Most software developers encounter three main problems: naming things, caching, and off-by-one errors. 🤦🏻♂️
In this tutorial, we’ll deal with caching. We’ll walk through how to implement RESTful request caching with Redis. We’ll also set up and deploy this system easily with Heroku.
For this demo, we’ll build a Node.js application with the Fastify framework, and we’ll integrate caching with Redis to reduce certain types of latency.
Ready to dive in? Let’s go!
Node.js + Fastify + long-running tasks
As I’m sure readers know, Node.js is a very popular platform for building web applications. With its support for JavaScript (or TypeScript, or both at the same time!), Node.js allows you to use the same language for both the frontend and the backend of your application. It also has a rich event loop that makes asynchronous request handling more intuitive.
The concurrency model in Node.js is very performant, able to . But even then, you might still run into situations where the request latency is unacceptably high. We’ll show this with our application.
As you follow along, you can always browse the codebase for this mini demo at my .
Initialize the basic application
By using , you can quickly get a Node.js application up and running to handle requests. Assuming you have Node.js installed, you’ll start by initializing a new project. We’ll use as our package manager.
After initializing a new project, we will install our Fastify-related dependencies.
~/project$ npm i fastify fastify-cli fastify-plugin |
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Then, we update our package.json file to add two scripts and turn on the ES module syntax.
We make sure to have the following lines:
"type": "module", "main": "app.js", "scripts": { "start": "fastify start -a 0.0.0.0 -l info app.js", "dev": "fastify start -p 8000 -w -l info -P app.js" }, |
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From there, we create our first file (routes.js) with an initial route:
// routes.js
export default async function (fastify,opts) { fastify.get("/api/health", async (, reply) => { return reply.send({ status: "ok" }); }); } |
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Then, we create our app.js file that prepares a Fastify instance and registers the routes:
// app.js import routes from "./routes.js";
export default async (fastify, opts) => { fastify.register(routes); }; |
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These two simple files—our application and our route definitions—are all we need to get up and running with a small Fastify service that exposes one endpoint: /api/health. Our dev script in package.json is set to run the fastify-cli to start our server on localhost port 8000, which is good enough for now. We start up our server:
Then, in another terminal window, we use to hit the endpoint:
~$ curl //localhost:8000/api/health {"status":"ok"} |
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Add a simulated long-running process
We’re off to a good start. Next, let’s add another route to simulate a long-running process. This will help us gather some latency data. In routes.js, we add another route handler within our exported default async function:
fastify.get("/api/user-data", async (_, reply) => { await sleep(5000); const userData = readData(); return reply.send({ data: userData }); }); |
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This exposes another endpoint: /api/user-data. Here, we have a method to simulate reading a lot of data from a database (readData) and a long-running process (sleep). We define those methods in routes.js as well. They look like this:
import fs from "fs";
function readData() { try { const data = fs.readFileSync("data.txt", "utf8"); return data; } catch (err) { console.error(err); } }
function sleep(ms) { return new Promise((resolve) => { setTimeout(resolve, ms); }); } |
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With our new route in place, we restart our server (npm run dev).
Measure latency with curl
How do we measure latency? The simplest way is to use curl. Curl captures various time profiling metrics when it makes requests. We just need to format curl’s output so that we can easily see the various latency values available. To do this, we define the output we want to see with a text file (curl-format.txt):
time_namelookup: %{time_namelookup}
time_connect: %{time_connect}
time_appconnect: %{time_appconnect}
time_pretransfer: %{time_pretransfer}
time_redirect: %{time_redirect}
time_starttransfer: %{time_starttransfer}
------------------- --------- time_total: %{time_total}
|
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With our output format defined, we can use it with our next curl call:
curl -w "@curl-format.txt" \ -o /dev/null -s \ "//localhost:8000/api/user-data" |
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The response we receive looks like this:
time_namelookup: 0.000028s time_connect: 0.000692s time_appconnect: 0.000000s time_pretransfer: 0.000772s time_redirect: 0.000000s time_starttransfer: 5.055683s ---------- time_total: 5.058479s |
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Well, that’s not good. Over five seconds is way too long for a transfer time (the time it takes the server to actually handle the request). Imagine if this endpoint was being hit hundreds or thousands of times per second! Your users would be frustrated, and your server may crash under the weight of continually re-doing this work.
Redis to the rescue!
Caching your responses is the first line of defense to reduce your transfer time (assuming you’ve addressed any of the poor programming practices that might be causing the latency!). So, let’s assume we’ve done everything we can do to reduce latency, but our application still needs five seconds to put this complex data together and return it to the user.
In our scenario, because the data is the same every time for every request to /api/user-data, we have a perfect candidate for caching. With caching, we’ll perform the necessary computation once, cache the result, and return the cached value for all subsequent requests.
is a performant, in-memory key/value store, and it’s a common tool used for caching. To leverage it, we first install Redis on our local machine. Then, we need to add to our project:
~/project$ npm i @fastify/redis |
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Register the Redis plugin with Fastify
We create a file, redis.js, which configures our Redis plugin and registers it with Fastify. Our file looks like this:
// redis.js
const REDIS_URL = process.env.REDIS_URL || "redis://127.0.0.1:6379";
import fp from "fastify-plugin"; import redis from "@fastify/redis";
const parseRedisUrl = (redisUrl) => { const url = new URL(redisUrl); const password = url.password; return { host: url.hostname, port: url.port, password, }; };
export default fp(async (fastify) => { fastify.register(redis, parseRedisUrl(REDIS_URL)); }); |
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Most of the lines in this file are dedicated to parsing a REDIS_URL value into a host, port, and password. If we have REDIS_URL set properly at runtime as an environment variable, then registering Redis with Fastify is simple. After configuring our plugin, we just need to modify app.js to use it:
// app.js
import redis from "./redis.js"; import routes from "./routes.js";
export default async (fastify, opts) => { fastify.register(redis); fastify.register(routes); }; |
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Now we have access to our Redis instance by referencing fastify.redis anywhere within our app.
Modify our endpoint to use caching
With Redis in the mix, let’s change our /api/user-data endpoint to use caching:
fastify.get("/api/user-data", async (_, reply) => { const { redis } = fastify;
// check if data is in cache const data = await redis.get("user-data", (err, val) => { if (val) { return { data: val }; } return null; });
if (data) { return reply.send(data); }
// simulate a long-running task await sleep(5000); const userData = readData();
// add data to the cache redis.set("user-data", userData);
return reply.send({ data: userData }); }); |
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Here, you see that we’ve hardcoded in Redis a single key, user-data, and stored our data under that key. Of course, our key could be a user ID or some other value that identifies a particular type of request or state. Also, we could , in the case that we expect data to change after a certain window of time.
If there is data in the cache, then we’ll return it and skip all the time-consuming work. Otherwise, do the long-running computation, add the result to the cache, and then return it to the user.
What do our transfer times look like after hitting this endpoint two more times (the first one to add the data into the cache, and the second one to retrieve it)?
time_namelookup: 0.000023s time_connect: 0.000560s time_appconnect: 0.000000s time_pretransfer: 0.000729s time_redirect: 0.000000s time_starttransfer: 0.044512s ---------- time_total: 0.047479s |
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Much better! We’ve reduced our request times from several seconds to milliseconds. That’s a huge improvement in performance!
Redis has many more features that may be useful here, including having key/value pairs timeout after a certain amount of time; that’s a more common scenario in production environments.
Using Redis in your Heroku deployment
Up to this point, we’ve only shown how this works in a local environment. Now, let’s go one step further and deploy it all to the cloud. Fortunately, Heroku provides many options for deploying web applications and working with Redis. Let’s walk through how to get set up there.
After and installing their , we’re ready to create a new app. In our case, we’ll call our app fastify-with-caching. Here are our steps:
Step 1: Login to Heroku
~/projects$ heroku login ... Logging in... done |
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Step 2: Create the Heroku app
When we create our Heroku app, we’ll get back our Heroku app URL. We take note of this because we’ll use it in our subsequent curl requests.
~/project$ heroku create -a fastify-with-caching Creating ⬢ fastify-with-caching... done //fastify-with-caching-3e247d11f4ad.herokuapp.com/ | //git.heroku.com/fastify-with-caching.git |
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Step 3: Add the Heroku Data for Redis add-on
We need to set up a that meets our application’s needs. For our demo project, it’s sufficient to create a Mini-tier Redis instance:
~/project$ heroku addons:create heroku-redis:mini -a fastify-with-caching Creating heroku-redis:mini on ⬢ fastify-with-caching…… redis-transparent-98258 is being created in the background.… |
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Spinning up the Redis instance may take two or three minutes. We can check the status of our instance periodically:
~/project$ heroku addons:info redis-transparent-98258 ... State: creating |
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Not too long after, we see this:
We’re just about ready to go!
When Heroku spins up our Redis add-on, it also adds our Redis credentials as config variables attached to our Heroku app. We can run the following command to see these config variables:
~/project$ heroku config -a fastify-with-caching === fastify-with-caching Config Vars
REDIS_TLS_URL: rediss://:p171d98f7696ab7eb2319f7b78083af749a0d0bb37622fc420e6c1205d8c4579c@ec2-18-213-142-76.compute-1.amazonaws.com:15940 REDIS_URL: redis://:p171d98f7696ab7eb2319f7b78083af749a0d0bb37622fc420e6c1205d8c4579c@ec2-18-213-142-76.compute-1.amazonaws.com:15939 |
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(Your credentials, of course, will be unique and different from what you see above.)
Notice that we have a REDIS_URL variable all set up for us. It’s a good thing our redis.js file is coded to properly parse an environment variable called REDIS_URL.
Step 4: Create a Heroku remote
Finally, we need to in our git repo so that we can easily deploy with git.
~/project$ heroku git:remote -a fastify-with-caching set git remote heroku to //git.heroku.com/fastify-with-caching.git |
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Step 5: Deploy!
Now, when we push our branch to our Heroku remote, Heroku will build and deploy our application.
~/project$ git push heroku main ... remote: Building source: remote: remote: -----> Building on the Heroku-22 stack remote: -----> Determining which buildpack to use for this app remote: -----> Node.js app detected remote: remote: -----> Creating runtime environment ... remote: -----> Compressing... remote: Done: 50.8M remote: -----> Launching... remote: Released v4 remote: //fastify-with-caching-3e247d11f4ad.herokuapp.com/ deployed to Heroku remote: remote: Verifying deploy... done. |
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Our application is up and running. It’s time to test it.
Test our deployed application
We start with a basic curl request to our /api/health endpoint:
$ curl //fastify-with-caching-3e247d11f4ad.herokuapp.com/api/health {"status":"ok"} |
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Excellent. That looks promising.
Next, let’s send our first request to the long-running process and capture the latency metrics:
$ curl \ -w "@curl-format.txt" \ -o /dev/null -s \ //fastify-with-caching-3e247d11f4ad.herokuapp.com/api/user-data time_namelookup: 0.035958s time_connect: 0.101336s time_appconnect: 0.249308s time_pretransfer: 0.249389s time_redirect: 0.000000s time_starttransfer: 5.384986s ------------------- ---------- time_total: 6.554382s |
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When we send the same request a second time, here’s the result:
$ curl \ -w "@curl-format.txt" \ -o /dev/null -s \ //fastify-with-caching-3e247d11f4ad.herokuapp.com/api/user-data time_namelookup: 0.025807s time_connect: 0.091763s time_appconnect: 0.236050s time_pretransfer: 0.236119s time_redirect: 0.000000s time_starttransfer: 0.334859s ------------------- ---------- time_total: 1.276264s |
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Much better! Caching allows us to bypass the long-running processes. From here, we can build out a much more robust caching mechanism for our application across all our routes and processes. We can continue to lean on Heroku and Heroku’s Redis add-on when we need to deploy our application to the cloud.
Bonus Tip: Clearing the cache for future tests
By the way, if you want to test this more than once, then you may occasionally need to delete the user-data key/value pair in Redis. You can use the Heroku CLI to access the Redis CLI for your Redis instance:
~$ heroku redis:cli -a fastify-with-caching Connecting to redis-transparent-98258 (REDIS_TLS_URL, REDIS_URL): ec2-18-213-142-76.compute-1.amazonaws.com:15940> DEL user-data 1 |
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Conclusion
In this tutorial, we explored how caching can greatly improve your web service's response time in cases where identical requests would produce identical responses. We looked at how to implement this with Redis, the industry-standard caching tool. We did this all with ease within a Node.js application that leverages the Fastify framework. Lastly, we deployed our demo application to Heroku, using their built-in Heroku Data for Redis instance management to cache in the cloud.