P Schaaf, and Justin Fagnani a follow if you want the low-down.

So, can you SSR all the things in your web components app? Well, don't expect any turn-key solutions here. It's early days, and the cowpaths are still quite fresh. Nonetheless, basic facilities are in use in production today, and there's a lot to look forward to coming up soon. But is it possible? Sure!

tl;dr : the techniques and libraries are still very early, but it's certainly possible to accomplish the goals of SSR in wc-based apps.

All right, I'm calling it.

Myth: Web Components are a Proprietary Google Technology

While the modern web components story began at Google (at a secret seance in the basement of one of their datacenters, I'm told 👻), it's grown beyond the bounds of any one company.

To wit:

The HTML Modules proposal was taken up by Microsoft.

The Template Instantiation proposal was tabled by Apple. (For the yanks, 'tabled' means 'offered for consideration')

The VSCode Team is leading the charge to standardize IDE tools for web components.

open-wc (caveat: I'm a contributor) is a community project not associated with any of the big players.

Web Components specs are open standards with multiple implementations and stakeholders.

Myth: You Need Polymer to Use Web Components

This is a fun one. Back in the dark ages of 2013, the only way to use 'web components' was to use the polymer library, which back then functioned as a combination polyfill/templating system/build tool/package manager/kitchen sink. The reason for this was simple: The Polymer Project invented the modern notion of web components, and the Polymer library (version 0) was their prototype implementation.

Since then, things have changed drastically. The polyfills split off from the Polymer library and its opinionated templating system years ago, and are now in use by many independent projects.

If this is news to you, give a quick read to the first part of my Polymer Library post, which clarifies the difference between the Polymer Project and the Polymer Library.

So, no, you don't need Polymer to use web components. You don't even need the Polyfills if you're only supporting evergreen browsers (minus Edge until Edgeium ships)

Want proof? Open a new tab in Chrome, Firefox, or Safari and paste this snippet into the console:

customElements . define ( ' the-proof ' , class extends HTMLElement { constructor () { super (); this . attachShadow ({ mode : ' open ' }); this . shadowRoot . innerHTML = ` <style>:host { display: block; }</style> You just used web components without Polymer ` ; } }); document . body . innerHTML = ` <the-proof>You Can't use web components without Polymer!!</the-proof> ` ;

tl;dr : The polyfills are independent, and the Polymer project even recommends not using the Polymer library for new projects.

Myth: You Need to Use HTML Imports

One of the things that drew me in to web components back in 2015 was the notion of writing sophisticated components in HTML files. The now-defunct HTML Imports specification let us do just that, and here's how it looked:

<link rel= "import" href= "/my-component.html" > <my-component></my-component>

HTML Imports struck a chord with many developers, as it signalled a return to a document-centric approach to web development, as opposed to the 'modern', script-centric approach, to which many of us find ourselves obliged nowadays. That's why, for many of us in the web components community, it was bittersweet when the HTML Imports specification was deprecated in favour of modules.

Yup, you read that right. HTML Imports are not a thing.1

Nowadays, web component and app authors are most likely to use JavaScript modules to package and import their components:

<script type= "module" src= "/my-component.js" ></script> <my-component></my-component>

This approach opens the door to the huge assortment of tooling options we have out there, and means you don't need to use Polymer tools for your projects.

But you're not limited to modules either: <good-map> is a vanilla web component wrapper for Google Maps which is distributed as a script instead of as a module. If you visit that repo, and I hope you do, don't be alarmed by the (optional) legacy HTML import, or by the fact that the last update was two years ago, the web components specs mean it still works just fine.

tl;dr : Not only are HTML Imports unnecessary, but you actually shouldn't use them in your projects.

Myth: You Need to Use Shadow DOM

This is one of the easiest myths to bust. Used GitHub lately? You've used web components without Shadow DOM. Open a tab to https://github.com in your favourite evergreen browser and paste this snippet in the console:

const isCustomElement = ({ tagName }) => tagName . includes ( ' - ' ); const usesShadowDom = ({ shadowRoot }) => !! shadowRoot ; const allElements = Array . from ( document . querySelectorAll ( ' * ' )) console . log ( " All Custom Elements " , allElements . filter ( isCustomElement )); console . log ( " Uses Shadow Dom " , allElements . filter ( usesShadowDom ));

Shadow DOM is the secret sauce of web components and I highly recommend you use it to the fullest extent. However, there are times when you might not want to encapsulate all of a component's styles against the rest of the document2. For those instances, it's simple to avoid the use of Shadow DOM - just don't opt in!

Here's a simple copypastable example:

customElements . define ( ' without-shadow ' , class extends HTMLElement { constructor () { super (); // no call to `this.attachShadow` this . innerHTML = `<p>A Custom Element Without Shadow DOM</p>` this . style . color = ' rebeccapurple ' ; } }); document . body . innerHTML = `<without-shadow></without-shadow>` ;

So, while I think you should use Shadow DOM, it's nice to know that you don't have to.

Myth: You Need Frameworks to Write Apps

You might have heard tell that "web components are great for leaf nodes like buttons, but you need frameworks to build real apps" or some such argument. It's certainly the case that if you're building a leaf node like a checkbox or a card, web components are the hands-down favourite (see next myth), but what you might not know is that you can indeed build entire apps with them.

I built a demo app using Apollo GraphQL and web components that scores well in lighthouse. Then there's the pwa-starter-kit example app. It uses web components with redux3 to manage state, has client-side routing, integration tests, and all that app-y goodness. At Forter, we're building prototypes and internal apps without frameworks, and the results so far are very positive.

And there are many more examples. (Ever wonder which JS framework GitHub uses?)

Now, I happen to think it's just as wrong-headed to say you should never use frameworks as it is to say that you always need one. There's nothing inherently wrong with frameworks. A Framework might be the right choice for your project, but don't let anyone ever tell you that you need one to write web apps.

tl;dr : Frameworks are great, but they're not absolute requirements, even for cutting edge workflows.

Myth: You Can't Use Web Components in Frameworks

This one's a quicky. All it takes to dispel it is 10 seconds scrolling through https://custom-elements-everywhere.com

Even the frameworks with the worst custom elements support are slowly but surely working on improving the situation, and workarounds are available.

tl;dr : Web components 💓love💓 frameworks.

Myth: The Web Community Has Moved on From Web Components

If you've read the whole post up till now, you might be scratching your head thinking "isn't this obvious?" And yet, judging by the amount of internet noise claiming that WC is dead, it bears some fleshing out.

We've already seen how organizations large and small are shipping web components. We've seen how you yourself probably used web components on popular websites within the last hour. We've seen how >10% of page loads across all browsing sessions load a page with a custom element in it. And all of that is just the beginning.

In 2018, there was a veritable Cambrian Explosion of new ideas and shipped code in the web components world - from Firefox shipping full support in version 63 to Edge announcing intent-to-ship, to innovative library releases like hybrids and haunted (think React hooks for web components), to projects like Angular Elements which improve the already formidable interop story between elements and frameworks. We're not talking about browser-implementers pontificating from behind their compilers! As we've seen above, there's been tremendous adoption from developers themselves at companies large and small, and among community volunteers.

So what should we make of the sometimes-insistent voices who claim that "web components just aren't there yet?"

Conclusion

If you've been waiting for web components to "arrive" before trying your hand at them, I'm giving you permission right now. It's an exciting time to be a web developer, and the future is only looking brighter.

Web components let us write and publish reusable pieces of web content and compose modular apps with increasingly small dependency and tool chains. If you haven't given this refreshing style of development a try, I hope you will soon.

Acknowledgements

Many people helped me write this post, and I'm very grateful.

Thanks in no particular order for generously offering their notes on this post go to westbrook, Dzintars, stramel, Thomas, tpluscode, and Corey Farell on the Polymer Slack; as well as lars, Passle, and daKmoR from the open-wc team; Dan Luria (who described this post as a 'brunch cocktail - both delightful and progressively more challenging') on the WeAllJS slack; my good friend Justin Kaufman; and my dear wife Rachel.

Endnotes