nixpkgs/lib/trivial.nix
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{ lib }:
let
inherit (lib.trivial)
isFunction
isInt
functionArgs
pathExists
release
setFunctionArgs
toBaseDigits
version
versionSuffix
warn;
inherit (lib)
isString
;
in {
## Simple (higher order) functions
/**
The identity function
For when you need a function that does nothing.
# Inputs
`x`
: The value to return
# Type
```
id :: a -> a
```
*/
id = x: x;
/**
The constant function
Ignores the second argument. If called with only one argument,
constructs a function that always returns a static value.
# Inputs
`x`
: Value to return
`y`
: Value to ignore
# Type
```
const :: a -> b -> a
```
# Examples
:::{.example}
## `lib.trivial.const` usage example
```nix
let f = const 5; in f 10
=> 5
```
:::
*/
const =
x:
y: x;
/**
Pipes a value through a list of functions, left to right.
# Inputs
`value`
: Value to start piping.
`fns`
: List of functions to apply sequentially.
# Type
```
pipe :: a -> [<functions>] -> <return type of last function>
```
# Examples
:::{.example}
## `lib.trivial.pipe` usage example
```nix
pipe 2 [
(x: x + 2) # 2 + 2 = 4
(x: x * 2) # 4 * 2 = 8
]
=> 8
# ideal to do text transformations
pipe [ "a/b" "a/c" ] [
# create the cp command
(map (file: ''cp "${src}/${file}" $out\n''))
# concatenate all commands into one string
lib.concatStrings
# make that string into a nix derivation
(pkgs.runCommand "copy-to-out" {})
]
=> <drv which copies all files to $out>
The output type of each function has to be the input type
of the next function, and the last function returns the
final value.
```
:::
*/
pipe = builtins.foldl' (x: f: f x);
# note please dont add a function like `compose = flip pipe`.
# This would confuse users, because the order of the functions
# in the list is not clear. With pipe, its obvious that it
# goes first-to-last. With `compose`, not so much.
## Named versions corresponding to some builtin operators.
/**
Concatenate two lists
# Inputs
`x`
: 1\. Function argument
`y`
: 2\. Function argument
# Type
```
concat :: [a] -> [a] -> [a]
```
# Examples
:::{.example}
## `lib.trivial.concat` usage example
```nix
concat [ 1 2 ] [ 3 4 ]
=> [ 1 2 3 4 ]
```
:::
*/
concat = x: y: x ++ y;
/**
boolean or
# Inputs
`x`
: 1\. Function argument
`y`
: 2\. Function argument
*/
or = x: y: x || y;
/**
boolean and
# Inputs
`x`
: 1\. Function argument
`y`
: 2\. Function argument
*/
and = x: y: x && y;
/**
boolean exclusive or
# Inputs
`x`
: 1\. Function argument
`y`
: 2\. Function argument
*/
# We explicitly invert the arguments purely as a type assertion.
# This is invariant under XOR, so it does not affect the result.
xor = x: y: (!x) != (!y);
/**
bitwise not
*/
bitNot = builtins.sub (-1);
/**
Convert a boolean to a string.
This function uses the strings "true" and "false" to represent
boolean values. Calling `toString` on a bool instead returns "1"
and "" (sic!).
# Inputs
`b`
: 1\. Function argument
# Type
```
boolToString :: bool -> string
```
*/
boolToString = b: if b then "true" else "false";
/**
Merge two attribute sets shallowly, right side trumps left
mergeAttrs :: attrs -> attrs -> attrs
# Inputs
`x`
: Left attribute set
`y`
: Right attribute set (higher precedence for equal keys)
# Examples
:::{.example}
## `lib.trivial.mergeAttrs` usage example
```nix
mergeAttrs { a = 1; b = 2; } { b = 3; c = 4; }
=> { a = 1; b = 3; c = 4; }
```
:::
*/
mergeAttrs =
x:
y: x // y;
/**
Flip the order of the arguments of a binary function.
# Inputs
`f`
: 1\. Function argument
`a`
: 2\. Function argument
`b`
: 3\. Function argument
# Type
```
flip :: (a -> b -> c) -> (b -> a -> c)
```
# Examples
:::{.example}
## `lib.trivial.flip` usage example
```nix
flip concat [1] [2]
=> [ 2 1 ]
```
:::
*/
flip = f: a: b: f b a;
/**
Return `maybeValue` if not null, otherwise return `default`.
# Inputs
`default`
: 1\. Function argument
`maybeValue`
: 2\. Function argument
# Examples
:::{.example}
## `lib.trivial.defaultTo` usage example
```nix
defaultTo "default" null
=> "default"
defaultTo "default" "foo"
=> "foo"
defaultTo "default" false
=> false
```
:::
*/
defaultTo = default: maybeValue:
if maybeValue != null then maybeValue
else default;
/**
Apply function if the supplied argument is non-null.
# Inputs
`f`
: Function to call
`a`
: Argument to check for null before passing it to `f`
# Examples
:::{.example}
## `lib.trivial.mapNullable` usage example
```nix
mapNullable (x: x+1) null
=> null
mapNullable (x: x+1) 22
=> 23
```
:::
*/
mapNullable =
f:
a: if a == null then a else f a;
# Pull in some builtins not included elsewhere.
inherit (builtins)
pathExists readFile isBool
isInt isFloat add sub lessThan
seq deepSeq genericClosure
bitAnd bitOr bitXor;
## nixpkgs version strings
/**
Returns the current full nixpkgs version number.
*/
version = release + versionSuffix;
/**
Returns the current nixpkgs release number as string.
*/
release = lib.strings.fileContents ./.version;
/**
The latest release that is supported, at the time of release branch-off,
if applicable.
Ideally, out-of-tree modules should be able to evaluate cleanly with all
supported Nixpkgs versions (master, release and old release until EOL).
So if possible, deprecation warnings should take effect only when all
out-of-tree expressions/libs/modules can upgrade to the new way without
losing support for supported Nixpkgs versions.
This release number allows deprecation warnings to be implemented such that
they take effect as soon as the oldest release reaches end of life.
*/
oldestSupportedRelease =
# Update on master only. Do not backport.
2405;
/**
Whether a feature is supported in all supported releases (at the time of
release branch-off, if applicable). See `oldestSupportedRelease`.
# Inputs
`release`
: Release number of feature introduction as an integer, e.g. 2111 for 21.11.
Set it to the upcoming release, matching the nixpkgs/.version file.
*/
isInOldestRelease =
lib.warnIf (lib.oldestSupportedReleaseIsAtLeast 2411)
"lib.isInOldestRelease is deprecated. Use lib.oldestSupportedReleaseIsAtLeast instead."
lib.oldestSupportedReleaseIsAtLeast;
/**
Alias for `isInOldestRelease` introduced in 24.11.
Use `isInOldestRelease` in expressions outside of Nixpkgs for greater compatibility.
*/
oldestSupportedReleaseIsAtLeast =
release:
release <= lib.trivial.oldestSupportedRelease;
/**
Returns the current nixpkgs release code name.
On each release the first letter is bumped and a new animal is chosen
starting with that new letter.
*/
codeName = "Warbler";
/**
Returns the current nixpkgs version suffix as string.
*/
versionSuffix =
let suffixFile = ../.version-suffix;
in if pathExists suffixFile
then lib.strings.fileContents suffixFile
else "pre-git";
/**
Attempts to return the the current revision of nixpkgs and
returns the supplied default value otherwise.
# Inputs
`default`
: Default value to return if revision can not be determined
# Type
```
revisionWithDefault :: string -> string
```
*/
revisionWithDefault =
default:
let
revisionFile = "${toString ./..}/.git-revision";
gitRepo = "${toString ./..}/.git";
in if lib.pathIsGitRepo gitRepo
then lib.commitIdFromGitRepo gitRepo
else if lib.pathExists revisionFile then lib.fileContents revisionFile
else default;
nixpkgsVersion = warn "lib.nixpkgsVersion is a deprecated alias of lib.version." version;
/**
Determine whether the function is being called from inside a Nix
shell.
# Type
```
inNixShell :: bool
```
*/
inNixShell = builtins.getEnv "IN_NIX_SHELL" != "";
/**
Determine whether the function is being called from inside pure-eval mode
by seeing whether `builtins` contains `currentSystem`. If not, we must be in
pure-eval mode.
# Type
```
inPureEvalMode :: bool
```
*/
inPureEvalMode = ! builtins ? currentSystem;
## Integer operations
/**
Return minimum of two numbers.
# Inputs
`x`
: 1\. Function argument
`y`
: 2\. Function argument
*/
min = x: y: if x < y then x else y;
/**
Return maximum of two numbers.
# Inputs
`x`
: 1\. Function argument
`y`
: 2\. Function argument
*/
max = x: y: if x > y then x else y;
/**
Integer modulus
# Inputs
`base`
: 1\. Function argument
`int`
: 2\. Function argument
# Examples
:::{.example}
## `lib.trivial.mod` usage example
```nix
mod 11 10
=> 1
mod 1 10
=> 1
```
:::
*/
mod = base: int: base - (int * (builtins.div base int));
## Comparisons
/**
C-style comparisons
a < b, compare a b => -1
a == b, compare a b => 0
a > b, compare a b => 1
# Inputs
`a`
: 1\. Function argument
`b`
: 2\. Function argument
*/
compare = a: b:
if a < b
then -1
else if a > b
then 1
else 0;
/**
Split type into two subtypes by predicate `p`, take all elements
of the first subtype to be less than all the elements of the
second subtype, compare elements of a single subtype with `yes`
and `no` respectively.
# Inputs
`p`
: Predicate
`yes`
: Comparison function if predicate holds for both values
`no`
: Comparison function if predicate holds for neither value
`a`
: First value to compare
`b`
: Second value to compare
# Type
```
(a -> bool) -> (a -> a -> int) -> (a -> a -> int) -> (a -> a -> int)
```
# Examples
:::{.example}
## `lib.trivial.splitByAndCompare` usage example
```nix
let cmp = splitByAndCompare (hasPrefix "foo") compare compare; in
cmp "a" "z" => -1
cmp "fooa" "fooz" => -1
cmp "f" "a" => 1
cmp "fooa" "a" => -1
# while
compare "fooa" "a" => 1
```
:::
*/
splitByAndCompare =
p: yes: no: a: b:
if p a
then if p b then yes a b else -1
else if p b then 1 else no a b;
/**
Reads a JSON file.
# Examples
:::{.example}
## `lib.trivial.importJSON` usage example
example.json
```json
{
"title": "Example JSON",
"hello": {
"world": "foo",
"bar": {
"foobar": true
}
}
}
```
```nix
importJSON ./example.json
=> {
title = "Example JSON";
hello = {
world = "foo";
bar = {
foobar = true;
};
};
}
```
:::
# Inputs
`path`
: 1\. Function argument
# Type
```
importJSON :: path -> any
```
*/
importJSON = path:
builtins.fromJSON (builtins.readFile path);
/**
Reads a TOML file.
# Examples
:::{.example}
## `lib.trivial.importTOML` usage example
example.toml
```toml
title = "TOML Example"
[hello]
world = "foo"
[hello.bar]
foobar = true
```
```nix
importTOML ./example.toml
=> {
title = "TOML Example";
hello = {
world = "foo";
bar = {
foobar = true;
};
};
}
```
:::
# Inputs
`path`
: 1\. Function argument
# Type
```
importTOML :: path -> any
```
*/
importTOML = path:
builtins.fromTOML (builtins.readFile path);
/**
`warn` *`message`* *`value`*
Print a warning before returning the second argument.
See [`builtins.warn`](https://nix.dev/manual/nix/latest/language/builtins.html#builtins-warn) (Nix >= 2.23).
On older versions, the Nix 2.23 behavior is emulated with [`builtins.trace`](https://nix.dev/manual/nix/latest/language/builtins.html#builtins-warn), including the [`NIX_ABORT_ON_WARN`](https://nix.dev/manual/nix/latest/command-ref/conf-file#conf-abort-on-warn) behavior, but not the `nix.conf` setting or command line option.
# Inputs
*`message`* (String)
: Warning message to print before evaluating *`value`*.
*`value`* (any value)
: Value to return as-is.
# Type
```
String -> a -> a
```
*/
warn =
# Since Nix 2.23, https://github.com/NixOS/nix/pull/10592
builtins.warn or (
let mustAbort = lib.elem (builtins.getEnv "NIX_ABORT_ON_WARN") ["1" "true" "yes"];
in
# Do not eta reduce v, so that we have the same strictness as `builtins.warn`.
msg: v:
# `builtins.warn` requires a string message, so we enforce that in our implementation, so that callers aren't accidentally incompatible with newer Nix versions.
assert isString msg;
if mustAbort
then builtins.trace "evaluation warning: ${msg}" (abort "NIX_ABORT_ON_WARN=true; warnings are treated as unrecoverable errors.")
else builtins.trace "evaluation warning: ${msg}" v
);
/**
`warnIf` *`condition`* *`message`* *`value`*
Like `warn`, but only warn when the first argument is `true`.
# Inputs
*`condition`* (Boolean)
: `true` to trigger the warning before continuing with *`value`*.
*`message`* (String)
: Warning message to print before evaluating
*`value`* (any value)
: Value to return as-is.
# Type
```
Bool -> String -> a -> a
```
*/
warnIf = cond: msg: if cond then warn msg else x: x;
/**
`warnIfNot` *`condition`* *`message`* *`value`*
Like `warnIf`, but negated: warn if the first argument is `false`.
# Inputs
*`condition`*
: `false` to trigger the warning before continuing with `val`.
*`message`*
: Warning message to print before evaluating *`value`*.
*`value`*
: Value to return as-is.
# Type
```
Boolean -> String -> a -> a
```
*/
warnIfNot = cond: msg: if cond then x: x else warn msg;
/**
Like the `assert b; e` expression, but with a custom error message and
without the semicolon.
If true, return the identity function, `r: r`.
If false, throw the error message.
Calls can be juxtaposed using function application, as `(r: r) a = a`, so
`(r: r) (r: r) a = a`, and so forth.
# Inputs
`cond`
: 1\. Function argument
`msg`
: 2\. Function argument
# Type
```
bool -> string -> a -> a
```
# Examples
:::{.example}
## `lib.trivial.throwIfNot` usage example
```nix
throwIfNot (lib.isList overlays) "The overlays argument to nixpkgs must be a list."
lib.foldr (x: throwIfNot (lib.isFunction x) "All overlays passed to nixpkgs must be functions.") (r: r) overlays
pkgs
```
:::
*/
throwIfNot = cond: msg: if cond then x: x else throw msg;
/**
Like throwIfNot, but negated (throw if the first argument is `true`).
# Inputs
`cond`
: 1\. Function argument
`msg`
: 2\. Function argument
# Type
```
bool -> string -> a -> a
```
*/
throwIf = cond: msg: if cond then throw msg else x: x;
/**
Check if the elements in a list are valid values from a enum, returning the identity function, or throwing an error message otherwise.
# Inputs
`msg`
: 1\. Function argument
`valid`
: 2\. Function argument
`given`
: 3\. Function argument
# Type
```
String -> List ComparableVal -> List ComparableVal -> a -> a
```
# Examples
:::{.example}
## `lib.trivial.checkListOfEnum` usage example
```nix
let colorVariants = ["bright" "dark" "black"]
in checkListOfEnum "color variants" [ "standard" "light" "dark" ] colorVariants;
=>
error: color variants: bright, black unexpected; valid ones: standard, light, dark
```
:::
*/
checkListOfEnum = msg: valid: given:
let
unexpected = lib.subtractLists valid given;
in
lib.throwIfNot (unexpected == [])
"${msg}: ${builtins.concatStringsSep ", " (builtins.map builtins.toString unexpected)} unexpected; valid ones: ${builtins.concatStringsSep ", " (builtins.map builtins.toString valid)}";
info = msg: builtins.trace "INFO: ${msg}";
showWarnings = warnings: res: lib.foldr (w: x: warn w x) res warnings;
## Function annotations
/**
Add metadata about expected function arguments to a function.
The metadata should match the format given by
builtins.functionArgs, i.e. a set from expected argument to a bool
representing whether that argument has a default or not.
setFunctionArgs : (a b) Map String Bool (a b)
This function is necessary because you can't dynamically create a
function of the { a, b ? foo, ... }: format, but some facilities
like callPackage expect to be able to query expected arguments.
# Inputs
`f`
: 1\. Function argument
`args`
: 2\. Function argument
*/
setFunctionArgs = f: args:
{ # TODO: Should we add call-time "type" checking like built in?
__functor = self: f;
__functionArgs = args;
};
/**
Extract the expected function arguments from a function.
This works both with nix-native { a, b ? foo, ... }: style
functions and functions with args set with 'setFunctionArgs'. It
has the same return type and semantics as builtins.functionArgs.
setFunctionArgs : (a b) Map String Bool.
# Inputs
`f`
: 1\. Function argument
*/
functionArgs = f:
if f ? __functor
then f.__functionArgs or (functionArgs (f.__functor f))
else builtins.functionArgs f;
/**
Check whether something is a function or something
annotated with function args.
# Inputs
`f`
: 1\. Function argument
*/
isFunction = f: builtins.isFunction f ||
(f ? __functor && isFunction (f.__functor f));
/**
`mirrorFunctionArgs f g` creates a new function `g'` with the same behavior as `g` (`g' x == g x`)
but its function arguments mirroring `f` (`lib.functionArgs g' == lib.functionArgs f`).
# Inputs
`f`
: Function to provide the argument metadata
`g`
: Function to set the argument metadata to
# Type
```
mirrorFunctionArgs :: (a -> b) -> (a -> c) -> (a -> c)
```
# Examples
:::{.example}
## `lib.trivial.mirrorFunctionArgs` usage example
```nix
addab = {a, b}: a + b
addab { a = 2; b = 4; }
=> 6
lib.functionArgs addab
=> { a = false; b = false; }
addab1 = attrs: addab attrs + 1
addab1 { a = 2; b = 4; }
=> 7
lib.functionArgs addab1
=> { }
addab1' = lib.mirrorFunctionArgs addab addab1
addab1' { a = 2; b = 4; }
=> 7
lib.functionArgs addab1'
=> { a = false; b = false; }
```
:::
*/
mirrorFunctionArgs =
f:
let
fArgs = functionArgs f;
in
g:
setFunctionArgs g fArgs;
/**
Turns any non-callable values into constant functions.
Returns callable values as is.
# Inputs
`v`
: Any value
# Examples
:::{.example}
## `lib.trivial.toFunction` usage example
```nix
nix-repl> lib.toFunction 1 2
1
nix-repl> lib.toFunction (x: x + 1) 2
3
```
:::
*/
toFunction =
v:
if isFunction v
then v
else k: v;
/**
Convert a hexadecimal string to it's integer representation.
# Type
```
fromHexString :: String -> [ String ]
```
# Examples
```nix
fromHexString "FF"
=> 255
fromHexString (builtins.hashString "sha256" "test")
=> 9223372036854775807
```
*/
fromHexString = value:
let
noPrefix = lib.strings.removePrefix "0x" (lib.strings.toLower value);
in let
parsed = builtins.fromTOML "v=0x${noPrefix}";
in parsed.v;
/**
Convert the given positive integer to a string of its hexadecimal
representation. For example:
toHexString 0 => "0"
toHexString 16 => "10"
toHexString 250 => "FA"
*/
toHexString = let
hexDigits = {
"10" = "A";
"11" = "B";
"12" = "C";
"13" = "D";
"14" = "E";
"15" = "F";
};
toHexDigit = d:
if d < 10
then toString d
else hexDigits.${toString d};
in i: lib.concatMapStrings toHexDigit (toBaseDigits 16 i);
/**
`toBaseDigits base i` converts the positive integer i to a list of its
digits in the given base. For example:
toBaseDigits 10 123 => [ 1 2 3 ]
toBaseDigits 2 6 => [ 1 1 0 ]
toBaseDigits 16 250 => [ 15 10 ]
# Inputs
`base`
: 1\. Function argument
`i`
: 2\. Function argument
*/
toBaseDigits = base: i:
let
go = i:
if i < base
then [i]
else
let
r = i - ((i / base) * base);
q = (i - r) / base;
in
[r] ++ go q;
in
assert (isInt base);
assert (isInt i);
assert (base >= 2);
assert (i >= 0);
lib.reverseList (go i);
}