Project Configuration
A project's configuration is constructed by Nx from three sources:
- Tasks inferred by Nx plugins from tooling configuration
- Workspace
targetDefaults
defined in thenx.json
file - Individual project level configuration files (
package.json
andproject.json
)
Each source will overwrite the previous source. That means targetDefaults
will overwrite inferred tasks and project level configuration will overwrite both targetDefaults
and inferred tasks. The combined project configuration can be viewed in the project details view by using Nx Console in your IDE or by running:
❯
nx show project myproject --web
demo
Root: packages/demo
Type:application
Targets
build
vite build
dev
vite dev
The project details view also shows where each setting is defined so that you know where to change it.
Project Level Configuration Files
If you need to edit your project settings or modify an inferred task, you can do so in either package.json
or project.json
files. The examples on this page show both styles, and the only functional difference is that tasks that use executors must be defined in a project.json
. Nx merges the two files to get each project's configuration. The full machine readable schema is available on GitHub.
The following configuration creates build
and test
targets for Nx.
1{
2 "name": "mylib",
3 "scripts": {
4 "test": "jest",
5 "build": "tsc -p tsconfig.lib.json" // the actual command here is arbitrary
6 }
7}
8
You can invoke nx build mylib
or nx test mylib
without any extra configuration.
Below are some more complete examples of project configuration files. For a more intuitive understanding of the roles of each option, you can highlight the options in the excerpt below that relate to different categories. Orchestration settings control the way Nx runs tasks. Execution settings control the actual task that is run. Caching settings control when Nx caches a task and what is actually cached.
1{
2 "name": "mylib",
3 "scripts": {
4 "test": "jest",
5 "build": "tsc -p tsconfig.lib.json", // the actual command here is arbitrary
6 "ignored": "exit 1"
7 },
8 "nx": {
9 "namedInputs": {
10 "default": ["{projectRoot}/**/*"],
11 "production": ["!{projectRoot}/**/*.spec.tsx"]
12 },
13 "targets": {
14 "build": {
15 "inputs": ["production", "^production"],
16 "outputs": ["{workspaceRoot}/dist/libs/mylib"],
17 "dependsOn": ["^build"]
18 },
19 "test": {
20 "inputs": ["default", "^production"],
21 "outputs": [],
22 "dependsOn": ["build"]
23 }
24 },
25 "includedScripts": ["test", "build"] // If you want to limit the scripts Nx sees, you can specify a list here.
26 }
27}
28
Task Definitions (Targets)
A large portion of project configuration is related to defining the tasks for the project. In addition, to defining what the task actually does, a task definition also has properties that define the way that Nx should run that task. Those properties are described in detail below.
Cache
In Nx 17 and higher, caching is configured by specifying "cache": true
in a target's configuration. This will tell Nx that it's ok to cache the results of a given target. For instance, if you have a target that runs tests, you can specify "cache": true
in the target default configuration for test
and Nx will cache the results of running tests.
1{
2 "targets": {
3 "test": {
4 "cache": true
5 }
6 }
7}
8
If you are using distributed task execution and disable caching for a given target, you will not be able to use distributed task execution for that target. This is because distributed task execution requires caching to be enabled. This means that the target you have disabled caching for, and any targets which depend on that target will fail the pipeline if you try to run them with Nx Agents enabled.
Parallelism
In Nx 19.5.0+, tasks can be configured to support parallelism or not. By default, tasks are run in parallel with other tasks on a given machine. However, in some cases, tasks can require a shared resource such as a port or memory. For these cases, setting "parallelism": false
, will ensure that those tasks will not run in parallel with other tasks on a single machine. For example, if the e2e
tasks all require port 4200, running them in parallel will conflict so the targets can specify to not support parallelism:
1{
2 "targets": {
3 "e2e": {
4 "parallelism": false
5 }
6 }
7}
8
If you are using distributed task execution, tasks will still be run simultaneously on different machines. Because different agents do not share resources with one another, it is perfectly fine for multiple agents to run tasks which do not support parallelism at the same time. Therefore, using Nx Agents is key to running tasks which do not support parallelism quickly and efficiently.
Inputs and Named Inputs
Each cacheable task needs to define inputs
which determine whether the task outputs can be retrieved from the cache or the task needs to be re-run. The namedInputs
defined in nx.json
or project level configuration are sets of reusable input definitions.
A typical set of inputs may look like this:
1{
2 "namedInputs": {
3 "default": ["{projectRoot}/**/*"], // every file in the project
4 "production": ["default", "!{projectRoot}/**/*.spec.tsx"] // except test files
5 },
6 "targets": {
7 "build": {
8 "inputs": [
9 "production", // this project's production files
10 { "externalDependencies": ["vite"] } // the version of the vite package
11 ]
12 }
13 }
14}
15
Learn about all the possible settings for `inputs` and `namedInputs`
This recipes walks you through a few examples of how to configure `inputs` and `namedInputs`
Outputs
Targets may define outputs to tell Nx where the target is going to create file artifacts that Nx should cache. "outputs": ["{workspaceRoot}/dist/libs/mylib"]
tells Nx where the build
target is going to create file artifacts.
This configuration is usually not needed. Nx comes with reasonable defaults (imported in nx.json
) which implement the configuration above.
Specifically, by default, the following locations are cached for builds:
{workspaceRoot}/dist/{projectRoot}
,{projectRoot}/build
,{projectRoot}/dist
,{projectRoot}/public
Read the configure outputs for task caching recipe for helpful tips for setting outputs.
Basic Example
Usually, a target writes to a specific directory or a file. The following instructs Nx to cache dist/libs/mylib
and build/libs/mylib/main.js
:
1{
2 "targets": {
3 "build": {
4 "outputs": [
5 "{workspaceRoot}/dist/libs/mylib",
6 "{workspaceRoot}/build/libs/mylib/main.js"
7 ]
8 }
9 }
10}
11
Specifying Globs
Sometimes, multiple targets might write to the same directory. When possible it is recommended to direct these targets into separate directories.
1{
2 "targets": {
3 "build-js": {
4 "outputs": ["{workspaceRoot}/dist/libs/mylib/js"]
5 },
6 "build-css": {
7 "outputs": ["{workspaceRoot}/dist/libs/mylib/css"]
8 }
9 }
10}
11
But if the above is not possible, globs (parsed by the GlobSet Rust library) can be specified as outputs to only cache a set of files rather than the whole directory.
1{
2 "targets": {
3 "build-js": {
4 "outputs": ["{workspaceRoot}/dist/libs/mylib/**/*.{js,map}"]
5 },
6 "build-css": {
7 "outputs": ["{workspaceRoot}/dist/libs/mylib/**/*.css"]
8 }
9 }
10}
11
More advanced patterns can be used to exclude files and folders in a single line
1{
2 "targets": {
3 "build-js": {
4 "outputs": ["{workspaceRoot}/dist/libs/!(cache|.next)/**/*.{js,map}"]
5 },
6 "build-css": {
7 "outputs": ["{workspaceRoot}/dist/libs/mylib/**/!(secondary).css"]
8 }
9 }
10}
11
dependsOn
Targets can depend on other targets. This is the relevant portion of the configuration file:
1{
2 "targets": {
3 "build": {
4 "dependsOn": ["^build"]
5 },
6 "test": {
7 "dependsOn": ["build"]
8 }
9 }
10}
11
A common scenario is having to build dependencies of a project first before building the project. This is what the "dependsOn": ["^build"]
property of the build
target configures. It tells Nx that before it can build mylib
it needs to make sure that mylib
's dependencies are built as well. This doesn't mean Nx is going to rerun those builds. If the right artifacts are already in the right place, Nx will do nothing. If they aren't in the right place, but they are available in the cache, Nx will retrieve them from the cache.
Another common scenario is for a target to depend on another target of the same project. For instance, "dependsOn": ["build"]
of the test
target tells Nx that before it can test mylib
it needs to make sure that mylib
is built, which will result in mylib
's dependencies being built as well.
You can also express task dependencies with an object syntax:
1{
2 "targets": {
3 "test": {
4 "dependsOn": [
5 {
6 "target": "build", // target name
7 "params": "ignore" // "forward" or "ignore", defaults to "ignore"
8 }
9 ]
10 }
11 }
12}
13
Starting from v19.5.0, wildcards can be used to define dependencies in the dependsOn
field.
1{
2 "targets": {
3 "test": {
4 "dependsOn": [
5 {
6 "target": "build", // target name
7 "params": "ignore" // "forward" or "ignore", defaults to "ignore"
8 },
9 "build-*", // support for using wildcards in dependsOn, matches: "build-css", "build-js" targets of current project
10 "^build-*", // matches tasks: "build-css", "build-js" targets of dependencies
11 "*build-*", // matches tasks: "build-css", "build-js" as well as "task-with-build-in-middle" targets of current project
12 "^*build-*" // matches tasks: "build-css", "build-js" as well as "task-with-build-in-middle" targets of dependencies
13 ]
14 }
15 }
16}
17
Examples
You can write the shorthand configuration above in the object syntax like this:
1{
2 "targets": {
3 "build": {
4 "dependsOn": [{ "dependencies": true, "target": "build" }] // Run build on my dependencies first
5 },
6 "test": {
7 "dependsOn": [{ "target": "build" }] // Run build on myself first
8 }
9 }
10}
11
With the expanded syntax, you also have a third option available to configure how to handle the params passed to the target. You can either forward them or you can ignore them (default).
1{
2 "targets": {
3 "build": {
4 // forward params passed to this target to the dependency targets
5 "dependsOn": [
6 { "projects": "{dependencies}", "target": "build", "params": "forward" }
7 ]
8 },
9 "test": {
10 // ignore params passed to this target, won't be forwarded to the dependency targets
11 "dependsOn": [
12 { "projects": "{dependencies}", "target": "build", "params": "ignore" }
13 ]
14 },
15 "lint": {
16 // ignore params passed to this target, won't be forwarded to the dependency targets
17 "dependsOn": [{ "projects": "{dependencies}", "target": "build" }]
18 }
19 }
20}
21
This also works when defining a relation for the target of the project itself using "projects": "self"
:
1{
2 "targets": {
3 "build": {
4 // forward params passed to this target to the project target
5 "dependsOn": [{ "target": "pre-build", "params": "forward" }]
6 }
7 }
8}
9
Additionally, when using the expanded object syntax, you can specify individual projects in version 16 or greater.
1{
2 "targets": {
3 "build": {
4 // Run is-even:pre-build and is-odd:pre-build before this target
5 "dependsOn": [
6 { "projects": ["is-even", "is-odd"], "target": "pre-build" }
7 ]
8 }
9 }
10}
11
This configuration is usually not needed. Nx comes with reasonable defaults (imported in nx.json
) which implement the configuration above.
Executor/command options
To define what a task does, you must configure which command or executor will run when the task is executed. In the case of inferred tasks you can provide project-specific overrides. As an example, if your repo has projects with a build
inferred target running the vite build
command, you can provide some extra options as follows:
1{
2 "targets": {
3 "build": {
4 "options": {
5 "assetsInlineLimit": 2048,
6 "assetsDir": "static/assets"
7 }
8 }
9 }
10}
11
For more details on how to pass args to the underlying command see the Pass Args to Commands recipe.
In the case of an explicit target using an executor, you can specify the executor and the options specific to that executor as follows:
1{
2 "targets": {
3 "build": {
4 "executor": "@nx/js:tsc",
5 "options": {
6 "generateExportsField": true
7 }
8 }
9 }
10}
11
Project Metadata
The following properties describe the project as a whole.
tags
You can annotate your projects with tags
as follows:
1{
2 "name": "mylib",
3 "nx": {
4 "tags": ["scope:myteam"]
5 }
6}
7
You can configure lint rules using these tags to, for instance, ensure that libraries belonging to myteam
are not depended on by libraries belong to theirteam
.
implicitDependencies
Nx uses powerful source-code analysis to figure out your workspace's project graph. Some dependencies cannot be deduced statically, so you can set them manually like this. The implicitDependencies
property is parsed with the minimatch library, so you can review that syntax for more advanced use cases.
1{
2 "name": "mylib",
3 "nx": {
4 "implicitDependencies": ["anotherlib"]
5 }
6}
7
You can also remove a dependency as follows:
1{
2 "name": "mylib",
3 "nx": {
4 "implicitDependencies": ["!anotherlib"] # regardless of what Nx thinks, "mylib" doesn't depend on "anotherlib"
5 }
6}
7
An implicit dependency could also be a glob pattern:
1{
2 "name": "mylib",
3 "nx": {
4 "implicitDependencies": ["shop-*"] # "mylib" depends on all projects beginning with "shop-"
5 }
6}
7
Including package.json files as projects in the graph
Any package.json
file that is referenced by the workspaces
property in the root package.json
file will be included as a project in the graph. If you are using Lerna, projects defined in lerna.json
will be included. If you are using pnpm, projects defined in pnpm-workspace.yml
will be included.
If you want to ignore a particular package.json
file, exclude it from those tools. For example, you can add !packages/myproject
to the workspaces
property.
Ignoring package.json scripts
Nx merges package.json
scripts with any targets defined in project.json
. If you only wish for some scripts to be used as Nx targets, you can specify them in the includedScripts
property of the project's package.json
.
1{
2 "name": "my-library",
3 "version": "0.0.1",
4 "scripts": {
5 "build": "tsc",
6 "postinstall": "node ./tasks/postinstall"
7 },
8 "nx": {
9 "includedScripts": ["build"]
10 }
11}
12