Specifics of npm's package.json handling
This document is all you need to know about what's required in your package.json file. It must be actual JSON, not just a JavaScript object literal.
A lot of the behavior described in this document is affected by the config
settings described in npm-config(7)
.
The most important things in your package.json are the name and version fields. Those are actually required, and your package won't install without them. The name and version together form an identifier that is assumed to be completely unique. Changes to the package should come along with changes to the version.
The name is what your thing is called.
Some rules:
Some tips:
A name can be optionally prefixed by a scope, e.g. @myorg/mypackage
. See
npm-scope(7)
for more detail.
The most important things in your package.json are the name and version fields. Those are actually required, and your package won't install without them. The name and version together form an identifier that is assumed to be completely unique. Changes to the package should come along with changes to the version.
Version must be parseable by
node-semver, which is bundled
with npm as a dependency. (npm install semver
to use it yourself.)
More on version numbers and ranges at semver(7).
Put a description in it. It's a string. This helps people discover your
package, as it's listed in npm search
.
Put keywords in it. It's an array of strings. This helps people
discover your package as it's listed in npm search
.
The url to the project homepage.
The url to your project's issue tracker and / or the email address to which issues should be reported. These are helpful for people who encounter issues with your package.
It should look like this:
{ "url" : "https://github.com/owner/project/issues"
, "email" : "project@hostname.com"
}
You can specify either one or both values. If you want to provide only a url, you can specify the value for "bugs" as a simple string instead of an object.
If a url is provided, it will be used by the npm bugs
command.
You should specify a license for your package so that people know how they are permitted to use it, and any restrictions you're placing on it.
If you're using a common license such as BSD-2-Clause or MIT, add a current SPDX license identifier for the license you're using, like this:
{ "license" : "BSD-3-Clause" }
You can check the full list of SPDX license IDs. Ideally you should pick one that is OSI approved.
If your package is licensed under multiple common licenses, use an SPDX license expression syntax version 2.0 string, like this:
{ "license" : "(ISC OR GPL-3.0)" }
If you are using a license that hasn't been assigned an SPDX identifier, or if you are using a custom license, use a string value like this one:
{ "license" : "SEE LICENSE IN <filename>" }
Then include a file named <filename>
at the top level of the package.
Some old packages used license objects or a "licenses" property containing an array of license objects:
// Not valid metadata
{ "license" :
{ "type" : "ISC"
, "url" : "https://opensource.org/licenses/ISC"
}
}
// Not valid metadata
{ "licenses" :
[
{ "type": "MIT"
, "url": "https://www.opensource.org/licenses/mit-license.php"
}
, { "type": "Apache-2.0"
, "url": "https://opensource.org/licenses/apache2.0.php"
}
]
}
Those styles are now deprecated. Instead, use SPDX expressions, like this:
{ "license": "ISC" }
{ "license": "(MIT OR Apache-2.0)" }
Finally, if you do not wish to grant others the right to use a private or unpublished package under any terms:
{ "license": "UNLICENSED" }
Consider also setting "private": true
to prevent accidental publication.
The "author" is one person. "contributors" is an array of people. A "person" is an object with a "name" field and optionally "url" and "email", like this:
{ "name" : "Barney Rubble"
, "email" : "b@rubble.com"
, "url" : "http://barnyrubble.tumblr.com/"
}
Or you can shorten that all into a single string, and npm will parse it for you:
"Barney Rubble <b@rubble.com> (http://barnyrubble.tumblr.com/)"
Both email and url are optional either way.
npm also sets a top-level "maintainers" field with your npm user info.
The optional "files" field is an array of file patterns that describes the entries to be included when your package is installed as a dependency. If the files array is omitted, everything except automatically-excluded files will be included in your publish. If you name a folder in the array, then it will also include the files inside that folder (unless they would be ignored by another rule in this section.).
You can also provide a .npmignore
file in the root of your package or
in subdirectories, which will keep files from being included. At the
root of your package it will not override the "files" field, but in
subdirectories it will. The .npmignore
file works just like a
.gitignore
. If there is a .gitignore
file, and .npmignore
is
missing, .gitignore
's contents will be used instead.
Files included with the "package.json#files" field cannot be excluded
through .npmignore
or .gitignore
.
Certain files are always included, regardless of settings:
package.json
README
CHANGES
/ CHANGELOG
/ HISTORY
LICENSE
/ LICENCE
NOTICE
README
, CHANGES
, LICENSE
& NOTICE
can have any case and extension.
Conversely, some files are always ignored:
.git
CVS
.svn
.hg
.lock-wscript
.wafpickle-N
.*.swp
.DS_Store
._*
npm-debug.log
.npmrc
node_modules
config.gypi
*.orig
package-lock.json
(use shrinkwrap instead)The main field is a module ID that is the primary entry point to your program.
That is, if your package is named foo
, and a user installs it, and then does
require("foo")
, then your main module's exports object will be returned.
This should be a module ID relative to the root of your package folder.
For most modules, it makes the most sense to have a main script and often not much else.
A lot of packages have one or more executable files that they'd like to install into the PATH. npm makes this pretty easy (in fact, it uses this feature to install the "npm" executable.)
To use this, supply a bin
field in your package.json which is a map of
command name to local file name. On install, npm will symlink that file into
prefix/bin
for global installs, or ./node_modules/.bin/
for local
installs.
For example, myapp could have this:
{ "bin" : { "myapp" : "./cli.js" } }
So, when you install myapp, it'll create a symlink from the cli.js
script to
/usr/local/bin/myapp
.
If you have a single executable, and its name should be the name of the package, then you can just supply it as a string. For example:
{ "name": "my-program"
, "version": "1.2.5"
, "bin": "./path/to/program" }
would be the same as this:
{ "name": "my-program"
, "version": "1.2.5"
, "bin" : { "my-program" : "./path/to/program" } }
Please make sure that your file(s) referenced in bin
starts with
#!/usr/bin/env node
, otherwise the scripts are started without the node
executable!
Specify either a single file or an array of filenames to put in place for the
man
program to find.
If only a single file is provided, then it's installed such that it is the
result from man <pkgname>
, regardless of its actual filename. For example:
{ "name" : "foo"
, "version" : "1.2.3"
, "description" : "A packaged foo fooer for fooing foos"
, "main" : "foo.js"
, "man" : "./man/doc.1"
}
would link the ./man/doc.1
file in such that it is the target for man foo
If the filename doesn't start with the package name, then it's prefixed. So, this:
{ "name" : "foo"
, "version" : "1.2.3"
, "description" : "A packaged foo fooer for fooing foos"
, "main" : "foo.js"
, "man" : [ "./man/foo.1", "./man/bar.1" ]
}
will create files to do man foo
and man foo-bar
.
Man files must end with a number, and optionally a .gz
suffix if they are
compressed. The number dictates which man section the file is installed into.
{ "name" : "foo"
, "version" : "1.2.3"
, "description" : "A packaged foo fooer for fooing foos"
, "main" : "foo.js"
, "man" : [ "./man/foo.1", "./man/foo.2" ]
}
will create entries for man foo
and man 2 foo
The CommonJS Packages spec details a
few ways that you can indicate the structure of your package using a directories
object. If you look at npm's package.json,
you'll see that it has directories for doc, lib, and man.
In the future, this information may be used in other creative ways.
Tell people where the bulk of your library is. Nothing special is done with the lib folder in any way, but it's useful meta info.
If you specify a bin
directory in directories.bin
, all the files in
that folder will be added.
Because of the way the bin
directive works, specifying both a
bin
path and setting directories.bin
is an error. If you want to
specify individual files, use bin
, and for all the files in an
existing bin
directory, use directories.bin
.
A folder that is full of man pages. Sugar to generate a "man" array by walking the folder.
Put markdown files in here. Eventually, these will be displayed nicely, maybe, someday.
Put example scripts in here. Someday, it might be exposed in some clever way.
Put your tests in here. It is currently not exposed, but it might be in the future.
Specify the place where your code lives. This is helpful for people who
want to contribute. If the git repo is on GitHub, then the npm docs
command will be able to find you.
Do it like this:
"repository" :
{ "type" : "git"
, "url" : "https://github.com/npm/npm.git"
}
"repository" :
{ "type" : "svn"
, "url" : "https://v8.googlecode.com/svn/trunk/"
}
The URL should be a publicly available (perhaps read-only) url that can be handed directly to a VCS program without any modification. It should not be a url to an html project page that you put in your browser. It's for computers.
For GitHub, GitHub gist, Bitbucket, or GitLab repositories you can use the same
shortcut syntax you use for npm install
:
"repository": "npm/npm"
"repository": "github:user/repo"
"repository": "gist:11081aaa281"
"repository": "bitbucket:user/repo"
"repository": "gitlab:user/repo"
The "scripts" property is a dictionary containing script commands that are run at various times in the lifecycle of your package. The key is the lifecycle event, and the value is the command to run at that point.
See npm-scripts(7)
to find out more about writing package scripts.
A "config" object can be used to set configuration parameters used in package scripts that persist across upgrades. For instance, if a package had the following:
{ "name" : "foo"
, "config" : { "port" : "8080" } }
and then had a "start" command that then referenced the
npm_package_config_port
environment variable, then the user could
override that by doing npm config set foo:port 8001
.
See npm-config(7)
and npm-scripts(7)
for more on package
configs.
Dependencies are specified in a simple object that maps a package name to a version range. The version range is a string which has one or more space-separated descriptors. Dependencies can also be identified with a tarball or git URL.
Please do not put test harnesses or transpilers in your
dependencies
object. See devDependencies
, below.
See semver(7) for more details about specifying version ranges.
version
Must match version
exactly>version
Must be greater than version
>=version
etc<version
<=version
~version
"Approximately equivalent to version" See semver(7)^version
"Compatible with version" See semver(7)1.2.x
1.2.0, 1.2.1, etc., but not 1.3.0http://...
See 'URLs as Dependencies' below*
Matches any version""
(just an empty string) Same as *
version1 - version2
Same as >=version1 <=version2
.range1 || range2
Passes if either range1 or range2 are satisfied.git...
See 'Git URLs as Dependencies' belowuser/repo
See 'GitHub URLs' belowtag
A specific version tagged and published as tag
See npm-dist-tag(1)
path/path/path
See Local Paths belowFor example, these are all valid:
{ "dependencies" :
{ "foo" : "1.0.0 - 2.9999.9999"
, "bar" : ">=1.0.2 <2.1.2"
, "baz" : ">1.0.2 <=2.3.4"
, "boo" : "2.0.1"
, "qux" : "<1.0.0 || >=2.3.1 <2.4.5 || >=2.5.2 <3.0.0"
, "asd" : "http://asdf.com/asdf.tar.gz"
, "til" : "~1.2"
, "elf" : "~1.2.3"
, "two" : "2.x"
, "thr" : "3.3.x"
, "lat" : "latest"
, "dyl" : "file:../dyl"
}
}
You may specify a tarball URL in place of a version range.
This tarball will be downloaded and installed locally to your package at install time.
Git urls are of the form:
<protocol>://[<user>[:<password>]@]<hostname>[:<port>][:][/]<path>[#<commit-ish> | #semver:<semver>]
<protocol>
is one of git
, git+ssh
, git+http
, git+https
, or
git+file
.
If #<commit-ish>
is provided, it will be used to clone exactly that
commit. If the commit-ish has the format #semver:<semver>
, <semver>
can
be any valid semver range or exact version, and npm will look for any tags
or refs matching that range in the remote repository, much as it would for a
registry dependency. If neither #<commit-ish>
or #semver:<semver>
is
specified, then master
is used.
Examples:
git+ssh://git@github.com:npm/npm.git#v1.0.27
git+ssh://git@github.com:npm/npm#semver:^5.0
git+https://isaacs@github.com/npm/npm.git
git://github.com/npm/npm.git#v1.0.27
As of version 1.1.65, you can refer to GitHub urls as just "foo":
"user/foo-project". Just as with git URLs, a commit-ish
suffix can be
included. For example:
{
"name": "foo",
"version": "0.0.0",
"dependencies": {
"express": "expressjs/express",
"mocha": "mochajs/mocha#4727d357ea",
"module": "user/repo#feature\/branch"
}
}
As of version 2.0.0 you can provide a path to a local directory that contains a
package. Local paths can be saved using npm install -S
or
npm install --save
, using any of these forms:
../foo/bar
~/foo/bar
./foo/bar
/foo/bar
in which case they will be normalized to a relative path and added to your
package.json
. For example:
{
"name": "baz",
"dependencies": {
"bar": "file:../foo/bar"
}
}
This feature is helpful for local offline development and creating tests that require npm installing where you don't want to hit an external server, but should not be used when publishing packages to the public registry.
If someone is planning on downloading and using your module in their program, then they probably don't want or need to download and build the external test or documentation framework that you use.
In this case, it's best to map these additional items in a devDependencies
object.
These things will be installed when doing npm link
or npm install
from the root of a package, and can be managed like any other npm
configuration param. See npm-config(7)
for more on the topic.
For build steps that are not platform-specific, such as compiling
CoffeeScript or other languages to JavaScript, use the prepare
script to do this, and make the required package a devDependency.
For example:
{ "name": "ethopia-waza",
"description": "a delightfully fruity coffee varietal",
"version": "1.2.3",
"devDependencies": {
"coffee-script": "~1.6.3"
},
"scripts": {
"prepare": "coffee -o lib/ -c src/waza.coffee"
},
"main": "lib/waza.js"
}
The prepare
script will be run before publishing, so that users
can consume the functionality without requiring them to compile it
themselves. In dev mode (ie, locally running npm install
), it'll
run this script as well, so that you can test it easily.
In some cases, you want to express the compatibility of your package with a
host tool or library, while not necessarily doing a require
of this host.
This is usually referred to as a plugin. Notably, your module may be exposing
a specific interface, expected and specified by the host documentation.
For example:
{
"name": "tea-latte",
"version": "1.3.5",
"peerDependencies": {
"tea": "2.x"
}
}
This ensures your package tea-latte
can be installed along with the second
major version of the host package tea
only. npm install tea-latte
could
possibly yield the following dependency graph:
├── tea-latte@1.3.5
└── tea@2.2.0
NOTE: npm versions 1 and 2 will automatically install peerDependencies
if
they are not explicitly depended upon higher in the dependency tree. In the
next major version of npm (npm@3), this will no longer be the case. You will
receive a warning that the peerDependency is not installed instead. The
behavior in npms 1 & 2 was frequently confusing and could easily put you into
dependency hell, a situation that npm is designed to avoid as much as possible.
Trying to install another plugin with a conflicting requirement will cause an error. For this reason, make sure your plugin requirement is as broad as possible, and not to lock it down to specific patch versions.
Assuming the host complies with semver, only changes in
the host package's major version will break your plugin. Thus, if you've worked
with every 1.x version of the host package, use "^1.0"
or "1.x"
to express
this. If you depend on features introduced in 1.5.2, use ">= 1.5.2 < 2"
.
This defines an array of package names that will be bundled when publishing the package.
In cases where you need to preserve npm packages locally or have them
available through a single file download, you can bundle the packages in a
tarball file by specifying the package names in the bundledDependencies
array and executing npm pack
.
For example:
If we define a package.json like this:
{
"name": "awesome-web-framework",
"version": "1.0.0",
"bundledDependencies": [
"renderized", "super-streams"
]
}
we can obtain awesome-web-framework-1.0.0.tgz
file by running npm pack
.
This file contains the dependencies renderized
and super-streams
which
can be installed in a new project by executing npm install
awesome-web-framework-1.0.0.tgz
.
If this is spelled "bundleDependencies"
, then that is also honored.
If a dependency can be used, but you would like npm to proceed if it cannot be
found or fails to install, then you may put it in the optionalDependencies
object. This is a map of package name to version or url, just like the
dependencies
object. The difference is that build failures do not cause
installation to fail.
It is still your program's responsibility to handle the lack of the dependency. For example, something like this:
try {
var foo = require('foo')
var fooVersion = require('foo/package.json').version
} catch (er) {
foo = null
}
if ( notGoodFooVersion(fooVersion) ) {
foo = null
}
// .. then later in your program ..
if (foo) {
foo.doFooThings()
}
Entries in optionalDependencies
will override entries of the same name in
dependencies
, so it's usually best to only put in one place.
You can specify the version of node that your stuff works on:
{ "engines" : { "node" : ">=0.10.3 <0.12" } }
And, like with dependencies, if you don't specify the version (or if you specify "*" as the version), then any version of node will do.
If you specify an "engines" field, then npm will require that "node" be somewhere on that list. If "engines" is omitted, then npm will just assume that it works on node.
You can also use the "engines" field to specify which versions of npm are capable of properly installing your program. For example:
{ "engines" : { "npm" : "~1.0.20" } }
Unless the user has set the engine-strict
config flag, this
field is advisory only and will only produce warnings when your package is installed as a dependency.
This feature was removed in npm 3.0.0
Prior to npm 3.0.0, this feature was used to treat this package as if the
user had set engine-strict
. It is no longer used.
You can specify which operating systems your module will run on:
"os" : [ "darwin", "linux" ]
You can also blacklist instead of whitelist operating systems, just prepend the blacklisted os with a '!':
"os" : [ "!win32" ]
The host operating system is determined by process.platform
It is allowed to both blacklist, and whitelist, although there isn't any good reason to do this.
If your code only runs on certain cpu architectures, you can specify which ones.
"cpu" : [ "x64", "ia32" ]
Like the os
option, you can also blacklist architectures:
"cpu" : [ "!arm", "!mips" ]
The host architecture is determined by process.arch
DEPRECATED
This option used to trigger an npm warning, but it will no longer warn. It is purely there for informational purposes. It is now recommended that you install any binaries as local devDependencies wherever possible.
If you set "private": true
in your package.json, then npm will refuse
to publish it.
This is a way to prevent accidental publication of private repositories. If
you would like to ensure that a given package is only ever published to a
specific registry (for example, an internal registry), then use the
publishConfig
dictionary described below to override the registry
config
param at publish-time.
This is a set of config values that will be used at publish-time. It's especially handy if you want to set the tag, registry or access, so that you can ensure that a given package is not tagged with "latest", published to the global public registry or that a scoped module is private by default.
Any config values can be overridden, but of course only "tag", "registry" and "access" probably matter for the purposes of publishing.
See npm-config(7)
to see the list of config options that can be
overridden.
npm will default some values based on package contents.
"scripts": {"start": "node server.js"}
If there is a server.js
file in the root of your package, then npm
will default the start
command to node server.js
.
"scripts":{"install": "node-gyp rebuild"}
If there is a binding.gyp
file in the root of your package and you have not defined an install
or preinstall
script, npm will
default the install
command to compile using node-gyp.
"contributors": [...]
If there is an AUTHORS
file in the root of your package, npm will
treat each line as a Name <email> (url)
format, where email and url
are optional. Lines which start with a #
or are blank, will be
ignored.