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How I built a modern website in 2021

September 29th, 2021 — 34 min read

MacBook Pro on top of brown table
MacBook Pro on top of brown table

For over half of 2021, I worked on a complete rewrite of kentcdodds.com. You're reading this on the rewrite of this site! Are you using dark mode or light mode? Have you signed in and selected your team yet? Have you tried to call into the Call Kent Podcast? This blog post isn't about these and other features of the new site, but how I built it. There's too much to dive deep in a single blog post. I just want to give you an overview of the technologies and libraries I used to make this experience for you.

If you haven't read it already, get a higher-level overview of what this website can do for your learning and advancement as a software engineer by reading Introducing the new kentcdodds.com first.

I've migrated from Postgres/Redis to SQLite. Read about that in the post I Migrated from a Postgres Cluster to Distributed SQLite with LiteFS.

Context

Before we get too far into this I want to make my one thing clear. If this was a simple developer's blogfolio site, my tech choices could be labeled as over-engineering and I would agree. However, I wanted to build an above and beyond experience, so I had to make thoughtful architectural decisions. What I'm doing on this site could definitely not be done with wordpress and a CDN 😆

If you're a beginner looking for how to build your personal website, this blog post is definitely not the place to learn that. If I were to build a simple personal website, I would still use Remix.run, but I would probably have it running on netlify serverless functions and write the content as markdown which has built-in support in Remix. That would be drastically simpler.

But again, that's not what kentcdodds.com is. If you're interested in how to productively build a maintainable website using modern tools that is fast all over the world despite every user getting content that's completely unique to them, then please continue.

Oh, and one more thing to give context on what this site can do:

Stats overview

First, to give you an idea of the scale we're talking here. So here are a few stats:

At the time of this writing (October 2021) here are the cloc stats:

$ npx cloc ./app ./types ./tests ./styles ./mocks ./cypress ./prisma ./.github
     266 text files.
     257 unique files.
      15 files ignored.

github.com/AlDanial/cloc v 1.90  T=0.16 s (1601.9 files/s, 194240.7 lines/s)
-------------------------------------------------------------------------------
Language                     files          blank        comment           code
-------------------------------------------------------------------------------
TypeScript                     219           2020            583          21582
CSS                             10            198            301           4705
JSON                             7              0              0            609
YAML                             2             43             13            232
SQL                              7             20             25             52
JavaScript                       4              2              3             42
Markdown                         1              0              0              2
TOML                             1              0              2              1
-------------------------------------------------------------------------------
SUM:                           251           2283            927          27225
-------------------------------------------------------------------------------

And to get a sense of the amount of content I have on this site, here's a word count:

$ find ./content -type f | xargs wc -w | tail -1
  280801 total

That's more than the first three Harry Potter books combined.

And adding up the amount of content on the four seasons of the Chats with Kent Podcast comes to about 35 hours of content + the ever-growing 3 hours of content on the brand new Call Kent Podcast which incidentally is also more than it takes to listen to Jim Dale read the first three Harry Potter books (unless you listen at 3x like me #subtlebrag 🙃).

27k lines of code isn't like your work project where a half dozen teams have been contributing code for the last 8 years or anything, but it's nothing like your blogfolio site either. This is a legit full-stack web application with a database, cache, user accounts, etc. I'm fairly confident that this is the biggest Remix application in existence at the moment.

I didn't do this whole thing by myself. You can check out the credits page for details on contributors. I was the primary code contributor and I made all the architecture decisions (and mistakes? only time will tell 😅) for the site.

The first commit was in November 2020. Most development has taken place in the last 4-5 months. There are ~945 commits so far 🤯.

GitHub contributor graph

Technology overview

Here are the primary technologies used in this project (in no particular order):

  • React: For the UI
  • Remix: Framework for the Client/Server/Routing
  • TypeScript: Typed JavaScript (necessary for any project you plan to maintain)
  • XState: State machine tool making complex component state management simple
  • Prisma: Fantastic ORM with stellar migrations and TypeScript client support
  • Express: Node server framework
  • Cypress: E2E testing framework
  • Jest: Unit/Component testing framework
  • Testing Library: Simple utilities for testing DOM-based user interfaces
  • MSW: Fantastic tool for mocking HTTP requests in the browser/node
  • Tailwind CSS: Utility classes for consistent/maintainable styling
  • Postcss: CSS processor (pretty much just use it for autoprefixer and tailwind)
  • Reach UI: A set of accessible UI components every app needs (accordion/tabs/dialog/etc...)
  • ESBuild: JavaScript bundler (used by Remix and mdx-bundler).
  • mdx-bundler: Tool for compiling and bundling MDX for my site content (blog posts and some simple pages).
  • Octokit: Library making interacting with the GitHub API easier.
  • Framer Motion: Great React Animation library
  • Unified: Markdown/HTML parser/transformer/compiler system.
  • Postgres: Battle tested SQL database
  • Redis: In-memory database–key/value store.

Here are the services this site uses:

  • Fly.io: Super hosting platform
  • GitHub Actions: Hosted CI pipeline service
  • Sentry: Error reporting service
  • Cloudinary: Fantastic image hosting and transformation service.
  • Fathom: Privacy-focused ethical analytics service.
  • Metronome: Remix metrics service

Architectural overview

Deployment pipeline

Excalidraw diagram of a deployment pipeline

I think it can be quite instructive of overall architecture to describe how an app is deployed. The Excalidraw diagram above describes it visually. Allow me to describe it in written form as well:

First, I commit a change to the local repo. Then I push my changes to the (open source) GitHub repository. From there, I have two GitHub Actions that run automatically on every push to the main branch.

The "Discord" circle just indicates that I've got a GitHub webhook installed for discord so each success/failure will result in a message in a channel on discord so I can easily keep track of how things are going at any time.

GitHub Actions: 🥬 Refresh Content

The first GitHub action is called "🥬 Refresh Content" and is intended to refresh any content that may have changed. Before describing what it does, let me explain the problem it solves. The previous version of kentcdodds.com was written with Gatsby and due to the SSG nature of Gatsby every time I wanted to make a content change, I would have to rebuild my entire site (which could take anywhere from 10-25 minutes).

But now that I have a server and I'm using SSR, I don't have to wait for a complete rebuild to refresh my content. My server can access all the content directly from GitHub via the GitHub API. The problem is that this adds a lot of overhead to each request for my blog posts. Add to that time to compile the MDX code and you've got yourself a really slow blog. So I've got myself a Redis cache for all of this. The issue then is the problem of caches: invalidation. I need to make sure that when I make an update to some content, the Redis cache gets refreshed.

And that's what this first GitHub action does. First it determines all content changes that occurred between the commit that's being built and the commit of the last time there was a refresh (that value is stored in redis and my server exposes an endpoint for my action to retrieve it). If any of the changed files were in the ./content directory, then the action makes an authenticated POST request to another endpoint on my server with all the content files that were changed. Then my server retrieves all the content from the GitHub API, recompiles the MDX pages, and pushes the update to the Redis cache which Fly.io automatically propagates to the other regions.

This reduces what used to take 10-25 minutes down to 8 seconds. And it saves me computational resources as well because fixing a typo in my content doesn't necessitate a rebuild/redeploy/cache bust of the whole site.

I realize that using GitHub as my CMS is a little odd, but wonderful people like you contribute improvements to my open source content all the time and I appreciate that. So by keeping things in GitHub, that can continue. (Note the edit link at the bottom of every post).

GitHub Actions: 🚀 Deploy

The second GitHub action deploys the site. First, it determines whether the changes are deployable to begin with. If the only thing that changed was content, then there's no reason to bother redeploying thanks to the refresh content action. The vast majority of my commits on my old site were content-only changes so this helps save the trees 🌲🌴🌳

Once it's determined that we have deployable changes, then we kick off multiple steps in parallel:

  • ⬣ ESLint: Linting the project for simple mistakes
  • ʦ TypeScript: Type checking the project for type errors
  • 🃏 Jest: Running component and unit tests
  • ⚫️ Cypress: Running end-to-end tests
  • 🐳 Build: Building the docker image

The Cypress step is further parallelized by splitting my E2E tests into three individual containers which split the tests between them to run them as quickly as possible.

You might notice that there are no arrows coming out of the Cypress step. This is intentional and temporary. Currently I do not fail the build if the E2E tests fail. So far, I haven't been worried about deploying something that's broken and I didn't want to hold up a deploy because I accidentally busted something for the 0 users who expect things to be working. The E2E tests are also the slowest part of the deployment pipeline and I want to get things deployed quickly. Eventually I'll probably care more about whether I break the site, but for now I'd rather have things deploy faster. I do know when those tests fail.

Once ESLint, TypeScript, Jest, and the Build all successfully complete, then we can move on to the deploy step. On my end this bit is simple. I simply use the Fly CLI to deploy the docker container that was created in the build step. From there Fly takes care of the rest. It starts up the docker container in each of the regions I've configured for my Node server: Dallas, Santiago, Sydney, Hong Kong, Chennai, and Amsterdam. When they're ready to receive traffic, Fly switches traffic to the new instance and then shuts down the old one. If there's a startup failure in any region, it rolls back automatically.

Additionally, this step of the deploy uses prisma's migrate feature to apply any migrations I've created since the last migration (it stores info on the last migration in my Postgres DB). Prisma performs the migration on the Dallas instance of my Postgres cluster and Fly automatically propagates those changes to all other regions instantly.

And that's what happens when I say: git push or click the "Merge" button 😄

Database Connectivity

Excalidraw diagram of a databases in different regions

One of the coolest parts of Fly.io (and the reason I chose Fly over alternative Node server hosts) is the ability to deploy your app to multiple regions all over the world. I've chosen 6 based on the analytics from my previous site, but they have many more.

Deploying the Node server to multiple regions is only part of the story though. To really get the network performance benefits of colocation, you need your data to be close by as well. So Fly also supports hosting Postgres and Redis clusters in each region as well. This means when an authorized user in Berlin goes to The Call Kent Podcast, they hit the closest server to them (Amsterdam) which will query the Postgres DB and Redis cache that are located in the same region, making the whole experience extremely fast wherever you are in the world.

What's more, I don't have to make the trade-off of vendor lock-in. At any time I could take my toys home and host my site anywhere else that supports deploying Docker. This is why I didn't go with a solution like Cloudflare Workers and FaunaDB. Additionally, I don't have to retrofit/limit my app to the constraints of those services. I'm extremely happy with Fly and don't expect to leave any time soon.

But that doesn't mean this is all trade-off free (nothing is). All of this multi-regional deployment comes with the problem of consistency. I've got multiple databases, but I don't want to partition my app by region. The data should be the same in all those databases. So how do I ensure consistency? Well, we choose one region to be our primary region, and then make all other regions read-only. Yup, so the user in Berlin won't be able to write to the database in Amsterdam. But don't worry, all instances of my Node server will make a read connection to the closest region so reads (by far the most common operation) are fast, and then they also create a write connection to the primary region so writes can work. And as soon as an update happens in the primary region, Fly automatically and immediately propagates those changes to all other regions. It's very very fast and works quite well!

Fly makes doing this quite easy and I'm super happy with it. That said, there's one other problem this creates that we need to deal with.

Fly Request Replays

Excalidraw diagram of a user POST request made to different regions being routed to the primary region

One problem with the read/write connections I use to make multi-regional deployment super fast is that if our friend in Berlin writes to the database and then reads the data they just wrote, it's possible they will read the old data before Fly has finished propagating the update. Data propagation normally happens in milliseconds, but in cases where the data is large (like when you submit a recording to The Call Kent Podcast), it's quite possible your next read will beat Fly.

One way to avoid this problem is to make sure that once you've done a write, the rest of the request performs its reads against the primary database. Unfortunately this makes the code a bit complex.

Another approach Fly supports is to "replay" a request to the primary region where the read and write connections are both on the primary region. You do this by sending a response to the request with the header fly-replay: REGION=dfw and Fly will intercept that response, prevent it from going back to the user, and replay the exact same request to the region specified (dfw is Dallas which is my primary region).

So I have a middleware in my express app that simply automatically replays all non-GET requests. This does mean that those requests will take a bit longer for our friend in Berlin, but again, those requests don't happen very often, and honestly I don't know of a better alternative anyway 🙃.

I'm really happy with this solution!

Local Development with MSW

When I'm developing locally, I have my postgres and redis databases running in a docker container via a simple docker-compose.yml. But I also interact with a bunch of 3rd party APIs. As of the time of this writing (September 2021), my app works with the following third party APIs:

  1. api.github.com
  2. oembed.com
  3. api.twitter.com
  4. api.tito.io
  5. api.transistor.fm
  6. s3.amazonaws.com
  7. discord.com/api
  8. api.convertkit.com
  9. api.simplecast.com
  10. api.mailgun.net
  11. res.cloudinary.com
  12. www.gravatar.com/avatar
  13. verifier.meetchopra.com

Phew! 😅 I'm a big believer in being able to work completely offline. It's fun to go up into the mountains with no internet connection and still be able to work on your site (and as I type this, I'm on an airplane without internet). But with so many 3rd party APIs how is this possible?

Simple: I mock it with MSW!

MSW is a fantastic tool for mocking network requests in both the browser and node. For me, 100% of my 3rd party network requests happen in Remix loaders on the server, so I only have MSW setup in my node server. What I love about MSW is that it's completely nonintrusive on my codebase. The way I get it running is pretty simple. Here's how I start my server:

node .

And here's how I start it with mocks enabled:

node --require ./mocks .

That's it. The ./mocks directory holds all my MSW handlers and initializes MSW to intercept HTTP requests made by the server. Now I'm not going to say it was easy writing the mocks for all of these services, it's a fair amount of code and took me a bit of time. But boy it's really helped me stay productive. My mock is much faster than the API and doesn't rely on my internet connection one bit. It's a huge win and I strongly recommend it.

For several of the APIs I have mocked, I'm just using faker.js to create random fake data that conforms to the types I've written for these APIs. But for the GitHub APIs, I actually happen to know what the response should be even if I'm not connected to the internet, because I'm literally working in the repository that I'll be requesting content from! So my GitHub API mock actually reads the filesystem and responds with actual content. This is how I work on my content locally. And I don't have to do anything fancy in my source code. As far as my app is concerned, I'm just making network requests for the content, but MSW intercepts it and lets me respond with what's on the file system.

To take it a step further, Remix auto-reloads the page when files change and I have things set up so whenever there's a change in the content, the redis cache for that content is automatically updated (yup, I use the redis cache locally too) and I trigger Remix to reload the page. If you can't tell, I think this whole thing is super cool.

And because I have this set up with MSW to work locally, I can make my E2E tests use the same thing and stay resilient. If I want to run my E2E tests against the real APIs, then all I have to do is not --require ./mocks and everything's hitting real APIs.

MSW is an enormous productivity and confidence booster for me.

Caching with Redis/LRU

As described earlier with the architecture diagrams, I host my redis cache with Fly.io. It's phenomenal. But I've built my own little abstraction for interacting with redis to have some interesting qualities that I think are worth talking about.

First, the problems: I want my site to be super fast, but I also want to do things on each request that take time. Some things I want to do could even be described as slow or unreliable. So I use Redis to cache things. This can take something that takes 350ms down to 5ms. However, with caching comes the complication of cache invalidation. I've described how I do this with my content, but I'm caching a lot more than that. Most of my 3rd party APIs are cached and even the results of a few of my Postgres queries are cached (Postgres is pretty fast, but on my blog I execute ~30 queries on every page).

Not everything is cached in Redis either, some things are cached via the lru-cache module (lru stands for "least-recently-used" and helps your cache avoid out of memory errors). I use the in-memory LRU cache for very short-lived cache values like the postgres queries.

With so many things that need to be cached, an abstraction was needed to make the invalidation process simpler and consistent. I was too impatient to find a library that would work for me, so I just built my own.

Here's the API:

type CacheMetadata = {
  createdTime: number
  maxAge: number | null
}
// it's the value/null/undefined or a promise that resolves to that
type VNUP<Value> = Value | null | undefined | Promise<Value | null | undefined>

async function cachified<
  Value,
  Cache extends {
    name: string
    get: (key: string) => VNUP<{
      metadata: CacheMetadata
      value: Value
    }>
    set: (
      key: string,
      value: {
        metadata: CacheMetadata
        value: Value
      },
    ) => unknown | Promise<unknown>
    del: (key: string) => unknown | Promise<unknown>
  },
>(options: {
  key: string
  cache: Cache
  getFreshValue: () => Promise<Value>
  checkValue?: (value: Value) => boolean
  forceFresh?: boolean | string
  request?: Request
  fallbackToCache?: boolean
  timings?: Timings
  timingType?: string
  maxAge?: number
}): Promise<Value> {
  // do the stuff...
}

// here's an example of the cachified credits.yml that powers the /credits page:
async function getPeople({
  request,
  forceFresh,
}: {
  request?: Request
  forceFresh?: boolean | string
}) {
  const allPeople = await cachified({
    cache: redisCache,
    key: 'content:data:credits.yml',
    request,
    forceFresh,
    maxAge: 1000 * 60 * 60 * 24 * 30,
    getFreshValue: async () => {
      const creditsString = await downloadFile('content/data/credits.yml')
      const rawCredits = YAML.parse(creditsString)
      if (!Array.isArray(rawCredits)) {
        console.error('Credits is not an array', rawCredits)
        throw new Error('Credits is not an array.')
      }

      return rawCredits.map(mapPerson).filter(typedBoolean)
    },
    checkValue: (value: unknown) => Array.isArray(value),
  })
  return allPeople
}

That's a lot of options 😶 But don't worry, I'll walk you through them. Let's start with the generic types:

  • Value refers to the value that should be stored/retrieved from the cache
  • Cache is just an object that has a name (for logging), and get, set, and del methods.
  • CacheMetadata is info that gets saved along with the value for determining when the value should be refreshed.

And now for the options:

  • key is the identifier for the value.
  • cache is the cache to use.
  • getFreshValue is the function that actually retrieves the value. This is what we would be running every time if we didn't have a cache in place. Once we get the fresh value, that value is set in the cache at the key.
  • checkValue is a function that verifies the value retrieved from the cache/getFreshValue is correct. It's possible that I deploy a change to the getFreshValue that changes the Value and if the value in the cache isn't correct then we want to force getFreshValue to be called to avoid runtime type errors. We also use this to check that what we got from getFreshValue is correct and if it's not then we throw a helpful error message (definitely better than a type error).
  • forceFresh allows you to skip looking at the cache and will call getFreshValue even if the value hasn't expired yet. If you provide a string then it splits that string by , and checks whether the key is included in that string. If it is then we'll call getFreshValue. This is useful for when you're calling a cachified function which calls other cachified functions (like the function that retrieves all the blog mdx files). You can call that function and only refresh some of the cache values, not all of them.
  • request is used to determine the default value of forceFresh. If the request has the query parameter of ?fresh and the user has the role of ADMIN (so... just me) then forceFresh will default to true. This allows me to manually refresh the cache for all resources on any page. I don't need to do this very often though. You can also provide a value of ,-separated cache key values to force only those cache values to be refreshed.
  • fallbackToCache if we tried to forceFresh (so we skipped the cache) and getting the fresh value failed, then we might want to fallback to the cached value rather than throwing an error. This controls that and defaults to true.
  • timings and timingsType are used for another utility I have for tracking how long things take which then gets sent back in the Server-Timing header (useful for identifying perf bottlenecks).
  • maxAge controls how long to keep the cached value around before trying to refresh it automatically.

When the value is read from the cache, we return the value immediately to keep things fast. After the request is sent, we determine whether that cached value is expired and if it is, then we call cachified again with forceRefresh set to true.

This has the effect of making it so no user ever actually has to wait for getFreshValue. The trade-off is the last user to request the data after the expiration time gets the old value. I think this is a reasonable trade-off.

I'm pretty happy with this abstraction and it's possible that I'll eventually copy/paste this section of the blog post to a README.md for it as an open source project in the future 😅

Image optimization with Cloudinary

Ok folks... Cloudinary is incredible. All the images on this site are hosted on cloudinary and then delivered to your browser in the perfect size and format for your device. It took a little work (and a lot of money... Cloudinary is not cheap) to make this magic happen, but it's saving a TON of internet bandwidth for you and makes the images load much faster.

One of the reasons my Gatsby site took so long to build was that every time I ran the build, gatsby had to generate all the sizes for all my images. The Gatsby team helped me put together a persistent cache, but if I ever needed to bust that cache then I'd have to run Netlify a few times (it would timeout) to fill up the cache again so I could deploy my site again 😬

With Cloudinary, I don't have that problem. I just upload the photo, reference the cloudinary ID in my mdx, and then my site generates the right sizes and srcset props for the <img /> tag. Because Cloudinary allows transforms in the URL, I'm able to generate an image that's exactly the dimensions I want for those props.

Additionally, I'm using Cloudinary to generate all the social images on the site so they can be dynamic (with text/custom font and everything). I'm doing the same for the images on The Call Kent Podcast. It's bonkers.

Another cool thing I'm doing that you may have noticed on the blog posts is on the server I make a request for the banner image that's only 100px wide with a blur transform. Then I convert that into a base64 string. This is cached along with the other metadata about the post. Then when I server-render the post, I server-render the base64 blurred image scaled up (I also use backdrop-filter with CSS to smooth it out a bit from the upscale) and then fade-in the full-size image when it's finished loading. I'm pretty darn happy with this approach.

Cloudinary blows my mind and I'm happy to pay the cost for what I get from it.

MDX Compilation with mdx-bundler

I've been using MDX to write my blog posts ever since I left Medium. I really love that I can easily have interactive bits in the middle of my blog posts without having to handle them in any special way in the code of my site.

When I moved from Gatsby's build-time compilation of MDX to Remix's with on-demand compilation, I needed to find a way to do that on-demand compilation. Right around this time was when xdm was created (a much faster and runtime-free MDX compiler). Unfortunately it's just a compiler, not a bundler. If you're importing components into your MDX, you need to make sure those imports will resolve when you run that compiled code. I decided what I needed wasn't just a compiler. I needed a bundler.

No such bundler existed, so I made one: mdx-bundler. I started with rollup and then gave esbuild a try and was blown away. It's out-of-this-world fast (though still not fast enough to bundle-on-demand so I do cache the compiled version).

As one might expect, I do have several unified plugins (remark/rehype) to automate some things for me during compilation of the mdx. I have one for auto-adding affiliate query params for amazon and egghead links. I have another for converting a link to a tweet into a completely custom twitter embed (way faster than using the twitter widget thing) and one for converting egghead video links into video embeds. I've got another custom one (borrowed from a secret package by Ryan Florence) for syntax highlighting based on Shiki, and one for optimizing inline cloudinary images.

Unified is really powerful and I love using it for my markdown-based content.

Database interaction with Prisma

Alright my friends. Let's talk about Prisma. I am not a database person... At all. All the backend stuff is outside of my wheelhouse. What's funny though is Remix makes the backend so approachable that most of the work I've been doing over the past few months has been backend stuff 😆 And I couldn't be happier with how simple Prisma makes working with a database. Not just querying Postgres, but also data migrations. It's truly amazing how approachable Prisma makes it. So let's talk about those things.

Migrations

With prisma, you describe your database models via a schema.prisma file. Then you can tell Prisma to use that to update your database to reflect your schema. If you ever need to change your schema, you can run prisma migrate dev --name <descriptive-name> and prisma will generate the SQL queries necessary to make the table updates for your schema changes.

If you're careful about how you do this, you can make zero downtime migrations. Zero downtime migrations aren't unique to prisma, but prisma does make creating these migrations much simpler for me, a guy who hasn't done SQL in years and never really liked it anyway 😬 During the development of my site, I had 7 migrations, and two of those were breaking schema changes. The fact that I of all people managed to do this should be endorsement enough 😅

TypeScript

The schema.prisma file can also be used to generate types for your database and this is where things get really awesome. Here's a quick example of a query:

const users = await prisma.user.findMany({
  select: {
    id: true,
    email: true,
    firstName: true,
  },
})
// This is users type. To be clear, I don't have to write this myself,
// the call above returns this type automatically:
const users: Array<{
  id: string
  email: string
  firstName: string
}>

And if I wanted to get the team then:

const users = await prisma.user.findMany({
  select: {
    id: true,
    email: true,
    firstName: true,
    team: true, // <-- just add the field I want
  },
})

And now suddenly the users array is:

const users: Array<{
  id: string
  email: string
  firstName: string
  team: Team
}>

And oh, what if I wanted to also get all the posts this user has read? Do I need some graphql resolver magic? Nope! Check this out:

const users = await prisma.user.findMany({
  select: {
    id: true,
    email: true,
    firstName: true,
    team: true,
    postReads: {
      select: {
        postSlug: true,
      },
    },
  },
})

And now my users array is:

const users: Array<{
  firstName: string
  email: string
  id: string
  team: Team
  postReads: Array<{
    postSlug: string
  }>
}>

Now that's what I'm talking about! And with Remix, I can easily query directly in my loader, and then have that typed data available in my component:

export async function loader({request}: DataFunctionArgs) {
  const users = await prisma.user.findMany({
    select: {
      id: true,
      email: true,
      firstName: true,
      team: true,
      postReads: {
        select: {
          postSlug: true,
        },
      },
    },
  })
  return json({users})
}

export default function UsersPage() {
  const data = useLoaderData<typeof loader>()
  return (
    <div>
      <h1>Users</h1>
      <ul>
        {/* all this auto-completes and type checks!! */}
        {data.users.map(user => (
          <li key={user.id}>
            <div>{user.firstName}</div>
          </li>
        ))}
      </ul>
    </div>
  )
}

And if I decide I don't need some data on the client, I simply update the prisma query and TypeScript will make sure I didn't miss anything. It's just fantastic.

Prisma has made me, a frontend developer, feel empowered to work directly with a database.

A while back, I tweeted some words that I'm eating...

Kent C. Dodds 🌌 avatar
Kent C. Dodds 🌌 @kentcdodds
Here are the only reasonable options for authentication in apps: 1. Use a cloud provider for auth 2. Have a team dedicated to auth for the company's apps 3. Use HTTP basic auth because security clearly doesn't matter that much for you anyway 🤷‍♂️

Yup, that's right... I hand-rolled my own authentication on this site. But I had a good reason! Remember all the talk above about making things super fast by collocating the node servers and databases close to users? Well, I'd kinda undo all that work if I used an authentication service. Every request would have to go to the region that provider supported to verify the user's logged in state. How disappointing would that be?

Around the time I was working on the authentication problem, Ryan Florence did some live streams where he implemented authentication for his own Remix app. It didn't look all that complicated. And he was kind enough to give me an outline of the things that are required and I got most of it done in just one day!

Something that helped a great deal was using magic links for authentication. Doing this means I don't need to worry about storing passwords or handling password resets/changes. But this wasn't just a selfish/lazy decision. I feel strongly that magic links are the best authentication system for an app like mine. Keep in mind that pretty much every other app has a "magic link"-like auth system even if it's implicit because of the "reset password" flow which emails you a link to reset your password. So it's certainly not any less secure. In fact, actually more secure because there's no password to lose.

Oh, and before you say:

But if there's no password, I can't use my password manager and I'll forget which of my 30 email addresses I used to sign up on your site!

Your password manager can definitely store login information that has only an email address and no password. Do that.

Ok, let's take a look at a diagram of the authentication flow:

Excalidraw diagram of a user going to the login screen, clicking the magic link, and getting authenticated

Some things I want to point out with this flow is that there's no interaction with the database until the user has actually signed up. Also, the flow for sign up and login are the same. This simplifies things a fair amount for me.

Now, let's take a look at what happens when a user navigates to an authenticated page.

Excalidraw diagram of a user going to an authenticated page and the session being resolved to a user or the user getting redirected to login

The basics of this is pretty simple:

  • Get the session ID from the session cookie
  • Get the user ID from the session
  • Get the user
  • Update the expiration time so active users rarely need to re-authenticate
  • If any of these fails, cleanup and redirect

It's honestly not as complicated as I remembered it being when I hand-rolled authentication years ago in other apps I worked on. Remix helps make it much easier with its cookie session abstraction.

Remix

Remix logo

Ok folks. Of all tools I'm using, Remix has made the biggest impact on my productivity and the performance of my website. Remix enables me to do all this cool stuff without over complicating my codebase.

I'm definitely going to be writing a lot of blog posts about Remix in the future, so subscribe to keep up with that. But here's a quick list of why Remix has been so fantastic for me:

  1. The ease of communicating between the server and client. Data over-fetching is no longer a problem because it's so easy for me to filter down what I want in the server code and have exactly what I need in the client code. Because of this there's no need for a huge and complicated graphql backend and client library to deal with that issue (you can definitely still use graphql with remix if you want to though). This one is huge and I will write many blog posts about this in the coming months.
  2. The auto-performance I get from Remix's use of the web platform. This is also a big one that will require multiple blog posts to explain.
  3. The ability to have CSS for a specific route and know that I won't clash with CSS on any other route. 👋 goodbye CSS-in-JS.
  4. The fact I don't have to even think about a server cache because Remix handles all that for me (including after mutations). All my components can assume the data is ready to go. Managing exceptions/errors is declarative. And Remix doesn't implement its own cache but instead leverages the browser cache to make things super fast even after a reload (or opening a link in a new tab).
  5. No worrying about a Layout component like with other frameworks and the benefits that offers me from a data-loading perspective. Again, this will require a blog post.

I mention that several of these will require a blog post. Not because you have anything to learn to take advantage of these things, but to explain to you that you don't. It's just the way Remix works. I spend less time thinking about how to make things work and more time realizing that my app's capabilities are not limited by my framework, but by my ✨ imagination ✨.

Conclusion

I can't tell you how much I've learned from building this website. It's been a ton of fun and I'm excited to put my learnings into blog posts and workshops to teach you the specifics of how I did this stuff so you can do it too. In fact, I've already scheduled some workshops for you to attend! Pick up tickets now. I look forward to seeing you there! Take care, and keep up the good work.

And don't forget, if you haven't already read the "Introducing the new kentcdodds.com" post, please do give it a read!

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Kent C. Dodds
Written by Kent C. Dodds

Kent C. Dodds is a JavaScript software engineer and teacher. Kent's taught hundreds of thousands of people how to make the world a better place with quality software development tools and practices. He lives with his wife and four kids in Utah.

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