Depending on what platform or features you need, the build process may differ. After you've built a binary, running the test suite to confirm that the binary works as intended is a good next step.
If you can reproduce a test failure, search for it in the Node.js issue tracker or file a new issue.
- Supported platforms
- Building Node.js on supported platforms
Intl
(ECMA-402) support- Building Node.js with FIPS-compliant OpenSSL
- Building Node.js with external core modules
- Note for downstream distributors of Node.js
This list of supported platforms is current as of the branch/release to which it belongs.
Node.js relies on V8 and libuv. We adopt a subset of their supported platforms.
There are three support tiers:
- Tier 1: These platforms represent the majority of Node.js users. The Node.js Build Working Group maintains infrastructure for full test coverage. Test failures on tier 1 platforms will block releases.
- Tier 2: These platforms represent smaller segments of the Node.js user base. The Node.js Build Working Group maintains infrastructure for full test coverage. Test failures on tier 2 platforms will block releases. Infrastructure issues may delay the release of binaries for these platforms.
- Experimental: May not compile or test suite may not pass. The core team does not create releases for these platforms. Test failures on experimental platforms do not block releases. Contributions to improve support for these platforms are welcome.
Platforms may move between tiers between major release lines. The table below will reflect those changes.
Node.js compilation/execution support depends on operating system, architecture, and libc version. The table below lists the support tier for each supported combination. A list of supported compile toolchains is also supplied for tier 1 platforms.
For production applications, run Node.js on supported platforms only.
Node.js does not support a platform version if a vendor has expired support for it. In other words, Node.js does not support running on End-of-Life (EoL) platforms. This is true regardless of entries in the table below.
Operating System | Architectures | Versions | Support Type | Notes |
---|---|---|---|---|
GNU/Linux | x64 | kernel >= 3.10, glibc >= 2.17 | Tier 1 | e.g. Ubuntu 16.041, Debian 9, EL 72 |
GNU/Linux | x64 | kernel >= 3.10, musl >= 1.1.19 | Experimental | e.g. Alpine 3.8 |
GNU/Linux | x86 | kernel >= 3.10, glibc >= 2.17 | Experimental | Downgraded as of Node.js 10 |
GNU/Linux | arm64 | kernel >= 4.5, glibc >= 2.17 | Tier 1 | e.g. Ubuntu 16.04, Debian 9, EL 73 |
GNU/Linux | armv7 | kernel >= 4.14, glibc >= 2.24 | Tier 1 | e.g. Ubuntu 18.04, Debian 9 |
GNU/Linux | armv6 | kernel >= 4.14, glibc >= 2.24 | Experimental | Downgraded as of Node.js 12 |
GNU/Linux | ppc64le >=power8 | kernel >= 3.10.0, glibc >= 2.17 | Tier 2 | e.g. Ubuntu 16.041, EL 72 |
GNU/Linux | s390x | kernel >= 3.10.0, glibc >= 2.17 | Tier 2 | e.g. EL 72 |
Windows | x64, x86 (WoW64) | >= Windows 8.1/2012 R2 | Tier 1 | 4,5 |
Windows | x86 (native) | >= Windows 8.1/2012 R2 | Tier 1 (running) / Experimental (compiling)6 | |
Windows | x64, x86 | Windows Server 2012 (not R2) | Experimental | |
Windows | arm64 | >= Windows 10 | Tier 2 (compiling) / Experimental (running) | |
macOS | x64 | >= 10.13 | Tier 1 | For notes about compilation see 7 |
macOS | arm64 | >= 11 | Tier 1 | |
SmartOS | x64 | >= 18 | Tier 2 | |
AIX | ppc64be >=power7 | >= 7.2 TL04 | Tier 2 | |
FreeBSD | x64 | >= 12.2 | Experimental |
Depending on the host platform, the selection of toolchains may vary.
Operating System | Compiler Versions |
---|---|
Linux | GCC >= 8.3 |
Windows | Visual Studio >= 2019 with the Windows 10 SDK on a 64-bit host |
macOS | Xcode >= 11 (Apple LLVM >= 11) |
Binaries at https://nodejs.org/download/release/ are produced on:
Binary package | Platform and Toolchain |
---|---|
aix-ppc64 | AIX 7.2 TL04 on PPC64BE with GCC 8 |
darwin-x64 | macOS 10.15, Xcode Command Line Tools 11 with -mmacosx-version-min=10.13 |
darwin-arm64 (and .pkg) | macOS 11 (arm64), Xcode Command Line Tools 12 with -mmacosx-version-min=10.13 |
linux-arm64 | CentOS 7 with devtoolset-8 / GCC 88 |
linux-armv7l | Cross-compiled on Ubuntu 18.04 x64 with custom GCC toolchain |
linux-ppc64le | CentOS 7 with devtoolset-8 / GCC 88 |
linux-s390x | RHEL 7 with devtoolset-8 / GCC 88 |
linux-x64 | CentOS 7 with devtoolset-8 / GCC 88 |
win-x64 and win-x86 | Windows 2012 R2 (x64) with Visual Studio 2019 |
OpenSSL-1.1.1 requires the following assembler version for use of asm support on x86_64 and ia32.
For use of AVX-512,
- gas (GNU assembler) version 2.26 or higher
- nasm version 2.11.8 or higher in Windows
AVX-512 is disabled for Skylake-X by OpenSSL-1.1.1.
For use of AVX2,
- gas (GNU assembler) version 2.23 or higher
- Xcode version 5.0 or higher
- llvm version 3.3 or higher
- nasm version 2.10 or higher in Windows
Please refer to https://www.openssl.org/docs/man1.1.1/man3/OPENSSL_ia32cap.html for details.
If compiling without one of the above, use configure
with the
--openssl-no-asm
flag. Otherwise, configure
will fail.
Supported platforms and toolchains change with each major version of Node.js. This document is only valid for the current major version of Node.js. Consult previous versions of this document for older versions of Node.js:
The Node.js project supports Python >= 3 for building and testing.
gcc
andg++
>= 8.3 or newer- GNU Make 3.81 or newer
- Python 3.6, 3.7, 3.8, 3.9, or 3.10 (see note above)
- For test coverage, your Python installation must include pip.
Installation via Linux package manager can be achieved with:
- Ubuntu, Debian:
sudo apt-get install python3 g++ make python3-pip
- Fedora:
sudo dnf install python3 gcc-c++ make python3-pip
- CentOS and RHEL:
sudo yum install python3 gcc-c++ make python3-pip
- OpenSUSE:
sudo zypper install python3 gcc-c++ make python3-pip
- Arch Linux, Manjaro:
sudo pacman -S python gcc make python-pip
FreeBSD and OpenBSD users may also need to install libexecinfo
.
- Xcode Command Line Tools >= 11 for macOS
- Python 3.6, 3.7, 3.8, 3.9, or 3.10 (see note above)
- For test coverage, your Python installation must include pip.
macOS users can install the Xcode Command Line Tools
by running
xcode-select --install
. Alternatively, if you already have the full Xcode
installed, you can find them under the menu Xcode -> Open Developer Tool -> More Developer Tools...
. This step will install clang
, clang++
, and
make
.
If the path to your build directory contains a space, the build will likely fail.
To build Node.js:
$ ./configure
$ make -j4
The -j4
option will cause make
to run 4 simultaneous compilation jobs which
may reduce build time. For more information, see the
GNU Make Documentation.
The above requires that python
resolves to a supported version of
Python. See Prerequisites.
After building, setting up firewall rules can avoid popups asking to accept incoming network connections when running tests.
Running the following script on macOS will add the firewall rules for the
executable node
in the out
directory and the symbolic node
link in the
project's root directory.
$ sudo ./tools/macos-firewall.sh
To install this version of Node.js into a system directory:
[sudo] make install
To verify the build:
$ make test-only
At this point, you are ready to make code changes and re-run the tests.
If you are running tests before submitting a pull request, use:
$ make -j4 test
make -j4 test
does a full check on the codebase, including running linters and
documentation tests.
To run the linter without running tests, use
make lint
/vcbuild lint
. It will lint JavaScript, C++, and Markdown files.
If you are updating tests and want to run tests in a single test file
(e.g. test/parallel/test-stream2-transform.js
):
$ tools/test.py test/parallel/test-stream2-transform.js
You can execute the entire suite of tests for a given subsystem by providing the name of a subsystem:
$ tools/test.py -J child-process
You can also execute the tests in a tests directory (such as test/message
):
$ tools/test.py -J test/message
If you want to check the other options, please refer to the help by using
the --help
option:
$ tools/test.py --help
You can usually run tests directly with node:
$ ./node ./test/parallel/test-stream2-transform.js
Remember to recompile with make -j4
in between test runs if you change code in
the lib
or src
directories.
The tests attempt to detect support for IPv6 and exclude IPv6 tests if appropriate. If your main interface has IPv6 addresses, then your loopback interface must also have '::1' enabled. For some default installations on Ubuntu, that does not seem to be the case. To enable '::1' on the loopback interface on Ubuntu:
sudo sysctl -w net.ipv6.conf.lo.disable_ipv6=0
You can use node-code-ide-configs to run/debug tests if your IDE configs are present.
It's good practice to ensure any code you add or change is covered by tests. You can do so by running the test suite with coverage enabled:
$ ./configure --coverage
$ make coverage
A detailed coverage report will be written to coverage/index.html
for
JavaScript coverage and to coverage/cxxcoverage.html
for C++ coverage.
If you only want to run the JavaScript tests then you do not need to run
the first command (./configure --coverage
). Run make coverage-run-js
,
to execute JavaScript tests independently of the C++ test suite:
$ make coverage-run-js
If you are updating tests and want to collect coverage for a single test file
(e.g. test/parallel/test-stream2-transform.js
):
$ make coverage-clean
$ NODE_V8_COVERAGE=coverage/tmp tools/test.py test/parallel/test-stream2-transform.js
$ make coverage-report-js
You can collect coverage for the entire suite of tests for a given subsystem by providing the name of a subsystem:
$ make coverage-clean
$ NODE_V8_COVERAGE=coverage/tmp tools/test.py --mode=release child-process
$ make coverage-report-js
The make coverage
command downloads some tools to the project root directory.
To clean up after generating the coverage reports:
$ make coverage-clean
To build the documentation:
This will build Node.js first (if necessary) and then use it to build the docs:
make doc
If you have an existing Node.js build, you can build just the docs with:
NODE=/path/to/node make doc-only
To read the man page:
man doc/node.1
If you prefer to read the full documentation in a browser, run the following.
make docserve
This will spin up a static file server and provide a URL to where you may browse the documentation locally.
If you're comfortable viewing the documentation using the program your operating system has associated with the default web browser, run the following.
make docopen
This will open a file URL to a one-page version of all the browsable HTML documents using the default browser.
To test if Node.js was built correctly:
./node -e "console.log('Hello from Node.js ' + process.version)"
If you run into an issue where the information provided by the JS stack trace is not enough, or if you suspect the error happens outside of the JS VM, you can try to build a debug enabled binary:
$ ./configure --debug
$ make -j4
make
with ./configure --debug
generates two binaries, the regular release
one in out/Release/node
and a debug binary in out/Debug/node
, only the
release version is actually installed when you run make install
.
To use the debug build with all the normal dependencies overwrite the release version in the install directory:
$ make install PREFIX=/opt/node-debug/
$ cp -a -f out/Debug/node /opt/node-debug/node
When using the debug binary, core dumps will be generated in case of crashes. These core dumps are useful for debugging when provided with the corresponding original debug binary and system information.
Reading the core dump requires gdb
built on the same platform the core dump
was captured on (i.e. 64-bit gdb
for node
built on a 64-bit system, Linux
gdb
for node
built on Linux) otherwise you will get errors like
not in executable format: File format not recognized
.
Example of generating a backtrace from the core dump:
$ gdb /opt/node-debug/node core.node.8.1535359906
$ backtrace
ASAN can help detect various memory
related bugs. ASAN builds are currently only supported on linux.
If you want to check it on Windows or macOS or you want a consistent toolchain
on Linux, you can try Docker
(using an image like gengjiawen/node-build:2020-02-14
).
The --debug
is not necessary and will slow down build and testing, but it can
show clear stacktrace if ASAN hits an issue.
$ ./configure --debug --enable-asan && make -j4
$ make test-only
If you plan to frequently rebuild Node.js, especially if using several branches,
installing ccache
can help to greatly reduce build times. Set up with:
On GNU/Linux:
sudo apt install ccache # for Debian/Ubuntu, included in most Linux distros
export CC="ccache gcc" # add to your .profile
export CXX="ccache g++" # add to your .profile
On macOS:
brew install ccache # see https://brew.sh
export CC="ccache cc" # add to ~/.zshrc or other shell config file
export CXX="ccache c++" # add to ~/.zshrc or other shell config file
This will allow for near-instantaneous rebuilds even when switching branches.
When modifying only the JS layer in lib
, it is possible to externally load it
without modifying the executable:
$ ./configure --node-builtin-modules-path $(pwd)
The resulting binary won't include any JS files and will try to load them from the specified directory. The JS debugger of Visual Studio Code supports this configuration since the November 2020 version and allows for setting breakpoints.
Stale builds can sometimes result in file not found
errors while building.
This and some other problems can be resolved with make distclean
. The
distclean
recipe aggressively removes build artifacts. You will need to
build again (make -j4
). Since all build artifacts have been removed, this
rebuild may take a lot more time than previous builds. Additionally,
distclean
removes the file that stores the results of ./configure
. If you
ran ./configure
with non-default options (such as --debug
), you will need
to run it again before invoking make -j4
.
- Python 3.10
- The "Desktop development with C++" workload from Visual Studio 2019 or the "C++ build tools" workload from the Build Tools, with the default optional components
- Basic Unix tools required for some tests,
Git for Windows includes Git Bash
and tools which can be included in the global
PATH
. - The NetWide Assembler, for OpenSSL assembler modules.
If not installed in the default location, it needs to be manually added
to
PATH
. A build with theopenssl-no-asm
option does not need this, nor does a build targeting ARM64 Windows.
Optional requirements to build the MSI installer package:
- The WiX Toolset v3.11 and the Wix Toolset Visual Studio 2019 Extension
- The WiX Toolset v3.14 if building for Windows 10 on ARM (ARM64)
Optional requirements for compiling for Windows 10 on ARM (ARM64):
- Visual Studio 15.9.0 or newer
- Visual Studio optional components
- Visual C++ compilers and libraries for ARM64
- Visual C++ ATL for ARM64
- Windows 10 SDK 10.0.17763.0 or newer
A Boxstarter script can be used for easy setup of Windows systems with all the required prerequisites for Node.js development. This script will install the following Chocolatey packages:
- Git for Windows with the
git
and Unix tools added to thePATH
- Python 3.x
- Visual Studio 2019 Build Tools with Visual C++ workload
- NetWide Assembler
To install Node.js prerequisites using Boxstarter WebLauncher, open https://boxstarter.org/package/nr/url?https://raw.githubusercontent.com/nodejs/node/HEAD/tools/bootstrap/windows_boxstarter with Internet Explorer or Edge browser on the target machine.
Alternatively, you can use PowerShell. Run those commands from an elevated PowerShell terminal:
Set-ExecutionPolicy Unrestricted -Force
iex ((New-Object System.Net.WebClient).DownloadString('https://boxstarter.org/bootstrapper.ps1'))
get-boxstarter -Force
Install-BoxstarterPackage https://raw.githubusercontent.com/nodejs/node/HEAD/tools/bootstrap/windows_boxstarter -DisableReboots
The entire installation using Boxstarter will take up approximately 10 GB of disk space.
If the path to your build directory contains a space or a non-ASCII character, the build will likely fail.
> .\vcbuild
To run the tests:
> .\vcbuild test
To test if Node.js was built correctly:
> Release\node -e "console.log('Hello from Node.js', process.version)"
Android is not a supported platform. Patches to improve the Android build are welcome. There is no testing on Android in the current continuous integration environment. The participation of people dedicated and determined to improve Android building, testing, and support is encouraged.
Be sure you have downloaded and extracted Android NDK before in a folder. Then run:
$ ./android-configure /path/to/your/android-ndk
$ make
Intl support is enabled by default.
This is the default option.
$ ./configure --with-intl=full-icu
> .\vcbuild full-icu
In this configuration, only English data is included, but
the full Intl
(ECMA-402) APIs. It does not need to download
any dependencies to function. You can add full data at runtime.
$ ./configure --with-intl=small-icu
> .\vcbuild small-icu
The Intl
object will not be available, nor some other APIs such as
String.normalize
.
$ ./configure --without-intl
> .\vcbuild without-intl
$ pkg-config --modversion icu-i18n && ./configure --with-intl=system-icu
If you are cross-compiling, your pkg-config
must be able to supply a path
that works for both your host and target environments.
You can find other ICU releases at
the ICU homepage.
Download the file named something like icu4c-**##.#**-src.tgz
(or
.zip
).
To check the minimum recommended ICU, run ./configure --help
and see
the help for the --with-icu-source
option. A warning will be printed
during configuration if the ICU version is too old.
From an already-unpacked ICU:
$ ./configure --with-intl=[small-icu,full-icu] --with-icu-source=/path/to/icu
From a local ICU tarball:
$ ./configure --with-intl=[small-icu,full-icu] --with-icu-source=/path/to/icu.tgz
From a tarball URL:
$ ./configure --with-intl=full-icu --with-icu-source=http://url/to/icu.tgz
First unpack latest ICU to deps/icu
icu4c-##.#-src.tgz (or .zip
)
as deps/icu
(You'll have: deps/icu/source/...
)
> .\vcbuild full-icu
The current version of Node.js supports FIPS when statically and
dynamically linking with OpenSSL 3.0.0 by using the configuration flag
--openssl-is-fips
.
FIPS can be supported by specifying the configuration flag --openssl-is-fips
:
$ ./configure --openssl-is-fips
$ make -j8
The above command will build and install the FIPS module into the out directory.
This includes building fips.so, running the installfips
command that generates
the FIPS configuration file (fipsmodule.cnf), copying and updating openssl.cnf
to include the correct path to fipsmodule.cnf and finally uncomment the fips
section.
We can then run node specifying --enable-fips
:
$ ./node --enable-fips -p 'crypto.getFips()'
1
The above will use the Node.js default locations for OpenSSL 3.0:
$ ./out/Release/openssl-cli version -m -d
OPENSSLDIR: "/nodejs/openssl/out/Release/obj.target/deps/openssl"
MODULESDIR: "/nodejs/openssl/out/Release/obj.target/deps/openssl/lib/openssl-modules"
The OpenSSL configuration files will be found in OPENSSLDIR
directory above:
$ ls -w 1 out/Release/obj.target/deps/openssl/*.cnf
out/Release/obj.target/deps/openssl/fipsmodule.cnf
out/Release/obj.target/deps/openssl/openssl.cnf
And the FIPS module will be located in the MODULESDIR
directory:
$ ls out/Release/obj.target/deps/openssl/lib/openssl-modules/
fips.so
For quictls/openssl 3.0 it is possible to enable FIPS when dynamically linking. If you want to build Node.js using openssl-3.0.0+quic, you can follow these steps:
clone OpenSSL source and prepare build
git clone git@github.com:quictls/openssl.git
cd openssl
./config \
--prefix=/path/to/install/dir/ \
shared \
enable-fips \
linux-x86_64
The /path/to/install/dir
is the path in which the make install
instructions
will publish the OpenSSL libraries and such. We will also use this path
(and sub-paths) later when compiling Node.js.
compile and install OpenSSL
make -j8
make install
make install_ssldirs
make install_fips
After the OpenSSL (including FIPS) modules have been compiled and installed
(into the /path/to/install/dir
) by the above instructions we also need to
update the OpenSSL configuration file located under
/path/to/install/dir/ssl/openssl.cnf
. Right next to this file, you should
find the fipsmodule.cnf
file - let's add the following to the end of the
openssl.cnf
file.
alter openssl.cnf
.include /absolute/path/to/fipsmodule.cnf
# List of providers to load
[provider_sect]
default = default_sect
# The fips section name should match the section name inside the
# included /path/to/install/dir/ssl/fipsmodule.cnf.
fips = fips_sect
[default_sect]
activate = 1
You can e.g. accomplish this by running the following command - be sure to
replace /path/to/install/dir/
with the path you have selected. Please make
sure that you specify an absolute path for the .include fipsmodule.cnf
line -
using relative paths did not work on my system!
alter openssl.cnf using a script
cat <<EOT >> /path/to/install/dir/ssl/openssl.cnf
.include /path/to/install/dir/ssl/fipsmodule.cnf
# List of providers to load
[provider_sect]
default = default_sect
# The fips section name should match the section name inside the
# included /path/to/install/dir/ssl/fipsmodule.cnf.
fips = fips_sect
[default_sect]
activate = 1
EOT
As you might have picked a non-custom path for your OpenSSL install dir, we have to export the following two environment variables in order for Node.js to find our OpenSSL modules we built beforehand:
export OPENSSL_CONF=/path/to/install/dir/ssl/openssl.cnf
export OPENSSL_MODULES=/path/to/install/dir/lib/ossl-modules
build Node.js
./configure \
--shared-openssl \
--shared-openssl-libpath=/path/to/install/dir/lib \
--shared-openssl-includes=/path/to/install/dir/include \
--shared-openssl-libname=crypto,ssl \
--openssl-is-fips
export LD_LIBRARY_PATH=/path/to/install/dir/lib
make -j8
verify the produced executable
ldd ./node
linux-vdso.so.1 (0x00007ffd7917b000)
libcrypto.so.81.3 => /path/to/install/dir/lib/libcrypto.so.81.3 (0x00007fd911321000)
libssl.so.81.3 => /path/to/install/dir/lib/libssl.so.81.3 (0x00007fd91125e000)
libdl.so.2 => /usr/lib64/libdl.so.2 (0x00007fd911232000)
libstdc++.so.6 => /usr/lib64/libstdc++.so.6 (0x00007fd911039000)
libm.so.6 => /usr/lib64/libm.so.6 (0x00007fd910ef3000)
libgcc_s.so.1 => /usr/lib64/libgcc_s.so.1 (0x00007fd910ed9000)
libpthread.so.0 => /usr/lib64/libpthread.so.0 (0x00007fd910eb5000)
libc.so.6 => /usr/lib64/libc.so.6 (0x00007fd910cec000)
/lib64/ld-linux-x86-64.so.2 (0x00007fd9117f2000)
If the ldd
command says that libcrypto
cannot be found one needs to set
LD_LIBRARY_PATH
to point to the directory used above for
--shared-openssl-libpath
(see previous step).
verify the OpenSSL version
./node -p process.versions.openssl
3.0.0-alpha16+quic
verify that FIPS is available
./node -p 'process.config.variables.openssl_is_fips'
true
./node --enable-fips -p 'crypto.getFips()'
1
FIPS support can then be enable via the OpenSSL configuration file or
using --enable-fips
or --force-fips
command line options to the Node.js
executable. See sections
Enabling FIPS using Node.js options and
Enabling FIPS using OpenSSL config below.
This is done using one of the Node.js options --enable-fips
or
--force-fips
, for example:
$ node --enable-fips -p 'crypto.getFips()'
This example show that using OpenSSL's configuration file, FIPS can be enabled
without specifying the --enable-fips
or --force-fips
options by setting
default_properties = fips=yes
in the FIPS configuration file. See
link
for details.
For this to work the OpenSSL configuration file (default openssl.cnf) needs to be updated. The following shows an example:
openssl_conf = openssl_init
.include /path/to/install/dir/ssl/fipsmodule.cnf
[openssl_init]
providers = prov
alg_section = algorithm_sect
[prov]
fips = fips_sect
default = default_sect
[default_sect]
activate = 1
[algorithm_sect]
default_properties = fips=yes
After this change Node.js can be run without the --enable-fips
or --force-fips
options.
It is possible to specify one or more JavaScript text files to be bundled in the binary as built-in modules when building Node.js.
This command will make /root/myModule.js
available via
require('/root/myModule')
and ./myModule2.js
available via
require('myModule2')
.
$ ./configure --link-module '/root/myModule.js' --link-module './myModule2.js'
To make ./myModule.js
available via require('myModule')
and
./myModule2.js
available via require('myModule2')
:
> .\vcbuild link-module './myModule.js' link-module './myModule2.js'
The Node.js ecosystem is reliant on ABI compatibility within a major release.
To maintain ABI compatibility it is required that distributed builds of Node.js
be built against the same version of dependencies, or similar versions that do
not break their ABI compatibility, as those released by Node.js for any given
NODE_MODULE_VERSION
(located in src/node_version.h
).
When Node.js is built (with an intention to distribute) with an ABI
incompatible with the official Node.js builds (e.g. using a ABI incompatible
version of a dependency), please reserve and use a custom NODE_MODULE_VERSION
by opening a pull request against the registry available at
https://github.com/nodejs/node/blob/HEAD/doc/abi_version_registry.json.
Footnotes
-
GCC 8 is not provided on the base platform. Users will need the Toolchain test builds PPA or similar to source a newer compiler. ↩ ↩2
-
GCC 8 is not provided on the base platform. Users will need the devtoolset-8 or later to source a newer compiler. ↩ ↩2 ↩3
-
Older kernel versions may work for ARM64. However the Node.js test infrastructure only tests >= 4.5. ↩
-
On Windows, running Node.js in Windows terminal emulators like
mintty
requires the usage of winpty for the tty channels to work (e.g.winpty node.exe script.js
). In "Git bash" if you call the node shell alias (node
without the.exe
extension),winpty
is used automatically. ↩ -
The Windows Subsystem for Linux (WSL) is not supported, but the GNU/Linux build process and binaries should work. The community will only address issues that reproduce on native GNU/Linux systems. Issues that only reproduce on WSL should be reported in the WSL issue tracker. Running the Windows binary (
node.exe
) in WSL will not work without workarounds such as stdio redirection. ↩ -
Running Node.js on x86 Windows should work and binaries are provided. However, tests in our infrastructure only run on WoW64. Furthermore, compiling on x86 Windows is Experimental and may not be possible. ↩
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Our macOS x64 Binaries are compiled with 10.13 as a target. However there is no guarantee compiling on 10.13 will work as Xcode11 is required to compile. ↩
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The Enterprise Linux devtoolset-8 allows us to compile binaries with GCC 8 but linked to the glibc and libstdc++ versions of the host platforms (CentOS 7 / RHEL 7). Therefore, binaries produced on these systems are compatible with glibc >= 2.17 and libstdc++ >= 6.0.20 (
GLIBCXX_3.4.20
). These are available on distributions natively supporting GCC 4.9, such as Ubuntu 14.04 and Debian 8. ↩ ↩2 ↩3 ↩4