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This is an alpha-quality release. Breaking changes are likely.

The nodejs rules integrate NodeJS development toolchain and runtime with Bazel.

This toolchain can be used to build applications that target a browser runtime, so this repo can be thought of as "JavaScript rules for Bazel" as well.

First, install a current bazel distribution, following the bazel instructions.

Next, create a WORKSPACE file in your project root (or edit the existing one) containing:

git_repository(
    name = "build_bazel_rules_nodejs",
    remote = "https://github.com/bazelbuild/rules_nodejs.git",
    tag = "0.3.1", # check for the latest tag when you install
)

load("@build_bazel_rules_nodejs//:defs.bzl", "node_repositories")

# NOTE: this rule installs nodejs, npm, and yarn, but does NOT install
# your npm dependencies into your node_modules folder.
# You must still run the package manager to do this.
node_repositories(package_json = ["//:package.json"])

If you'd like to have Bazel use the node_modules directory you are managing, then next you will create a BUILD.bazel file in your project root containing:

package(default_visibility = ["//visibility:public"])

# NOTE: this may move to node_modules/BUILD in a later release
filegroup(name = "node_modules", srcs = glob(["node_modules/**/*"]))

We recommend using the version of the package management tools installed by Bazel to ensure everything is compatible.

To use the Yarn package manager, which we recommend for its built-in verification command, you can run:

$ bazel run @yarn//:yarn

If you use npm instead, run:

$ bazel run @nodejs//:npm install

To have Bazel manage its own copy of node_modules, which is useful to avoid juggling multiple toolchains, you can add the following to your WORKSPACE file:

load("@build_bazel_rules_nodejs//:defs.bzl", "npm_install")

npm_install(
    name = "foo",
    # This can also take package.json
    package_json = "//:package-lock.json",
)

You can then reference this version of node_modules in your BUILD rules via:

load("@build_bazel_rules_nodejs//:defs.bzl", "nodejs_binary")

nodejs_binary(
    name = "bar",
    # Ordinarily this defaults to //:node_modules
    node_modules = "@foo//:node_modules",
    ...
)

With this approach, Bazel is responsible for making sure that node_modules is up to date with package[-lock].json. This means Bazel will set it up when the repo is first cloned, and rebuild it whenever it changes.

For Bazel to provide the strongest guarantees about reproducibility and the fidelity of your build, it is recommended that you let Bazel take responsibility for this.

However, this approach manages a second copy of node_modules, so if you are juggling Bazel and other tooling, or sensitive to the additional network traffic this might incur, consider self-managing.

The nodejs_binary rule allows you to run an application by giving the entry point. The entry point can come from an external dependency installed by the package manager, or it can be a .js file from a package built by Bazel.

nodejs_test is the same as nodejs_binary, but instead of calling it with bazel run, you call it with bazel test. The test passes if the program exits with a zero exit code.

The jasmine_node_test rule allows you to write a test that executes in NodeJS.

rollup_bundle runs the Rollup and Uglify toolchain to produce a single JavaScript bundle.

npm_package packages up a library to publish to npm.

If you have installed the rollup package, you could write this rule:

load("@build_bazel_rules_nodejs//:defs.bzl", "nodejs_binary")

nodejs_binary(
    name = "rollup",
    entry_point = "rollup/bin/rollup",
)

and run it with

$ bazel run :rollup -- --help

See the examples/rollup directory in this repository.

We can reference a path in the local workspace to run a program we write.

load("@build_bazel_rules_nodejs//:defs.bzl", "nodejs_binary")

nodejs_binary(
    name = "example",
    data = [
        "@//:node_modules",
        "main.js",
    ],
    entry_point = "workspace_name/main.js",
    args = ["--node_options=--expose-gc"],
)

This example illustrates how to pass arguments to nodejs (as opposed to passing arguments to the program).

The data attribute is optional, by default it includes the node_modules directory. To include your own sources, include a file or target that produces JavaScript.

See the examples/program directory in this repository.

The jasmine_node_test rule can be used to run unit tests in NodeJS, using the Jasmine framework. Targets declared with this rule can be run with bazel test.

Attributes:

The srcs of a jasmine_node_test should include the test .js files. The deps should include the production .js sources, or other rules which produce .js files, such as TypeScript.

The examples/program/index.spec.js file illustrates this. Another usage is in https://github.com/angular/tsickle/blob/master/test/BUILD

Bazel is generally only a build tool, and is unaware of your version control system. However, when publishing releases, you typically want to embed version information in the resulting distribution. Bazel supports this natively, using the following approach:

1. Your tools/bazel.rc should pass the workspace_status_command argument to bazel build. This tells Bazel how to interact with the version control system when needed.

   build --workspace_status_command=./tools/bazel_stamp_vars.sh
   

2. Create tools/bazel_stamp_vars.sh. This is a script that prints variable/value pairs. Make sure you set the executable bit, eg. chmod 755 tools/bazel_stamp_vars.sh. For example, we could run git describe to get the current tag:

   #!/usr/bin/env bash
   echo BUILD_SCM_VERSION $(git describe --abbrev=7 --tags HEAD)

   For a more full-featured script, take a look at the bazel_stamp_vars in Angular

3. A genrule() with stamp=True can read the result. Bazel puts the output of the bazel_stamp_vars.sh in the magic location bazel-out/volatile-status.txt. (Note, this doesn't require that you actually have a bazel-out folder in your project.) We recommend adding this target to your tools/BAZEL.build:

   genrule(
       name = "stamp_data",
       outs = ["stamp_data.txt"],
       cmd = "cat bazel-out/volatile-status.txt > $@",
       stamp = True,
       visibility = ["//:__subpackages__"],
   )

4. Now you can pass this target to the stamp_data attribute of rollup_bundle or npm_package:

   stamp_data = "//tools:stamp_data"

See https://www.kchodorow.com/blog/2017/03/27/stamping-your-builds/ for more background.

A rollup_bundle rule produces three bundle files:

1. ES5 syntax, minified by uglify. This is the default output of the rule, meaning this file will be provided when this rule appears in the deps[] of another rule.

$ bazel build internal/e2e/rollup:bundle

2. ES5 syntax, un-minified.

$ bazel build internal/e2e/rollup:bundle.js

3. ES2015 syntax, un-minified.

$ bazel build internal/e2e/rollup:bundle.es6.js

Attributes:

srcs are .js files to be included in the bundle

deps are other rules which produce .js files, such as ts_library

entry_point is the main file of the application that will be executed. Only sources reachable from the import graph of this file will be included in the bundle.

stamp_data is a label of a file containing version info. See the Stamping section above.

Note: we expect other bundling rules will follow later, such as Closure compiler and Webpack.

The npm_package rule is used to create a package to publish to external users who do not use Bazel.

For those downstream dependencies that use Bazel, they can simply write BUILD files to consume your library.

You can use a pair of // BEGIN-INTERNAL ... // END-INTERNAL comments to mark regions of files that should be elided during publishing. For example:

function doThing() {
    // BEGIN-INTERNAL
    // This is a secret internal-only comment
    doInternalOnlyThing();
    // END-INTERNAL
}

Attributes:

srcs are files in your input tree

deps are other rules which produce arbitrary files

replacements is a dictionary of JS regexp to new string, in addition to the BEGIN/END-INTERNAL replacement.

stamp_data is a label of a file containing version info. See the Stamping section above.

Example:

load("@build_bazel_rules_nodejs//:defs.bzl", "npm_package")

npm_package(
    name = "my_package",
    srcs = ["package.json"],
    deps = [":my_typescript_lib"],
    replacements = {"//internal/": "//"},
)

Usage:

npm_package yields three labels. Build the package directory using the default label:

$ bazel build :my_package
Target //:my_package up-to-date:
  bazel-out/fastbuild/bin/my_package
$ ls -R bazel-out/fastbuild/bin/my_package

Dry-run of publishing to npm, calling npm pack (it builds the package first if needed):

$ bazel run :my_package.pack
INFO: Running command line: bazel-out/fastbuild/bin/my_package.pack
my-package-name-1.2.3.tgz
$ tar -tzf my-package-name-1.2.3.tgz

Actually publish the package with npm publish (also builds first):

# Check login credentials
$ bazel run @nodejs//:npm who
# Publishes the package
$ bazel run :my_package.publish

Most bazel rules include package management. That is, the WORKSPACE file installs your dependencies as well as the toolchain. In some environments, this is the normal workflow, for example in Java, Gradle and Maven are each both a build tool and a package manager.

In nodejs, there are a variety of package managers and build tools which can interoperate. Also, there is a well-known package installation location (node_modules directory in your project). Command-line and other tools look in this directory to find packages. So we must either download packages twice (risking version skew between them) or point all tools to Bazel's external directory with NODE_PATH which would be very inconvenient.

Instead, our philosophy is: in the NodeJS ecosystem, Bazel is only a build tool. It is up to the user to install packages into their node_modules directory, though the build tool can verify the contents.

Bazel generally guarantees builds are correct with respect to their inputs. For example, this means that given the same source tree, you can re-build the same artifacts as an earlier release of your program. In the nodejs rules, Bazel is not the package manager, so some reponsibility falls to the developer to avoid builds that use the wrong dependencies. This problem exists with any build system in the JavaScript ecosystem.

Both NPM and Yarn have a lockfile, which ensures that dependencies only change when the lockfile changes. Users are strongly encouraged to use the locking mechanism in their package manager.

References:

• npm: https://docs.npmjs.com/files/package-lock.json
• yarn: https://yarnpkg.com/lang/en/docs/yarn-lock/

Note that bazelbuild#1 will take the guarantee further: by using the lockfile as an input to Bazel, the nodejs rules can verify the integrity of the dependencies. This would make it impossible for a build to be non-reproducible, so long as you have the same lockfile.