6.1 KiB
Nixpkgs Overriding Packages
Welcome to the 17th Nix pill. In the previous 16th pill we have started to dive into the nixpkgs repository. Nixpkgs
is a function, and we've looked at some parameters like system
and config
.
Today we'll talk about a special attribute: config.packageOverrides
. Overriding packages in a set with fixed point can be considered another design pattern in nixpkgs.
Overriding a package
Recall the override design pattern from the nix pill 14. Instead of calling a function with parameters directly, we make the call (function + parameters) overridable.
We put the override function in the returned attribute set of the original function call.
Take for example graphviz
. It has an input parameter xorg
. If it's null, then graphviz
will build without X support.
$ nix repl
nix-repl> :l <nixpkgs>
Added 4360 variables.
nix-repl> :b graphviz.override { withXorg = false; }
This will build graphviz
without X support, it's as simple as that.
However, let's say a package P
depends on graphviz
, how do we make P
depend on the new graphviz
without X support?
In an imperative world...
...you could do something like this:
pkgs = import <nixpkgs> {};
pkgs.graphviz = pkgs.graphviz.override { withXorg = false; };
build(pkgs.P)
Given pkgs.P
depends on pkgs.graphviz
, it's easy to build P
with the replaced graphviz
. In a pure functional language it's not that easy because you can assign to variables only once.
Fixed point
The fixed point with lazy evaluation is crippling but about necessary in a language like Nix. It lets us achieve something similar to what we'd do imperatively.
Follows the definition of fixed point in nixpkgs:
{
# Take a function and evaluate it with its own returned value.
fix =
f:
let
result = f result;
in
result;
}
It's a function that accepts a function f
, calls f result
on the result just returned by f result
and returns it. In other words it's f(f(f(....
At first sight, it's an infinite loop. With lazy evaluation it isn't, because the call is done only when needed.
nix-repl> fix = f: let result = f result; in result
nix-repl> pkgs = self: { a = 3; b = 4; c = self.a+self.b; }
nix-repl> fix pkgs
{ a = 3; b = 4; c = 7; }
Without the rec
keyword, we were able to refer to a
and b
of the same set.
-
First
pkgs
gets called with an unevaluated thunk(pkgs(pkgs(...)
-
To set the value of
c
thenself.a
andself.b
are evaluated. -
The
pkgs
function gets called again to get the value ofa
andb
.
The trick is that c
is not needed to be evaluated in the inner call, thus it doesn't go in an infinite loop.
Won't go further with the explanation here. A good post about fixed point and Nix can be found here.
Overriding a set with fixed point
Given that self.a
and self.b
refer to the passed set and not to the literal set in the function, we're able to override both a
and b
and get a new value for c
:
nix-repl> overrides = { a = 1; b = 2; }
nix-repl> let newpkgs = pkgs (newpkgs // overrides); in newpkgs
{ a = 3; b = 4; c = 3; }
nix-repl> let newpkgs = pkgs (newpkgs // overrides); in newpkgs // overrides
{ a = 1; b = 2; c = 3; }
In the first case we computed pkgs with the overrides, in the second case we also included the overridden attributes in the result.
Overriding nixpkgs packages
We've seen how to override attributes in a set such that they get recursively picked by dependent attributes. This approach can be used for derivations too, after all nixpkgs
is a giant set of attributes that depend on each other.
To do this, nixpkgs
offers config.packageOverrides
. So nixpkgs
returns a fixed point of the package set, and packageOverrides
is used to inject the overrides.
Create a config.nix
file like this somewhere:
{
packageOverrides = pkgs: {
graphviz = pkgs.graphviz.override {
# disable xorg support
withXorg = false;
};
};
}
Now we can build e.g. asciidoc-full
and it will automatically use the overridden graphviz
:
nix-repl> pkgs = import <nixpkgs> { config = import ./config.nix; }
nix-repl> :b pkgs.asciidoc-full
Note how we pass the config
with packageOverrides
when importing nixpkgs
. Then pkgs.asciidoc-full
is a derivation that has graphviz
input (pkgs.asciidoc
is the lighter version and doesn't use graphviz
at all).
Since there's no version of asciidoc
with graphviz
without X support in the binary cache, Nix will recompile the needed stuff for you.
The ~/.config/nixpkgs/config.nix file
In the previous pill we already talked about this file. The above config.nix
that we just wrote could be the content of ~/.config/nixpkgs/config.nix
(or the deprecated location ~/.nixpkgs/config.nix
).
Instead of passing it explicitly whenever we import nixpkgs
, it will be automatically imported by nixpkgs.
Conclusion
We've learned about a new design pattern: using fixed point for overriding packages in a package set.
Whereas in an imperative setting, like with other package managers, a library is installed replacing the old version and applications will use it, in Nix it's not that straight and simple. But it's more precise.
Nix applications will depend on specific versions of libraries, hence the reason why we have to recompile asciidoc
to use the new graphviz
library.
The newly built asciidoc
will depend on the new graphviz
, and old asciidoc
will keep using the old graphviz
undisturbed.
Next pill
...we will stop studying nixpkgs
for a moment and talk about store paths. How does Nix compute the path in the store where to place the result of builds? How to add files to the store for which we have an integrity hash?