Building a Single Vue App with Nx

In this tutorial you'll learn how to use Vue with Nx in a "standalone" (non-monorepo) setup. Not to be confused with the "Vue Standalone API", a standalone project in Nx is a non-monorepo setup where you have a single application at the root level.

What are you going to learn?

  • how to add Nx to a Vue project
  • 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

We'll start out this tutorial using Nx together with a Vue application generated with the default npm create vue command. Later, we'll add the @nx/vue plugin to show the nice enhancements that it can provide. Visit our "Why Nx" page to learn more about plugins and what role they play in the Nx architecture.

Final Code

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

Creating a new Vue App

Create a new Vue application with the following command:

~

npm create vue vue-app -- --ts --jsx --router --vitest --playwright --eslint-with-prettier

1 2Vue.js - The Progressive JavaScript Framework 3 4Scaffolding project in ~/vue-app... 5 6Done. Now run: 7 8 cd vue-app 9 npm install 10 npm run format 11 npm run dev 12

Once you have run npm install, set up Git with the following commands:

git init

git add .

git commit -m "initial commit"

This command sets up a Vue app that uses Typescript and is configured to use the Vue router, Vitest for unit tests, Playwright for e2e tests and ESLint and Prettier for formatting. Your repository should now have the following structure:

1└─ vue-app 2 ├─ .vscode 3 │ └─ extensions.json 4 ├─ e2e 5 │ ├─ tsconfig.json 6 │ └─ vue.spec.ts 7 ├─ public 8 ├─ src 9 │ ├─ assets 10 │ ├─ components 11 │ ├─ router 12 │ ├─ views 13 │ ├─ App.vue 14 │ └─ main.ts 15 ├─ .eslintrc.cjs 16 ├─ .prettierrc.json 17 ├─ index.html 18 ├─ package.json 19 ├─ playwright.config.ts 20 ├─ README.md 21 ├─ tsconfig.app.json 22 ├─ tsconfig.json 23 ├─ tsconfig.node.json 24 ├─ tsconfig.vitest.json 25 ├─ vite.config.ts 26 └─ vitest.config.ts 27

The setup includes..

  • a new Vue application at the root of the Nx workspace (src)
  • a Playwright based set of e2e tests (e2e/)
  • Prettier preconfigured
  • ESLint preconfigured
  • Vitest preconfigured

You can build the application with the following command:

1npm run build 2

Add Nx

Nx offers many features, but at its core, it is a task runner. Out of the box, it can:

After the initial set up, you can incrementally add on other features that would be helpful in your organization.

To enable Nx in your repository, run a single command:

npx nx@latest init

This command will download the latest version of Nx and help set up your repository to take advantage of it.

First, the script will propose installing some plugins based on the packages that are being used in your repository.

  • Leave the plugins deselected so that we can explore what Nx provides without any plugins.

Second, the script asks a series of questions to help set up caching for you.

  • Which scripts are cacheable? - Choose test:e2e, build-only, type-check and lint
  • Does the "test:e2e" script create any outputs? - Enter playwright-report
  • Does the "build-only" script create any outputs? - Enter dist
  • Does the "type-check" script create any outputs? - Enter nothing
  • Does the "lint" script create any outputs? - Enter nothing
  • Would you like remote caching to make your build faster? - Choose Skip for now.

We'll enable Nx Cloud and add remote caching later in the tutorial.

Caching Pre-configured

Nx has been configured to run your npm scripts as Nx tasks. You can run a single task like this:

npx nx type-check vue-app

During the init script, Nx also configured caching for these tasks. You can see in the nx.json file that the scripts we identified as cacheable have the cache property set to true and the build-only target specifies that its output goes to the project's dist folder.

nx.json
1{ 2 "$schema": "./node_modules/nx/schemas/nx-schema.json", 3 "targetDefaults": { 4 "test:e2e": { 5 "outputs": ["{projectRoot}/playwright-report"], 6 "cache": true 7 }, 8 "build-only": { 9 "outputs": ["{projectRoot}/dist"], 10 "cache": true 11 }, 12 "type-check": { 13 "cache": true 14 }, 15 "lint": { 16 "cache": true 17 } 18 }, 19 "defaultBase": "main" 20} 21

Try running type-check for the vue-app app a second time:

npx nx type-check vue-app

The first time nx type-check was run, it took about 2 seconds - just like running npm run type-check. But the second time you run nx type-check, it completes instantly and displays this message:

1Nx read the output from the cache instead of running the command for 1 out of 1 tasks. 2

You can see the same caching behavior working when you run npx nx lint.

Create a Task Pipeline

If you look at the build script in package.json, you'll notice that it is actually doing two things. It runs the type-check script and, in parallel, runs the build-only script.

package.json
1{ 2 "scripts": { 3 "build": "run-p type-check \"build-only {@}\" --", 4 "build-only": "vite build", 5 "type-check": "vue-tsc --build --force" 6 } 7} 8

Instead of deciding ahead of time whether tasks need to be run in parallel or series, let's define the dependencies between tasks and then allow Nx to run them in the most efficient way possible. Update the package.json file with the following information:

package.json
1{ 2 "scripts": { 3 "build": "nx exec -- echo 'Ran type-check and build-only'", 4 "build-only": "vite build", 5 "type-check": "vue-tsc --build --force" 6 } 7} 8

Since the build command itself doesn't do anything, we can replace it with an echo to the console. The dependencies between the tasks we can define in the dependsOn property in the nx.json file:

nx.json
1{ 2 "targetDefaults": { 3 "build": { 4 "dependsOn": ["type-check", "build-only"] 5 } 6 } 7} 8

Whenever Nx runs the build task, it knows that the type-check and build-only tasks need to be run first. However, if the build script is run without using Nx (say with npm run build), the task dependencies will not be run. That's why we add the nx exec -- command at the beginning of the build script in package.json. If you run npm run build, Nx will be used to run the task and any dependencies will be invoked correctly.

Now if you run nx build vue-app, Nx will run type-check and build-only first.

There's still one piece of functionality that was lost by this change. The {@} syntax in the original build script was used to forward command line arguments to the build-only script. To accomplish the same thing with Nx, instead of using a string for the build-only task dependency, we'll use an object and tell Nx to forward arguments on to that task.

nx.json
1{ 2 "targetDefaults": { 3 "build": { 4 "dependsOn": [ 5 "type-check", 6 { 7 "target": "build-only", 8 "params": "forward" 9 } 10 ] 11 } 12 } 13} 14

If you run nx build vue-app -l=error, Nx will run the build-only script with a log level of error.

~/vue-app

npx nx build

1> nx run vue-app:type-check [existing outputs match the cache, left as is] 2 3 4> vue-app@0.0.0 type-check 5> vue-tsc --build --force 6 7 8> nx run vue-app:build-only [local cache] 9 10 11> vue-app@0.0.0 build-only 12> vite build -l error 13 14 15> nx run vue-app:build -l error 16 17 18> vue-app@0.0.0 build 19> nx exec -- echo 'Ran type-check and build-only' -l error 20 21Ran type-check and build-only -l error 22 23————————————————————————————————————————————————————————————————————— 24 25 NX Successfully ran target build for project vue-app and 2 tasks it depends on (456ms) 26 27 With additional flags: 28 --l=error 29

And once again, running npx nx build or npm run build twice will complete instantly.

Use Nx Plugins to Enhance Vite Tasks with Caching

You may remember that we defined the outputs property in nx.json when we were answering questions in the nx init script. The value is currently hard-coded so that if you change the output path in your vite.config.ts, you have to remember to also change the outputs array in the build task configuration. This is where plugins can help. Plugins enable better integration with specific tools. The @nx/vite plugin can understand the vite.config.ts file and automatically create and configure tasks based on the settings in that file.

Nx plugins can:

  • automatically configure caching for you, including inputs and outputs based on the underlying tooling configuration
  • create tasks for a project using the tooling configuration files
  • provide code generators to help scaffold out projects
  • automatically keep the tooling versions and configuration files up to date

For this tutorial, we'll just focus on the automatic caching configuration.

First, let's delete the outputs array for the build-only task in nx.json so that we don't override the inferred values from the plugin. Your nx.json should look like this:

nx.json
1{ 2 "$schema": "./node_modules/nx/schemas/nx-schema.json", 3 "targetDefaults": { 4 "test:e2e": { 5 "outputs": ["{projectRoot}/playwright-report"], 6 "cache": true 7 }, 8 "build": { 9 "dependsOn": [ 10 "type-check", 11 { 12 "target": "build-only", 13 "params": "forward" 14 } 15 ] 16 }, 17 "build-only": { 18 "cache": true 19 }, 20 "type-check": { 21 "cache": true 22 }, 23 "lint": { 24 "cache": true 25 } 26 }, 27 "defaultBase": "main" 28} 29

Now let's add the @nx/vite plugin:

~/vue-app

npx nx add @nx/vite

1✔ Installing @nx/vite... 2✔ Initializing @nx/vite... 3 4 NX Package @nx/vite added successfully. 5

The nx add command installs the version of the plugin that matches your repo's Nx version and runs that plugin's initialization script. For @nx/vite, the initialization script registers the plugin in the plugins array of nx.json and updates any package.json scripts that execute Vite related tasks. Open the project details view for the vue-app app and look at the vite:build task.

npx nx show project vue-app

Loading...

If you hover over the settings for the vite:build task, you can see where those settings come from. The inputs and outputs are defined by the @nx/vite plugin from the vite.config.ts file where as the dependsOn property we set earlier in the tutorial is set in the targetDefaults in the nx.json file.

Now let's change where the vite:build results are output to in the vite.config.ts file.

vite.config.ts
1import { fileURLToPath, URL } from 'node:url' 2 3import { defineConfig } from 'vite' 4import vue from '@vitejs/plugin-vue' 5import vueJsx from '@vitejs/plugin-vue-jsx' 6 7// https://vitejs.dev/config/ 8export default defineConfig({ 9 plugins: [vue(), vueJsx()], 10 build: { 11 outDir: 'dist/vue-app' 12 }, 13 resolve: { 14 alias: { 15 '@': fileURLToPath(new URL('./src', import.meta.url)) 16 } 17 } 18}) 19

Now if you look at project details view again, you'll see that the outputs property for Nx's caching has been updated to stay in sync with the setting in the vite.config.ts file.

You can also add the @nx/eslint plugin to see how it infers lint tasks based on the ESLint configuration files.

1npx nx add @nx/eslint 2

Creating New Components

You can just create new Vue components as you normally would. However, Nx plugins also ship generators. They allow you to easily scaffold code, configuration or entire projects. Let's add the @nx/vue plugin to take advantage of the generators it provides.

1npx nx add @nx/vue 2

To see what capabilities the @nx/vue plugin ships, run the following command and inspect the output:

~/vue-app

npx nx list @nx/vue

1 2NX Capabilities in @nx/vue: 3 4 GENERATORS 5 6 init : Initialize the `@nx/vue` plugin. 7 application : Create a Vue application. 8 library : Create a Vue library. 9 component : Create a Vue component. 10 setup-tailwind : Set up Tailwind configuration for a project. 11 storybook-configuration : Set up storybook for a Vue app or library. 12 stories : Create stories for all components declared in an app or library. 13
Prefer a more visual UI?

If you prefer a more integrated experience, you can install the "Nx Console" extension for your code editor. It has support for VSCode, IntelliJ and ships a LSP for Vim. Nx Console provides autocompletion support in Nx configuration files and has UIs for browsing and running generators.

More info can be found in the editor setup page.

Run the following command to generate a new "BaseButton" component. Note how we append --dry-run to first check the output.

~/vue-app

npx nx g @nx/vue:component BaseButton --no-export --skipTests --directory=src/components --dry-run

1 NX Generating @nx/vue:component 2 3✔ Where should the component be generated? · src/components/BaseButton.vue 4CREATE src/components/BaseButton.vue 5 6NOTE: The "dryRun" flag means no changes were made. 7

As you can see it generates a new component in the src/components/ folder. If you want to actually run the generator, remove the --dry-run flag.

src/components/BaseButton.vue
1<script setup lang="ts"> 2// defineProps<{}>() 3</script> 4 5<template> 6 <p>Welcome to BaseButton!</p> 7</template> 8 9<style scoped></style> 10

You're ready to go!

In the previous sections you learned about the basics of using Nx, running tasks and navigating an Nx workspace. You're ready to ship features now!

But there's more to learn. You have two possibilities here:

Modularize your Vue App with Local Libraries

When you develop your Vue application, usually all your logic sits in the src folder. Ideally separated by various folder names which represent your "domains". As your app grows, this becomes more and more monolithic though.

1└─ vue-app 2 ├─ ... 3 ├─ src 4 │ ├─ views 5 │ │ ├─ products 6 │ │ └─ cart 7 │ ├─ components 8 │ │ ├─ ui 9 │ │ └─ ... 10 │ ├─ App.vue 11 │ └─ main.ts 12 ├─ ... 13 ├─ package.json 14 ├─ ... 15

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

Create a Local Library

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 these areas using the Vue library generator:

1nx g @nx/vue:library products --unitTestRunner=vitest --bundler=vite --directory=modules/products --component 2

Note how we use the --directory flag to place the library into a subfolder. You can choose whatever folder structure you like to organize your libraries.

Nx tries to set up your workspace to work with the modular library architecture, but depending on your existing configuration, you may need to tweak some settings. In this repo, you'll need to do a few things in order to prepare for future steps.

Lint Settings

We want the lint task for the root vue-app project to only lint the files for that project, so we'll change the lint command in package.json:

package.json
1{ 2 "scripts": { 3 "lint": "eslint src --ext .vue,.js,.jsx,.cjs,.mjs,.ts,.tsx,.cts,.mts --fix --ignore-path .gitignore" 4 } 5} 6

Now we need to update the .eslintrc.cjs file to extend the .eslintrc.base.json file:

.eslintrc.cjs
1/* eslint-env node */ 2require('@rushstack/eslint-patch/modern-module-resolution'); 3 4module.exports = { 5 root: true, 6 extends: [ 7 'plugin:vue/vue3-essential', 8 'eslint:recommended', 9 '@vue/eslint-config-typescript', 10 '@vue/eslint-config-prettier/skip-formatting', 11 './.eslintrc.base.json', 12 ], 13 ignorePatterns: ['!**/*'], 14 overrides: [ 15 { 16 files: ['e2e/**/*.{test,spec}.{js,ts,jsx,tsx}'], 17 extends: ['plugin:playwright/recommended'], 18 }, 19 ], 20 parserOptions: { 21 ecmaVersion: 'latest', 22 }, 23}; 24

Build Settings

To make sure that the build can correctly pull in code from libraries, we need to move the typescript paths from the tsconfig.app.json file to the newly created tsconfig.base.json and extend that base file.

tsconfig.app.json
1{ 2 "extends": ["@vue/tsconfig/tsconfig.dom.json", "./tsconfig.base.json"], 3 "include": ["env.d.ts", "src/**/*", "src/**/*.vue"], 4 "exclude": ["src/**/__tests__/*"] 5} 6
tsconfig.vitest.json
1{ 2 "extends": "./tsconfig.app.json", 3 "exclude": [], 4 "compilerOptions": { 5 "lib": [], 6 "types": ["node", "jsdom"] 7 } 8} 9
tsconfig.base.json
1{ 2 "compileOnSave": false, 3 "compilerOptions": { 4 "baseUrl": ".", 5 "paths": { 6 "@/*": ["./src/*"], 7 "products": ["modules/products/src/index.ts"] 8 } 9 } 10} 11

We also need to update vite.config.ts to account for typescript aliases. Run the following generator to automatically update your configuration file.

npx nx g @nx/vite:setup-paths-plugin

This will update the vite.config.ts file to include the nxViteTsPaths plugin in the plugins array.

vite.config.ts
1import { fileURLToPath, URL } from 'node:url'; 2 3import { defineConfig } from 'vite'; 4import vue from '@vitejs/plugin-vue'; 5import vueJsx from '@vitejs/plugin-vue-jsx'; 6import { nxViteTsPaths } from '@nx/vite/plugins/nx-tsconfig-paths.plugin'; 7 8// https://vitejs.dev/config/ 9export default defineConfig({ 10 plugins: [vue(), vueJsx(), nxViteTsPaths()], 11 build: { 12 outDir: 'dist/vue-app', 13 }, 14 resolve: { 15 alias: { 16 '@': fileURLToPath(new URL('./src', import.meta.url)), 17 }, 18 }, 19}); 20

Create More Libraries

Now that the repository is set up, let's generate the orders and ui libraries.

1nx g @nx/vue:library orders --unitTestRunner=vitest --bundler=vite --directory=modules/orders --component 2nx g @nx/vue:library ui --unitTestRunner=vitest --bundler=vite --directory=modules/shared/ui --component 3

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

1└─ vue-app 2 ├─ ... 3 ├─ e2e/ 4 ├─ modules 5 │ ├─ products 6 │ │ ├─ .eslintrc.json 7 │ │ ├─ README.md 8 │ │ ├─ vite.config.ts 9 │ │ ├─ package.json 10 │ │ ├─ project.json 11 │ │ ├─ src 12 │ │ │ ├─ index.ts 13 │ │ │ └─ lib 14 │ │ │ ├─ products.spec.ts 15 │ │ │ └─ products.vue 16 │ │ ├─ tsconfig.json 17 │ │ ├─ tsconfig.lib.json 18 │ │ ├─ tsconfig.spec.json 19 │ │ └─ vite.config.ts 20 │ ├─ orders 21 │ │ ├─ ... 22 │ │ ├─ project.json 23 │ │ ├─ src 24 │ │ │ ├─ index.ts 25 │ │ │ └─ ... 26 │ │ └─ ... 27 │ └─ shared 28 │ └─ ui 29 │ ├─ ... 30 │ ├─ project.json 31 │ ├─ src 32 │ │ ├─ index.ts 33 │ │ └─ ... 34 │ └─ ... 35 ├─ src 36 │ ├─ components 37 │ ├─ ... 38 │ ├─ App.vue 39 │ └─ main.tsx 40 ├─ ... 41

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 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 Vue Application

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

tsconfig.base.json
1{ 2 "compilerOptions": { 3 ... 4 "paths": { 5 "@/*": ["./src/*"], 6 "orders": ["modules/orders/src/index.ts"], 7 "products": ["modules/products/src/index.ts"], 8 "ui": ["modules/shared/ui/src/index.ts"] 9 }, 10 ... 11 }, 12} 13

That way we can easily import them into other libraries and our Vue application. As an example, let's import the Products component from the products project into our main application. First, configure the router in the src/router/index.ts.

src/router/index.ts
1import { createRouter, createWebHistory } from 'vue-router'; 2import HomeView from '../views/HomeView.vue'; 3 4const router = createRouter({ 5 history: createWebHistory(import.meta.env.BASE_URL), 6 routes: [ 7 { 8 path: '/', 9 name: 'home', 10 component: HomeView, 11 }, 12 { 13 path: '/about', 14 name: 'about', 15 // route level code-splitting 16 // this generates a separate chunk (About.[hash].js) for this route 17 // which is lazy-loaded when the route is visited. 18 component: () => import('../views/AboutView.vue'), 19 }, 20 { 21 path: '/products', 22 name: 'products', 23 component: () => import('products').then((m) => m.Products), 24 }, 25 { 26 path: '/orders', 27 name: 'orders', 28 component: () => import('orders').then((m) => m.Orders), 29 }, 30 ], 31}); 32 33export default router; 34

Then we can add links to the routes in App.vue.

src/App.vue
1<script setup lang="ts"> 2import { RouterLink, RouterView } from 'vue-router' 3import HelloWorld from './components/HelloWorld.vue' 4</script> 5 6<template> 7 <header> 8 <img alt="Vue logo" class="logo" src="@/assets/logo.svg" width="125" height="125" /> 9 10 <div class="wrapper"> 11 <HelloWorld msg="You did it!" /> 12 13 <nav> 14 <RouterLink to="/">Home</RouterLink> 15 <RouterLink to="/about">About</RouterLink> 16 <RouterLink to="/products">Products</RouterLink> 17 <RouterLink to="/orders">Orders</RouterLink> 18 </nav> 19 </div> 20 </header> 21 22 <RouterView /> 23</template> 24 25... 26

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

products route

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:

nx graph

You should be able to see something similar to the following in your browser (hint: click the "Show all projects" button).

Loading...

Notice how ui is not yet connected to anything because we didn't import it in any of our projects. Also the arrows to orders and products are dashed because we're using lazy imports.

Exercise for you: change the codebase so that ui is used by orders and products.

Imposing Constraints with Module Boundary Rules

Once you modularize your codebase you want to make sure that the modules 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 (see library types)
  • 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.

modules/orders/project.json
1{ 2 ... 3 "tags": ["type:feature", "scope:orders"], 4 ... 5} 6

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

modules/products/project.json
1{ 2 ... 3 "tags": ["type:feature", "scope:products"], 4 ... 5} 6

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

modules/shared/ui/project.json
1{ 2 ... 3 "tags": ["type:ui", "scope:shared"], 4 ... 5} 6

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.

Lint Settings

We want the lint task for the root react-app project to only lint the files for that project (in the src folder), so we'll change the lint command in package.json:

package.json
1{ 2 "scripts": { 3 "lint": "eslint src --ext .vue,.js,.jsx,.cjs,.mjs,.ts,.tsx,.cts,.mts --fix --ignore-path .gitignore" 4 } 5} 6

We need to update the .eslintrc.cjs file to extend the .eslintrc.base.json file and undo the ignorePattern from that config that ignores every file. The .eslintrc.base.json file serves as a common set of lint rules for every project in the repository.

.eslintrc.cjs
1/* eslint-env node */ 2require('@rushstack/eslint-patch/modern-module-resolution'); 3 4module.exports = { 5 root: true, 6 extends: [ 7 'plugin:vue/vue3-essential', 8 'eslint:recommended', 9 '@vue/eslint-config-typescript', 10 '@vue/eslint-config-prettier/skip-formatting', 11 './.eslintrc.base.json', 12 ], 13 ignorePatterns: ['!**/*'], 14 overrides: [ 15 { 16 files: ['e2e/**/*.{test,spec}.{js,ts,jsx,tsx}'], 17 extends: ['plugin:playwright/recommended'], 18 }, 19 ], 20 parserOptions: { 21 ecmaVersion: 'latest', 22 }, 23}; 24

Now we need to update the .eslintrc.base.json file and define the depConstraints in the @nx/enforce-module-boundaries rule:

.eslintrc.base.json
1{ 2 "overrides": [ 3 { 4 "files": ["*.ts", "*.tsx", "*.js", "*.jsx"], 5 "rules": { 6 "@nx/enforce-module-boundaries": [ 7 "error", 8 { 9 "enforceBuildableLibDependency": true, 10 "allow": [], 11 "depConstraints": [ 12 { 13 "sourceTag": "*", 14 "onlyDependOnLibsWithTags": ["*"] 15 }, 16 { 17 "sourceTag": "type:feature", 18 "onlyDependOnLibsWithTags": ["type:feature", "type:ui"] 19 }, 20 { 21 "sourceTag": "type:ui", 22 "onlyDependOnLibsWithTags": ["type:ui"] 23 }, 24 { 25 "sourceTag": "scope:orders", 26 "onlyDependOnLibsWithTags": [ 27 "scope:orders", 28 "scope:products", 29 "scope:shared" 30 ] 31 }, 32 { 33 "sourceTag": "scope:products", 34 "onlyDependOnLibsWithTags": ["scope:products", "scope:shared"] 35 }, 36 { 37 "sourceTag": "scope:shared", 38 "onlyDependOnLibsWithTags": ["scope:shared"] 39 } 40 ] 41 } 42 ] 43 } 44 } 45 ... 46 ] 47} 48

When Nx set up the @nx/eslint plugin, it chose a task name that would not conflict with the pre-existing lint script. Let's overwrite that name so that all the linting tasks use the same lint name. Update the setting in the nx.json file:

nx.json
1{ 2 ... 3 "plugins": [ 4 { 5 "plugin": "@nx/eslint/plugin", 6 "options": { 7 "targetName": "lint" 8 } 9 } 10 ] 11} 12

Test Boundary Rules

To test the boundary rules, go to your modules/products/src/lib/products.tsx file and import the Orders from the orders project:

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

modules/products/src/lib/products.vue
1<script setup lang="ts"> 2defineProps<{}>(); 3 4// 👇 this import is not allowed 5import { Orders } from 'orders'; 6</script> 7 8<template> 9 <p>Welcome to Products!</p> 10</template> 11 12<style scoped></style> 13

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

nx run-many -t lint

1 ✔ nx run ui:lint [existing outputs match the cache, left as is] 2 ✔ nx run orders:lint [existing outputs match the cache, left as is] 3 4—————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————— 5 ✖ nx run products:lint 6 > eslint . 7 8 ~/vue-app/modules/products/src/lib/products.vue 9 5:1 error A project tagged with "scope:products" can only depend on libs tagged with "scope:products", "scope:shared" @nx/enforce-module-boundaries 10 111 problem (1 error, 0 warnings) 12 13 ✔ nx run vue-app:lint (892ms) 14 ✔ nx run vue-app:lint (1s) 15 16—————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————————— 17 18 NX Ran targets lint for 4 projects (1s) 19 204/5 succeeded [2 read from cache] 21 221/5 targets failed, including the following: 23 24 - nx run products:lint 25

Learn more about how to enforce module boundaries.

Migrating to a Monorepo

When you are ready to add another application to the repo, you'll probably want to move myvueapp to its own folder. To do this, you can run the convert-to-monorepo generator or manually move the configuration files.

Set Up CI for Your Vue App

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.

Generate a CI Workflow

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

npx nx generate ci-workflow --ci=github

Choose your CI provider

You can choose github, circleci, azure, bitbucket-pipelines, or gitlab for the ci flag.

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:

1- run: npx nx affected -t lint test build e2e-ci 2

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:

npx nx connect

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.

1- run: npx nx-cloud start-ci-run --distribute-on="5 linux-medium-js" --stop-agents-after="e2e-ci" 2

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

Next Steps

Connect with the rest of the Nx community with these resources: