Building React Apps in an Nx Monorepo

In this tutorial you'll learn how to use React with Nx in a monorepo (integrated) setup.

What are you going to learn?

• how to create a new React application
• how to run a single task (i.e. serve your app) or run multiple tasks in parallel
• how to leverage code generators to scaffold components
• how to modularize your codebase and impose architectural constraints for better maintainability

Why Use an Integrated Monorepo?

An integrated monorepo is a repository configured with a set of features that work together toward the goal of allowing developers to focus on building features rather than the configuration, coordination and maintenance of the tooling in the repo.

You'll notice that instead of using npm/yarn/pnpm workspaces, projects within the repository are linked using typescript path aliases that are defined in the tsconfig.base.json file. Also, since we're creating projects using Nx plugin generators, all new projects come preconfigured with useful tools like Prettier, ESLint and Jest.

Nx Plugins are optional packages that extend the capabilities of Nx, catering to various specific technologies. For instance, we have plugins tailored to React (e.g., @nx/react), Vite (@nx/vite), Cypress (@nx/cypress), and more. These plugins offer additional features, making your development experience more efficient and enjoyable when working with specific tech stacks.

Features of an integrated monorepo:

• Install dependencies at the root by default
• Scaffold new code with generators
• Updates dependencies with automated migrations

Visit our "Why Nx" page for more details.

Final Code

Here's the source code of the final result for this tutorial.

Creating a new React Monorepo

Create a new React monorepo with the following command:

Let's name the initial application react-store. In this tutorial we're going to use vite as a bundler, cypress for e2e tests and css for styling. The above command generates the following structure:

The setup includes..

• a new React application (apps/react-store/)
• a Playwright based set of e2e tests (apps/react-store-e2e/)
• Prettier preconfigured
• ESLint preconfigured
• Jest preconfigured

Typically, an integrated Nx workspace places application projects in the apps folder and library projects in the libs folder. Applications are encouraged to be as light-weight as possible so that more code is pushed into libraries and can be reused in other projects. This folder structure is just a suggestion and can be modified to suit your organization's needs.

The nx.json file contains configuration settings for Nx itself and global default settings that individual projects inherit. The apps/react-store/project.json file contains settings that are specific to the react-store project. We'll examine that file more in the next section.

Serving the App

To serve your new React application, just run:

Your application should be served at http://localhost:4200.

Nx uses the following syntax to run tasks:

Inferred Tasks

Nx identifies available tasks for your project from tooling configuration files, package.json scripts and the targets defined in project.json. To view the tasks that Nx has detected, look in the Nx Console project detail view or run:

If you expand the build task, you can see that it was created by the @nx/vite plugin by analyzing your vite.config.ts file. Notice the outputs are defined as {workspaceRoot}/dist/apps/react-store. This value is being read from the build.outDir defined in your vite.config.ts file. Let's change that value in your vite.config.ts file:

Now if you look at the project details view, the outputs for the build target will say {workspaceRoot}/build/react-store. This feature ensures that Nx will always cache the correct files.

You can also override the settings for inferred tasks by modifying the targetDefaults in nx.json or setting a value in your project.json file. Nx will merge the values from the inferred tasks with the values you define in targetDefaults and in your specific project's configuration.

Adding Another Application

Nx plugins usually provide generators that allow you to easily scaffold code, configuration or entire projects. To see what capabilities the @nx/react plugin provides, run the following command and inspect the output:

Run the following command to generate a new inventory application. Note how we append --dry-run to first check the output.

As you can see, it generates a new application in the apps/inventory/ folder. Let's actually run the generator by removing the --dry-run flag.

Sharing Code with Local Libraries

When you develop your React application, usually all your logic sits in the app folder. Ideally separated by various folder names which represent your "domains". As your app grows, however, the app becomes more and more monolithic and the code is unable to be shared with other applications.

Nx allows you to separate this logic into "local libraries". The main benefits include

• better separation of concerns
• better reusability
• more explicit "APIs" between your "domain areas"
• better scalability in CI by enabling independent test/lint/build commands for each library
• better scalability in your teams by allowing different teams to work on separate libraries

Creating Local Libraries

Let's assume our domain areas include products, orders and some more generic design system components, called ui. We can generate a new library for each of these areas using the React library generator:

Note how we type out the full path in the directory flag to place the libraries into a subfolder. You can choose whatever folder structure you like to organize your projects. If you change your mind later, you can run the move generator to move a project to a different folder.

Running the above commands should lead to the following directory structure:

Each of these libraries

• has a project details view where you can see the available tasks (e.g. running tests for just orders: nx test orders)
• has its own project.json file where you can customize targets
• has the name you specified in the generate command; you can find the name in the corresponding project.json file
• has a dedicated index.ts file which is the "public API" of the library
• is mapped in the tsconfig.base.json at the root of the workspace

Importing Libraries into the React Applications

All libraries that we generate automatically have aliases created in the root-level tsconfig.base.json.

Hence we can easily import them into other libraries and our Angular application. As an example, let's use the pre-generated ProductsComponent component from our libs/products library.

You can see that the Products component is exported via the index.ts file of our products library so that other projects in the repository can use it. This is our public API with the rest of the workspace. Only export what's really necessary to be usable outside the library itself.

We're ready to import it into our main application now. First (if you haven't already), let's set up React Router.

Configure it in the main.tsx.

Then we can import the Products component into our app.tsx and render it via the routing mechanism whenever a user hits the /products route.

Serving your app (nx serve react-store) and then navigating to /products should give you the following result:

Let's apply the same for our orders library.

• import the Orders component from libs/orders into the app.tsx and render it via the routing mechanism whenever a user hits the /orders route

In the end, your app.tsx should look similar to this:

Let's also show products in the inventory app.

Visualizing your Project Structure

Nx automatically detects the dependencies between the various parts of your workspace and builds a project graph. This graph is used by Nx to perform various optimizations such as determining the correct order of execution when running tasks like nx build, identifying affected projects and more. Interestingly you can also visualize it.

Just run:

You should be able to see something similar to the following in your browser.

Notice how shared-ui is not yet connected to anything because we didn't import it in any of our projects.

Exercise for you: change the codebase such that shared-ui is used by orders and products. Note: you need to restart the nx graph command to update the graph visualization or run the CLI command with the --watch flag.

Testing and Linting - Running Multiple Tasks

Our current setup doesn't just come with targets for serving and building the React application, but also has targets for unit testing, e2e testing and linting. Again, these are defined in the project.json file. We can use the same syntax as before to run these tasks:

More conveniently, we can also run tasks in parallel using the following syntax:

Caching

One thing to highlight is that Nx is able to cache the tasks you run.

Note that all of these targets are automatically cached by Nx. If you re-run a single one or all of them again, you'll see that the task completes immediately. In addition, (as can be seen in the output example below) there will be a note that a matching cache result was found and therefore the task was not run again.

Not all tasks might be cacheable though. You can configure the cache settings in the targetDefaults property of the nx.json file. You can also learn more about how caching works.

Testing Affected Projects

Commit your changes to git.

And then make a small change to the products library.

One of the key features of Nx in a monorepo setting is that you're able to run tasks only for projects that are actually affected by the code changes that you've made. To run the tests for only the projects affected by this change, run:

Note that the unit tests were run for products, react-store and inventory, but not for orders because a change to products can not possibly break the tests for orders. In a small repo like this, there isn't a lot of time saved, but as there are more tests and more projects, this quickly becomes an essential command.

You can also see what projects are affected in the graph visualizer with;

Building the Apps for Deployment

If you're ready and want to ship your applications, you can build them using

All the required files will be placed in dist/react-store and dist/inventory and can be deployed to your favorite hosting provider.

You can even create your own deploy task that sends the build output to your hosting provider.

Replace the command with whatever terminal command you use to deploy your site.

The "dependsOn": ["build"] setting tells Nx to make sure that the project's build task has been run successfully before the deploy task.

With the deploy tasks defined, you can deploy a single application with nx deploy react-store or deploy any applications affected by the current changes with:

Imposing Constraints with Module Boundary Rules

Once you modularize your codebase you want to make sure that the libs are not coupled to each other in an uncontrolled way. Here are some examples of how we might want to guard our small demo workspace:

• we might want to allow orders to import from shared-ui but not the other way around
• we might want to allow orders to import from products but not the other way around
• we might want to allow all libraries to import the shared-ui components, but not the other way around

When building these kinds of constraints you usually have two dimensions:

• type of project: what is the type of your library. Example: "feature" library, "utility" library, "data-access" library, "ui" library
• scope (domain) of the project: what domain area is covered by the project. Example: "orders", "products", "shared" ... this really depends on the type of product you're developing

Nx comes with a generic mechanism that allows you to assign "tags" to projects. "tags" are arbitrary strings you can assign to a project that can be used later when defining boundaries between projects. For example, go to the project.json of your orders library and assign the tags type:feature and scope:orders to it.

Then go to the project.json of your products library and assign the tags type:feature and scope:products to it.

Finally, go to the project.json of the shared-ui library and assign the tags type:ui and scope:shared to it.

Notice how we assign scope:shared to our UI library because it is intended to be used throughout the workspace.

Next, let's come up with a set of rules based on these tags:

• type:feature should be able to import from type:feature and type:ui
• type:ui should only be able to import from type:ui
• scope:orders should be able to import from scope:orders, scope:shared and scope:products
• scope:products should be able to import from scope:products and scope:shared

To enforce the rules, Nx ships with a custom ESLint rule. Open the .eslintrc.base.json at the root of the workspace and add the following depConstraints in the @nx/enforce-module-boundaries rule configuration:

To test it, go to your libs/products/src/lib/products.tsx file and import the Orders component from the orders project:

If you lint your workspace you'll get an error now:

If you have the ESLint plugin installed in your IDE you should also immediately see an error.

Learn more about how to enforce module boundaries.

Set Up CI for Your React Monorepo

This tutorial walked you through how Nx can improve the local development experience, but the biggest difference Nx makes is in CI. As repositories get bigger, making sure that the CI is fast, reliable and maintainable can get very challenging. Nx provides a solution.

• Nx reduces wasted time in CI with the affected command.
• Nx Replay's remote caching will reuse task artifacts from different CI executions making sure you will never run the same computation twice.
• Nx Agents efficiently distribute tasks across machines ensuring constant CI time regardless of the repository size. The right number of machines is allocated for each PR to ensure good performance without wasting compute.
• Nx Atomizer automatically splits large e2e tests to distribute them across machines. Nx can also automatically identify and rerun flaky e2e tests.

Generate a CI Workflow

If you are starting a new project, you can use the following command to generate a CI workflow file.

This generator creates a .github/workflows/ci.yml file that contains a CI pipeline that will run the lint, test, build and e2e tasks for projects that are affected by any given PR.

The key line in the CI pipeline is:

Connect to Nx Cloud

Nx Cloud is a companion app for your CI system that provides remote caching, task distribution, e2e tests deflaking, better DX and more.

To connect to Nx Cloud:

• Commit and push your changes
• Go to https://cloud.nx.app, create an account, and connect your repository

Connect to Nx Cloud Manually

If you are not able to connect via the automated process at https://cloud.nx.app, you can connect your workspace manually by running:

You will then need to merge your changes and connect to your workspace on https://cloud.nx.app.

Enable a Distributed CI Pipeline

The current CI pipeline runs on a single machine and can only handle small workspaces. To transform your CI into a CI that runs on multiple machines and can handle workspaces of any size, uncomment the npx nx-cloud start-ci-run line in the .github/workflows/ci.yml file.

For more information about how Nx can improve your CI pipeline, check out one of these detailed tutorials:

• Circle CI with Nx
• GitHub Actions with Nx

Next Steps

Here's some things you can dive into next:

• Learn more about the underlying mental model of Nx
• Learn how to migrate your React app to Nx
• Learn how to setup Tailwind
• Setup Storybook for our shared UI library

Also, make sure you

• Join the Official Nx Discord Server to ask questions and find out the latest news about Nx.
• Follow Nx on Twitter to stay up to date with Nx news
• Read our Nx blog
• Subscribe to our Youtube channel for demos and Nx insights