Global configuration
Nix comes with certain defaults about what packages can and cannot be
installed, based on a package's metadata. By default, Nix will prevent
installation if any of the following criteria are true:
The package is thought to be broken, and has had its
meta.broken set to true.
The package isn't intended to run on the given system, as none of its
meta.platforms match the given system.
The package's meta.license is set to a license which is
considered to be unfree.
The package has known security vulnerabilities but has not or can not be
updated for some reason, and a list of issues has been entered in to the
package's meta.knownVulnerabilities.
Note that all this is checked during evaluation already, and the check
includes any package that is evaluated. In particular, all build-time
dependencies are checked. nix-env -qa will (attempt to)
hide any packages that would be refused.
Each of these criteria can be altered in the nixpkgs configuration.
The nixpkgs configuration for a NixOS system is set in the
configuration.nix, as in the following example:
{
nixpkgs.config = {
allowUnfree = true;
};
}
However, this does not allow unfree software for individual users. Their
configurations are managed separately.
A user's of nixpkgs configuration is stored in a user-specific configuration
file located at ~/.config/nixpkgs/config.nix. For
example:
{
allowUnfree = true;
}
Note that we are not able to test or build unfree software on Hydra due to
policy. Most unfree licenses prohibit us from either executing or
distributing the software.
Installing broken packages
There are two ways to try compiling a package which has been marked as
broken.
For allowing the build of a broken package once, you can use an
environment variable for a single invocation of the nix tools:
$ export NIXPKGS_ALLOW_BROKEN=1
For permanently allowing broken packages to be built, you may add
allowBroken = true; to your user's configuration file,
like this:
{
allowBroken = true;
}
Installing packages on unsupported systems
There are also two ways to try compiling a package which has been marked as
unsuported for the given system.
For allowing the build of a broken package once, you can use an
environment variable for a single invocation of the nix tools:
$ export NIXPKGS_ALLOW_UNSUPPORTED_SYSTEM=1
For permanently allowing broken packages to be built, you may add
allowUnsupportedSystem = true; to your user's
configuration file, like this:
{
allowUnsupportedSystem = true;
}
The difference between a package being unsupported on some system and being
broken is admittedly a bit fuzzy. If a program ought to
work on a certain platform, but doesn't, the platform should be included in
meta.platforms, but marked as broken with e.g.
meta.broken = !hostPlatform.isWindows. Of course, this
begs the question of what "ought" means exactly. That is left to the package
maintainer.
Installing unfree packages
There are several ways to tweak how Nix handles a package which has been
marked as unfree.
To temporarily allow all unfree packages, you can use an environment
variable for a single invocation of the nix tools:
$ export NIXPKGS_ALLOW_UNFREE=1
It is possible to permanently allow individual unfree packages, while
still blocking unfree packages by default using the
allowUnfreePredicate configuration option in the user
configuration file.
This option is a function which accepts a package as a parameter, and
returns a boolean. The following example configuration accepts a package
and always returns false:
{
allowUnfreePredicate = (pkg: false);
}
For a more useful example, try the following. This configuration only
allows unfree packages named flash player and visual studio code:
{
allowUnfreePredicate = pkg: builtins.elem (lib.getName pkg) [
"flashplayer"
"vscode"
];
}
It is also possible to whitelist and blacklist licenses that are
specifically acceptable or not acceptable, using
whitelistedLicenses and
blacklistedLicenses, respectively.
The following example configuration whitelists the licenses
amd and wtfpl:
{
whitelistedLicenses = with stdenv.lib.licenses; [ amd wtfpl ];
}
The following example configuration blacklists the gpl3
and agpl3 licenses:
{
blacklistedLicenses = with stdenv.lib.licenses; [ agpl3 gpl3 ];
}
A complete list of licenses can be found in the file
lib/licenses.nix of the nixpkgs tree.
Installing insecure packages
There are several ways to tweak how Nix handles a package which has been
marked as insecure.
To temporarily allow all insecure packages, you can use an environment
variable for a single invocation of the nix tools:
$ export NIXPKGS_ALLOW_INSECURE=1
It is possible to permanently allow individual insecure packages, while
still blocking other insecure packages by default using the
permittedInsecurePackages configuration option in the
user configuration file.
The following example configuration permits the installation of the
hypothetically insecure package hello, version
1.2.3:
{
permittedInsecurePackages = [
"hello-1.2.3"
];
}
It is also possible to create a custom policy around which insecure
packages to allow and deny, by overriding the
allowInsecurePredicate configuration option.
The allowInsecurePredicate option is a function which
accepts a package and returns a boolean, much like
allowUnfreePredicate.
The following configuration example only allows insecure packages with
very short names:
{
allowInsecurePredicate = (pkg: (builtins.stringLength (lib.getName pkg) <= 5);
}
Note that permittedInsecurePackages is only checked if
allowInsecurePredicate is not specified.
Modify packages via packageOverrides
You can define a function called packageOverrides in your
local ~/.config/nixpkgs/config.nix to override Nix
packages. It must be a function that takes pkgs as an argument and returns a
modified set of packages.
{
packageOverrides = pkgs: rec {
foo = pkgs.foo.override { ... };
};
}
Declarative Package Management
Build an environment
Using packageOverrides, it is possible to manage
packages declaratively. This means that we can list all of our desired
packages within a declarative Nix expression. For example, to have
aspell, bc,
ffmpeg, coreutils,
gdb, nixUnstable,
emscripten, jq,
nox, and silver-searcher, we could
use the following in ~/.config/nixpkgs/config.nix:
{
packageOverrides = pkgs: with pkgs; {
myPackages = pkgs.buildEnv {
name = "my-packages";
paths = [
aspell
bc
coreutils
gdb
ffmpeg
nixUnstable
emscripten
jq
nox
silver-searcher
];
};
};
}
To install it into our environment, you can just run nix-env -iA
nixpkgs.myPackages. If you want to load the packages to be built
from a working copy of nixpkgs you just run
nix-env -f. -iA myPackages. To explore what's been
installed, just look through ~/.nix-profile/. You can
see that a lot of stuff has been installed. Some of this stuff is useful
some of it isn't. Let's tell Nixpkgs to only link the stuff that we want:
{
packageOverrides = pkgs: with pkgs; {
myPackages = pkgs.buildEnv {
name = "my-packages";
paths = [
aspell
bc
coreutils
gdb
ffmpeg
nixUnstable
emscripten
jq
nox
silver-searcher
];
pathsToLink = [ "/share" "/bin" ];
};
};
}
pathsToLink tells Nixpkgs to only link the paths listed
which gets rid of the extra stuff in the profile. /bin
and /share are good defaults for a user environment,
getting rid of the clutter. If you are running on Nix on MacOS, you may
want to add another path as well, /Applications, that
makes GUI apps available.
Getting documentation
After building that new environment, look through
~/.nix-profile to make sure everything is there that
we wanted. Discerning readers will note that some files are missing. Look
inside ~/.nix-profile/share/man/man1/ to verify this.
There are no man pages for any of the Nix tools! This is because some
packages like Nix have multiple outputs for things like documentation (see
section 4). Let's make Nix install those as well.
{
packageOverrides = pkgs: with pkgs; {
myPackages = pkgs.buildEnv {
name = "my-packages";
paths = [
aspell
bc
coreutils
ffmpeg
nixUnstable
emscripten
jq
nox
silver-searcher
];
pathsToLink = [ "/share/man" "/share/doc" "/bin" ];
extraOutputsToInstall = [ "man" "doc" ];
};
};
}
This provides us with some useful documentation for using our packages.
However, if we actually want those manpages to be detected by man, we need
to set up our environment. This can also be managed within Nix expressions.
{
packageOverrides = pkgs: with pkgs; rec {
myProfile = writeText "my-profile" ''
export PATH=$HOME/.nix-profile/bin:/nix/var/nix/profiles/default/bin:/sbin:/bin:/usr/sbin:/usr/bin
export MANPATH=$HOME/.nix-profile/share/man:/nix/var/nix/profiles/default/share/man:/usr/share/man
'';
myPackages = pkgs.buildEnv {
name = "my-packages";
paths = [
(runCommand "profile" {} ''
mkdir -p $out/etc/profile.d
cp ${myProfile} $out/etc/profile.d/my-profile.sh
'')
aspell
bc
coreutils
ffmpeg
man
nixUnstable
emscripten
jq
nox
silver-searcher
];
pathsToLink = [ "/share/man" "/share/doc" "/bin" "/etc" ];
extraOutputsToInstall = [ "man" "doc" ];
};
};
}
For this to work fully, you must also have this script sourced when you are
logged in. Try adding something like this to your
~/.profile file:
#!/bin/sh
if [ -d $HOME/.nix-profile/etc/profile.d ]; then
for i in $HOME/.nix-profile/etc/profile.d/*.sh; do
if [ -r $i ]; then
. $i
fi
done
fi
Now just run source $HOME/.profile and you can starting
loading man pages from your environent.
GNU info setup
Configuring GNU info is a little bit trickier than man pages. To work
correctly, info needs a database to be generated. This can be done with
some small modifications to our environment scripts.
{
packageOverrides = pkgs: with pkgs; rec {
myProfile = writeText "my-profile" ''
export PATH=$HOME/.nix-profile/bin:/nix/var/nix/profiles/default/bin:/sbin:/bin:/usr/sbin:/usr/bin
export MANPATH=$HOME/.nix-profile/share/man:/nix/var/nix/profiles/default/share/man:/usr/share/man
export INFOPATH=$HOME/.nix-profile/share/info:/nix/var/nix/profiles/default/share/info:/usr/share/info
'';
myPackages = pkgs.buildEnv {
name = "my-packages";
paths = [
(runCommand "profile" {} ''
mkdir -p $out/etc/profile.d
cp ${myProfile} $out/etc/profile.d/my-profile.sh
'')
aspell
bc
coreutils
ffmpeg
man
nixUnstable
emscripten
jq
nox
silver-searcher
texinfoInteractive
];
pathsToLink = [ "/share/man" "/share/doc" "/share/info" "/bin" "/etc" ];
extraOutputsToInstall = [ "man" "doc" "info" ];
postBuild = ''
if [ -x $out/bin/install-info -a -w $out/share/info ]; then
shopt -s nullglob
for i in $out/share/info/*.info $out/share/info/*.info.gz; do
$out/bin/install-info $i $out/share/info/dir
done
fi
'';
};
};
}
postBuild tells Nixpkgs to run a command after building
the environment. In this case, install-info adds the
installed info pages to dir which is GNU info's default
root node. Note that texinfoInteractive is added to the
environment to give the install-info command.