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705 lines
17 KiB
Markdown
705 lines
17 KiB
Markdown
# Language Constructs
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This section covers syntax and semantics of the Nix language.
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## Basic Literals
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### String {#string-literal}
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See [String literals](string-literals.md).
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### Number {#number-literal}
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<!-- TODO(@rhendric, #10970): split this into int and float -->
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Numbers, which can be *integers* (like `123`) or *floating point*
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(like `123.43` or `.27e13`).
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Integers in the Nix language are 64-bit [two's complement] signed integers, with a range of -9223372036854775808 to 9223372036854775807, inclusive.
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[two's complement]: https://en.wikipedia.org/wiki/Two%27s_complement
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Note that negative numeric literals are actually parsed as unary negation of positive numeric literals.
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This means that the minimum integer `-9223372036854775808` cannot be written as-is as a literal, since the positive number `9223372036854775808` is one past the maximum range.
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See [arithmetic] and [comparison] operators for semantics.
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[arithmetic]: ./operators.md#arithmetic
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[comparison]: ./operators.md#comparison
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### Path {#path-literal}
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*Paths* can be expressed by path literals such as `./builder.sh`.
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A path literal must contain at least one slash to be recognised as such.
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For instance, `builder.sh` is not a path:
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it's parsed as an expression that selects the attribute `sh` from the variable `builder`.
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Path literals are resolved relative to their [base directory](@docroot@/glossary.md#gloss-base-directory).
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Path literals may also refer to absolute paths by starting with a slash.
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> **Note**
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>
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> Absolute paths make expressions less portable.
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> In the case where a function translates a path literal into an absolute path string for a configuration file, it is recommended to write a string literal instead.
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> This avoids some confusion about whether files at that location will be used during evaluation.
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> It also avoids unintentional situations where some function might try to copy everything at the location into the store.
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If the first component of a path is a `~`, it is interpreted such that the rest of the path were relative to the user's home directory.
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For example, `~/foo` would be equivalent to `/home/edolstra/foo` for a user whose home directory is `/home/edolstra`.
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Path literals that start with `~` are not allowed in [pure](@docroot@/command-ref/conf-file.md#conf-pure-eval) evaluation.
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Path literals can also include [string interpolation], besides being [interpolated into other expressions].
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[interpolated into other expressions]: ./string-interpolation.md#interpolated-expressions
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At least one slash (`/`) must appear *before* any interpolated expression for the result to be recognized as a path.
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`a.${foo}/b.${bar}` is a syntactically valid number division operation.
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`./a.${foo}/b.${bar}` is a path.
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[Lookup path](./constructs/lookup-path.md) literals such as `<nixpkgs>` also resolve to path values.
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## List {#list-literal}
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Lists are formed by enclosing a whitespace-separated list of values
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between square brackets. For example,
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```nix
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[ 123 ./foo.nix "abc" (f { x = y; }) ]
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```
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defines a list of four elements, the last being the result of a call to
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the function `f`. Note that function calls have to be enclosed in
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parentheses. If they had been omitted, e.g.,
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```nix
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[ 123 ./foo.nix "abc" f { x = y; } ]
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```
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the result would be a list of five elements, the fourth one being a
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function and the fifth being a set.
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Note that lists are only lazy in values, and they are strict in length.
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Elements in a list can be accessed using [`builtins.elemAt`](./builtins.md#builtins-elemAt).
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## Attribute Set {#attrs-literal}
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An attribute set is a collection of name-value-pairs called *attributes*.
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Attribute sets are written enclosed in curly brackets (`{ }`).
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Attribute names and attribute values are separated by an equal sign (`=`).
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Each value can be an arbitrary expression, terminated by a semicolon (`;`)
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An attribute name is a string without context, and is denoted by a [name] (an [identifier](./identifiers.md#identifiers) or [string literal](string-literals.md)).
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[name]: ./identifiers.md#names
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> **Syntax**
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>
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> *attrset* → `{` { *name* `=` *expr* `;` } `}`
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Attributes can appear in any order.
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An attribute name may only occur once in each attribute set.
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> **Example**
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>
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> This defines an attribute set with attributes named:
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> - `x` with the value `123`, an integer
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> - `text` with the value `"Hello"`, a string
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> - `y` where the value is the result of applying the function `f` to the attribute set `{ bla = 456; }`
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>
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> ```nix
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> {
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> x = 123;
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> text = "Hello";
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> y = f { bla = 456; };
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> }
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> ```
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Attributes in nested attribute sets can be written using *attribute paths*.
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> **Syntax**
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>
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> *attrset* → `{` { *attrpath* `=` *expr* `;` } `}`
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An attribute path is a dot-separated list of [names][name].
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> **Syntax**
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>
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> *attrpath* = *name* { `.` *name* }
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<!-- -->
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> **Example**
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>
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> ```nix
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> { a.b.c = 1; a.b.d = 2; }
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> ```
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>
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> {
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> a = {
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> b = {
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> c = 1;
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> d = 2;
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> };
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> };
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> }
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Attribute names can also be set implicitly by using the [`inherit` keyword](#inheriting-attributes).
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> **Example**
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>
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> ```nix
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> { inherit (builtins) true; }
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> ```
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>
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> { true = true; }
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Attributes can be accessed with the [`.` operator](./operators.md#attribute-selection).
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Example:
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```nix
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{ a = "Foo"; b = "Bar"; }.a
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```
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This evaluates to `"Foo"`.
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It is possible to provide a default value in an attribute selection using the `or` keyword.
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Example:
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```nix
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{ a = "Foo"; b = "Bar"; }.c or "Xyzzy"
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```
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```nix
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{ a = "Foo"; b = "Bar"; }.c.d.e.f.g or "Xyzzy"
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```
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will both evaluate to `"Xyzzy"` because there is no `c` attribute in the set.
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You can use arbitrary double-quoted strings as attribute names:
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```nix
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{ "$!@#?" = 123; }."$!@#?"
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```
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```nix
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let bar = "bar"; in
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{ "foo ${bar}" = 123; }."foo ${bar}"
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```
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Both will evaluate to `123`.
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Attribute names support [string interpolation]:
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```nix
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let bar = "foo"; in
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{ foo = 123; }.${bar}
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```
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```nix
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let bar = "foo"; in
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{ ${bar} = 123; }.foo
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```
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Both will evaluate to `123`.
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In the special case where an attribute name inside of a set declaration
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evaluates to `null` (which is normally an error, as `null` cannot be coerced to
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a string), that attribute is simply not added to the set:
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```nix
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{ ${if foo then "bar" else null} = true; }
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```
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This will evaluate to `{}` if `foo` evaluates to `false`.
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A set that has a [`__functor`]{#attr-__functor} attribute whose value is callable (i.e. is
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itself a function or a set with a `__functor` attribute whose value is
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callable) can be applied as if it were a function, with the set itself
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passed in first , e.g.,
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```nix
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let add = { __functor = self: x: x + self.x; };
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inc = add // { x = 1; };
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in inc 1
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```
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evaluates to `2`. This can be used to attach metadata to a function
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without the caller needing to treat it specially, or to implement a form
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of object-oriented programming, for example.
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## Recursive sets
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Recursive sets are like normal [attribute sets](./types.md#attribute-set), but the attributes can refer to each other.
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> *rec-attrset* = `rec {` [ *name* `=` *expr* `;` `]`... `}`
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Example:
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```nix
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rec {
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x = y;
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y = 123;
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}.x
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```
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This evaluates to `123`.
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Note that without `rec` the binding `x = y;` would
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refer to the variable `y` in the surrounding scope, if one exists, and
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would be invalid if no such variable exists. That is, in a normal
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(non-recursive) set, attributes are not added to the lexical scope; in a
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recursive set, they are.
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Recursive sets of course introduce the danger of infinite recursion. For
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example, the expression
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```nix
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rec {
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x = y;
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y = x;
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}.x
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```
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will crash with an `infinite recursion encountered` error message.
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## Let-expressions
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A let-expression allows you to define local variables for an expression.
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> *let-in* = `let` [ *identifier* = *expr* ]... `in` *expr*
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Example:
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```nix
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let
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x = "foo";
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y = "bar";
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in x + y
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```
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This evaluates to `"foobar"`.
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## Inheriting attributes
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When defining an [attribute set](./types.md#attribute-set) or in a [let-expression](#let-expressions) it is often convenient to copy variables from the surrounding lexical scope (e.g., when you want to propagate attributes).
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This can be shortened using the `inherit` keyword.
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Example:
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```nix
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let x = 123; in
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{
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inherit x;
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y = 456;
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}
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```
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is equivalent to
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```nix
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let x = 123; in
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{
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x = x;
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y = 456;
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}
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```
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and both evaluate to `{ x = 123; y = 456; }`.
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> **Note**
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>
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> This works because `x` is added to the lexical scope by the `let` construct.
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It is also possible to inherit attributes from another attribute set.
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Example:
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In this fragment from `all-packages.nix`,
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```nix
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graphviz = (import ../tools/graphics/graphviz) {
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inherit fetchurl stdenv libpng libjpeg expat x11 yacc;
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inherit (xorg) libXaw;
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};
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xorg = {
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libX11 = ...;
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libXaw = ...;
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...
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}
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libpng = ...;
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libjpg = ...;
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...
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```
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the set used in the function call to the function defined in
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`../tools/graphics/graphviz` inherits a number of variables from the
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surrounding scope (`fetchurl` ... `yacc`), but also inherits `libXaw`
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(the X Athena Widgets) from the `xorg` set.
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Summarizing the fragment
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```nix
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...
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inherit x y z;
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inherit (src-set) a b c;
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...
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```
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is equivalent to
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```nix
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...
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x = x; y = y; z = z;
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a = src-set.a; b = src-set.b; c = src-set.c;
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...
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```
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when used while defining local variables in a let-expression or while
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defining a set.
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In a `let` expression, `inherit` can be used to selectively bring specific attributes of a set into scope. For example
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```nix
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let
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x = { a = 1; b = 2; };
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inherit (builtins) attrNames;
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in
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{
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names = attrNames x;
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}
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```
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is equivalent to
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```nix
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let
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x = { a = 1; b = 2; };
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in
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{
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names = builtins.attrNames x;
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}
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```
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both evaluate to `{ names = [ "a" "b" ]; }`.
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## Functions
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Functions have the following form:
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```nix
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pattern: body
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```
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The pattern specifies what the argument of the function must look like,
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and binds variables in the body to (parts of) the argument. There are
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three kinds of patterns:
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- If a pattern is a single identifier, then the function matches any
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argument. Example:
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```nix
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let negate = x: !x;
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concat = x: y: x + y;
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in if negate true then concat "foo" "bar" else ""
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```
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Note that `concat` is a function that takes one argument and returns
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a function that takes another argument. This allows partial
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parameterisation (i.e., only filling some of the arguments of a
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function); e.g.,
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```nix
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map (concat "foo") [ "bar" "bla" "abc" ]
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```
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evaluates to `[ "foobar" "foobla" "fooabc" ]`.
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- A *set pattern* of the form `{ name1, name2, …, nameN }` matches a
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set containing the listed attributes, and binds the values of those
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attributes to variables in the function body. For example, the
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function
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```nix
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{ x, y, z }: z + y + x
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```
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can only be called with a set containing exactly the attributes `x`,
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`y` and `z`. No other attributes are allowed. If you want to allow
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additional arguments, you can use an ellipsis (`...`):
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```nix
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{ x, y, z, ... }: z + y + x
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```
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This works on any set that contains at least the three named
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attributes.
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It is possible to provide *default values* for attributes, in
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which case they are allowed to be missing. A default value is
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specified by writing `name ? e`, where *e* is an arbitrary
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expression. For example,
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```nix
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{ x, y ? "foo", z ? "bar" }: z + y + x
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```
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specifies a function that only requires an attribute named `x`, but
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optionally accepts `y` and `z`.
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- An `@`-pattern provides a means of referring to the whole value
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being matched:
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```nix
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args@{ x, y, z, ... }: z + y + x + args.a
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```
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but can also be written as:
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```nix
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{ x, y, z, ... } @ args: z + y + x + args.a
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```
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Here `args` is bound to the argument *as passed*, which is further
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matched against the pattern `{ x, y, z, ... }`.
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The `@`-pattern makes mainly sense with an ellipsis(`...`) as
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you can access attribute names as `a`, using `args.a`, which was
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given as an additional attribute to the function.
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> **Warning**
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>
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> `args@` binds the name `args` to the attribute set that is passed to the function.
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> In particular, `args` does *not* include any default values specified with `?` in the function's set pattern.
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>
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> For instance
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>
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> ```nix
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> let
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> f = args@{ a ? 23, ... }: [ a args ];
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> in
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> f {}
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> ```
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>
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> is equivalent to
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>
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> ```nix
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> let
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> f = args @ { ... }: [ (args.a or 23) args ];
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> in
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> f {}
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> ```
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>
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> and both expressions will evaluate to:
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>
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> ```nix
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> [ 23 {} ]
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> ```
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Note that functions do not have names. If you want to give them a name,
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you can bind them to an attribute, e.g.,
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```nix
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let concat = { x, y }: x + y;
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in concat { x = "foo"; y = "bar"; }
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```
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## Conditionals
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Conditionals look like this:
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```nix
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if e1 then e2 else e3
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```
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where *e1* is an expression that should evaluate to a Boolean value
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(`true` or `false`).
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## Assertions
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Assertions are generally used to check that certain requirements on or
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between features and dependencies hold. They look like this:
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```nix
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assert e1; e2
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```
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where *e1* is an expression that should evaluate to a Boolean value. If
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it evaluates to `true`, *e2* is returned; otherwise expression
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evaluation is aborted and a backtrace is printed.
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Here is a Nix expression for the Subversion package that shows how
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assertions can be used:.
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```nix
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{ localServer ? false
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, httpServer ? false
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, sslSupport ? false
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, pythonBindings ? false
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, javaSwigBindings ? false
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, javahlBindings ? false
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, stdenv, fetchurl
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, openssl ? null, httpd ? null, db4 ? null, expat, swig ? null, j2sdk ? null
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}:
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assert localServer -> db4 != null; ①
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assert httpServer -> httpd != null && httpd.expat == expat; ②
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assert sslSupport -> openssl != null && (httpServer -> httpd.openssl == openssl); ③
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assert pythonBindings -> swig != null && swig.pythonSupport;
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assert javaSwigBindings -> swig != null && swig.javaSupport;
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assert javahlBindings -> j2sdk != null;
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stdenv.mkDerivation {
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name = "subversion-1.1.1";
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...
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openssl = if sslSupport then openssl else null; ④
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...
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}
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```
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The points of interest are:
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1. This assertion states that if Subversion is to have support for
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local repositories, then Berkeley DB is needed. So if the Subversion
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function is called with the `localServer` argument set to `true` but
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the `db4` argument set to `null`, then the evaluation fails.
|
|
|
|
Note that `->` is the [logical
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|
implication](https://en.wikipedia.org/wiki/Truth_table#Logical_implication)
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Boolean operation.
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|
|
|
2. This is a more subtle condition: if Subversion is built with Apache
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|
(`httpServer`) support, then the Expat library (an XML library) used
|
|
by Subversion should be same as the one used by Apache. This is
|
|
because in this configuration Subversion code ends up being linked
|
|
with Apache code, and if the Expat libraries do not match, a build-
|
|
or runtime link error or incompatibility might occur.
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|
|
|
3. This assertion says that in order for Subversion to have SSL support
|
|
(so that it can access `https` URLs), an OpenSSL library must be
|
|
passed. Additionally, it says that *if* Apache support is enabled,
|
|
then Apache's OpenSSL should match Subversion's. (Note that if
|
|
Apache support is not enabled, we don't care about Apache's
|
|
OpenSSL.)
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|
|
|
4. The conditional here is not really related to assertions, but is
|
|
worth pointing out: it ensures that if SSL support is disabled, then
|
|
the Subversion derivation is not dependent on OpenSSL, even if a
|
|
non-`null` value was passed. This prevents an unnecessary rebuild of
|
|
Subversion if OpenSSL changes.
|
|
|
|
## With-expressions
|
|
|
|
A *with-expression*,
|
|
|
|
```nix
|
|
with e1; e2
|
|
```
|
|
|
|
introduces the set *e1* into the lexical scope of the expression *e2*.
|
|
For instance,
|
|
|
|
```nix
|
|
let as = { x = "foo"; y = "bar"; };
|
|
in with as; x + y
|
|
```
|
|
|
|
evaluates to `"foobar"` since the `with` adds the `x` and `y` attributes
|
|
of `as` to the lexical scope in the expression `x + y`. The most common
|
|
use of `with` is in conjunction with the `import` function. E.g.,
|
|
|
|
```nix
|
|
with (import ./definitions.nix); ...
|
|
```
|
|
|
|
makes all attributes defined in the file `definitions.nix` available as
|
|
if they were defined locally in a `let`-expression.
|
|
|
|
The bindings introduced by `with` do not shadow bindings introduced by
|
|
other means, e.g.
|
|
|
|
```nix
|
|
let a = 3; in with { a = 1; }; let a = 4; in with { a = 2; }; ...
|
|
```
|
|
|
|
establishes the same scope as
|
|
|
|
```nix
|
|
let a = 1; in let a = 2; in let a = 3; in let a = 4; in ...
|
|
```
|
|
|
|
Variables coming from outer `with` expressions *are* shadowed:
|
|
|
|
```nix
|
|
with { a = "outer"; };
|
|
with { a = "inner"; };
|
|
a
|
|
```
|
|
|
|
Does evaluate to `"inner"`.
|
|
|
|
## Comments
|
|
|
|
- Inline comments start with `#` and run until the end of the line.
|
|
|
|
> **Example**
|
|
>
|
|
> ```nix
|
|
> # A number
|
|
> 2 # Equals 1 + 1
|
|
> ```
|
|
>
|
|
> ```console
|
|
> 2
|
|
> ```
|
|
|
|
- Block comments start with `/*` and run until the next occurrence of `*/`.
|
|
|
|
> **Example**
|
|
>
|
|
> ```nix
|
|
> /*
|
|
> Block comments
|
|
> can span multiple lines.
|
|
> */ "hello"
|
|
> ```
|
|
>
|
|
> ```console
|
|
> "hello"
|
|
> ```
|
|
|
|
This means that block comments cannot be nested.
|
|
|
|
> **Example**
|
|
>
|
|
> ```nix
|
|
> /* /* nope */ */ 1
|
|
> ```
|
|
>
|
|
> ```console
|
|
> error: syntax error, unexpected '*'
|
|
>
|
|
> at «string»:1:15:
|
|
>
|
|
> 1| /* /* nope */ *
|
|
> | ^
|
|
> ```
|
|
|
|
Consider escaping nested comments and unescaping them in post-processing.
|
|
|
|
> **Example**
|
|
>
|
|
> ```nix
|
|
> /* /* nested *\/ */ 1
|
|
> ```
|
|
>
|
|
> ```console
|
|
> 1
|
|
> ```
|