Expand description
A fixed-size array, denoted [T; N]
, for the element type, T
, and the
non-negative compile-time constant size, N
.
There are two syntactic forms for creating an array:
- A list with each element, i.e.,
[x, y, z]
. - A repeat expression
[x; N]
, which produces an array withN
copies ofx
. The type ofx
must beCopy
.
Note that [expr; 0]
is allowed, and produces an empty array.
This will still evaluate expr
, however, and immediately drop the resulting value, so
be mindful of side effects.
Arrays of any size implement the following traits if the element type allows it:
Copy
Clone
Debug
IntoIterator
(implemented for[T; N]
,&[T; N]
and&mut [T; N]
)PartialEq
,PartialOrd
,Eq
,Ord
Hash
AsRef
,AsMut
Borrow
,BorrowMut
Arrays of sizes from 0 to 32 (inclusive) implement the Default
trait
if the element type allows it. As a stopgap, trait implementations are
statically generated up to size 32.
Arrays coerce to slices ([T]
), so a slice method may be called on
an array. Indeed, this provides most of the API for working with arrays.
Slices have a dynamic size and do not coerce to arrays.
You can move elements out of an array with a slice pattern. If you want
one element, see mem::replace
.
Examples
let mut array: [i32; 3] = [0; 3];
array[1] = 1;
array[2] = 2;
assert_eq!([1, 2], &array[1..]);
// This loop prints: 0 1 2
for x in array {
print!("{} ", x);
}
RunYou can also iterate over reference to the array’s elements:
let array: [i32; 3] = [0; 3];
for x in &array { }
RunYou can use a slice pattern to move elements out of an array:
fn move_away(_: String) { /* Do interesting things. */ }
let [john, roa] = ["John".to_string(), "Roa".to_string()];
move_away(john);
move_away(roa);
RunEditions
Prior to Rust 1.53, arrays did not implement IntoIterator
by value, so the method call
array.into_iter()
auto-referenced into a slice iterator. Right now, the old
behavior is preserved in the 2015 and 2018 editions of Rust for compatibility, ignoring
IntoIterator
by value. In the future, the behavior on the 2015 and 2018 edition
might be made consistent to the behavior of later editions.
// Rust 2015 and 2018:
let array: [i32; 3] = [0; 3];
// This creates a slice iterator, producing references to each value.
for item in array.into_iter().enumerate() {
let (i, x): (usize, &i32) = item;
println!("array[{}] = {}", i, x);
}
// The `array_into_iter` lint suggests this change for future compatibility:
for item in array.iter().enumerate() {
let (i, x): (usize, &i32) = item;
println!("array[{}] = {}", i, x);
}
// You can explicitly iterate an array by value using `IntoIterator::into_iter`
for item in IntoIterator::into_iter(array).enumerate() {
let (i, x): (usize, i32) = item;
println!("array[{}] = {}", i, x);
}
RunStarting in the 2021 edition, array.into_iter()
uses IntoIterator
normally to iterate
by value, and iter()
should be used to iterate by reference like previous editions.
// Rust 2021:
let array: [i32; 3] = [0; 3];
// This iterates by reference:
for item in array.iter().enumerate() {
let (i, x): (usize, &i32) = item;
println!("array[{}] = {}", i, x);
}
// This iterates by value:
for item in array.into_iter().enumerate() {
let (i, x): (usize, i32) = item;
println!("array[{}] = {}", i, x);
}
RunFuture language versions might start treating the array.into_iter()
syntax on editions 2015 and 2018 the same as on edition 2021. So code using
those older editions should still be written with this change in mind, to
prevent breakage in the future. The safest way to accomplish this is to
avoid the into_iter
syntax on those editions. If an edition update is not
viable/desired, there are multiple alternatives:
- use
iter
, equivalent to the old behavior, creating references - use
IntoIterator::into_iter
, equivalent to the post-2021 behavior (Rust 1.53+) - replace
for ... in array.into_iter() {
withfor ... in array {
, equivalent to the post-2021 behavior (Rust 1.53+)
// Rust 2015 and 2018:
let array: [i32; 3] = [0; 3];
// This iterates by reference:
for item in array.iter() {
let x: &i32 = item;
println!("{}", x);
}
// This iterates by value:
for item in IntoIterator::into_iter(array) {
let x: i32 = item;
println!("{}", x);
}
// This iterates by value:
for item in array {
let x: i32 = item;
println!("{}", x);
}
// IntoIter can also start a chain.
// This iterates by value:
for item in IntoIterator::into_iter(array).enumerate() {
let (i, x): (usize, i32) = item;
println!("array[{}] = {}", i, x);
}
RunImplementations
Returns an array of the same size as self
, with function f
applied to each element
in order.
If you don’t necessarily need a new fixed-size array, consider using
Iterator::map
instead.
Note on performance and stack usage
Unfortunately, usages of this method are currently not always optimized as well as they could be. This mainly concerns large arrays, as mapping over small arrays seem to be optimized just fine. Also note that in debug mode (i.e. without any optimizations), this method can use a lot of stack space (a few times the size of the array or more).
Therefore, in performance-critical code, try to avoid using this method
on large arrays or check the emitted code. Also try to avoid chained
maps (e.g. arr.map(...).map(...)
).
In many cases, you can instead use Iterator::map
by calling .iter()
or .into_iter()
on your array. [T; N]::map
is only necessary if you
really need a new array of the same size as the result. Rust’s lazy
iterators tend to get optimized very well.
Examples
let x = [1, 2, 3];
let y = x.map(|v| v + 1);
assert_eq!(y, [2, 3, 4]);
let x = [1, 2, 3];
let mut temp = 0;
let y = x.map(|v| { temp += 1; v * temp });
assert_eq!(y, [1, 4, 9]);
let x = ["Ferris", "Bueller's", "Day", "Off"];
let y = x.map(|v| v.len());
assert_eq!(y, [6, 9, 3, 3]);
Runpub fn try_map<F, R>(
self,
f: F
) -> <<R as Try>::Residual as Residual<[R::Output; N]>>::TryType where
F: FnMut(T) -> R,
R: Try,
R::Residual: Residual<[R::Output; N]>,
pub fn try_map<F, R>(
self,
f: F
) -> <<R as Try>::Residual as Residual<[R::Output; N]>>::TryType where
F: FnMut(T) -> R,
R: Try,
R::Residual: Residual<[R::Output; N]>,
A fallible function f
applied to each element on array self
in order to
return an array the same size as self
or the first error encountered.
The return type of this function depends on the return type of the closure.
If you return Result<T, E>
from the closure, you’ll get a Result<[T; N]; E>
.
If you return Option<T>
from the closure, you’ll get an Option<[T; N]>
.
Examples
#![feature(array_try_map)]
let a = ["1", "2", "3"];
let b = a.try_map(|v| v.parse::<u32>()).unwrap().map(|v| v + 1);
assert_eq!(b, [2, 3, 4]);
let a = ["1", "2a", "3"];
let b = a.try_map(|v| v.parse::<u32>());
assert!(b.is_err());
use std::num::NonZeroU32;
let z = [1, 2, 0, 3, 4];
assert_eq!(z.try_map(NonZeroU32::new), None);
let a = [1, 2, 3];
let b = a.try_map(NonZeroU32::new);
let c = b.map(|x| x.map(NonZeroU32::get));
assert_eq!(c, Some(a));
Run‘Zips up’ two arrays into a single array of pairs.
zip()
returns a new array where every element is a tuple where the
first element comes from the first array, and the second element comes
from the second array. In other words, it zips two arrays together,
into a single one.
Examples
#![feature(array_zip)]
let x = [1, 2, 3];
let y = [4, 5, 6];
let z = x.zip(y);
assert_eq!(z, [(1, 4), (2, 5), (3, 6)]);
RunReturns a slice containing the entire array. Equivalent to &s[..]
.
Returns a mutable slice containing the entire array. Equivalent to
&mut s[..]
.
Borrows each element and returns an array of references with the same
size as self
.
Example
#![feature(array_methods)]
let floats = [3.1, 2.7, -1.0];
let float_refs: [&f64; 3] = floats.each_ref();
assert_eq!(float_refs, [&3.1, &2.7, &-1.0]);
RunThis method is particularly useful if combined with other methods, like
map
. This way, you can avoid moving the original
array if its elements are not Copy
.
#![feature(array_methods)]
let strings = ["Ferris".to_string(), "♥".to_string(), "Rust".to_string()];
let is_ascii = strings.each_ref().map(|s| s.is_ascii());
assert_eq!(is_ascii, [true, false, true]);
// We can still access the original array: it has not been moved.
assert_eq!(strings.len(), 3);
RunBorrows each element mutably and returns an array of mutable references
with the same size as self
.
Example
#![feature(array_methods)]
let mut floats = [3.1, 2.7, -1.0];
let float_refs: [&mut f64; 3] = floats.each_mut();
*float_refs[0] = 0.0;
assert_eq!(float_refs, [&mut 0.0, &mut 2.7, &mut -1.0]);
assert_eq!(floats, [0.0, 2.7, -1.0]);
RunDivides one array reference into two at an index.
The first will contain all indices from [0, M)
(excluding
the index M
itself) and the second will contain all
indices from [M, N)
(excluding the index N
itself).
Panics
Panics if M > N
.
Examples
#![feature(split_array)]
let v = [1, 2, 3, 4, 5, 6];
{
let (left, right) = v.split_array_ref::<0>();
assert_eq!(left, &[]);
assert_eq!(right, &[1, 2, 3, 4, 5, 6]);
}
{
let (left, right) = v.split_array_ref::<2>();
assert_eq!(left, &[1, 2]);
assert_eq!(right, &[3, 4, 5, 6]);
}
{
let (left, right) = v.split_array_ref::<6>();
assert_eq!(left, &[1, 2, 3, 4, 5, 6]);
assert_eq!(right, &[]);
}
RunDivides one mutable array reference into two at an index.
The first will contain all indices from [0, M)
(excluding
the index M
itself) and the second will contain all
indices from [M, N)
(excluding the index N
itself).
Panics
Panics if M > N
.
Examples
#![feature(split_array)]
let mut v = [1, 0, 3, 0, 5, 6];
let (left, right) = v.split_array_mut::<2>();
assert_eq!(left, &mut [1, 0][..]);
assert_eq!(right, &mut [3, 0, 5, 6]);
left[1] = 2;
right[1] = 4;
assert_eq!(v, [1, 2, 3, 4, 5, 6]);
RunDivides one array reference into two at an index from the end.
The first will contain all indices from [0, N - M)
(excluding
the index N - M
itself) and the second will contain all
indices from [N - M, N)
(excluding the index N
itself).
Panics
Panics if M > N
.
Examples
#![feature(split_array)]
let v = [1, 2, 3, 4, 5, 6];
{
let (left, right) = v.rsplit_array_ref::<0>();
assert_eq!(left, &[1, 2, 3, 4, 5, 6]);
assert_eq!(right, &[]);
}
{
let (left, right) = v.rsplit_array_ref::<2>();
assert_eq!(left, &[1, 2, 3, 4]);
assert_eq!(right, &[5, 6]);
}
{
let (left, right) = v.rsplit_array_ref::<6>();
assert_eq!(left, &[]);
assert_eq!(right, &[1, 2, 3, 4, 5, 6]);
}
RunDivides one mutable array reference into two at an index from the end.
The first will contain all indices from [0, N - M)
(excluding
the index N - M
itself) and the second will contain all
indices from [N - M, N)
(excluding the index N
itself).
Panics
Panics if M > N
.
Examples
#![feature(split_array)]
let mut v = [1, 0, 3, 0, 5, 6];
let (left, right) = v.rsplit_array_mut::<4>();
assert_eq!(left, &mut [1, 0]);
assert_eq!(right, &mut [3, 0, 5, 6][..]);
left[1] = 2;
right[1] = 4;
assert_eq!(v, [1, 2, 3, 4, 5, 6]);
RunTrait Implementations
impl<T, const LANES: usize> AsMut<[T; LANES]> for Simd<T, LANES> where
LaneCount<LANES>: SupportedLaneCount,
T: SimdElement,
impl<T, const LANES: usize> AsMut<[T; LANES]> for Simd<T, LANES> where
LaneCount<LANES>: SupportedLaneCount,
T: SimdElement,
impl<T, const LANES: usize> AsRef<[T; LANES]> for Simd<T, LANES> where
LaneCount<LANES>: SupportedLaneCount,
T: SimdElement,
impl<T, const LANES: usize> AsRef<[T; LANES]> for Simd<T, LANES> where
LaneCount<LANES>: SupportedLaneCount,
T: SimdElement,
Mutably borrows from an owned value. Read more
impl<T, const LANES: usize> From<[T; LANES]> for Simd<T, LANES> where
LaneCount<LANES>: SupportedLaneCount,
T: SimdElement,
impl<T, const LANES: usize> From<[T; LANES]> for Simd<T, LANES> where
LaneCount<LANES>: SupportedLaneCount,
T: SimdElement,
impl<T, const LANES: usize> From<[bool; LANES]> for Mask<T, LANES> where
T: MaskElement,
LaneCount<LANES>: SupportedLaneCount,
impl<T, const LANES: usize> From<[bool; LANES]> for Mask<T, LANES> where
T: MaskElement,
LaneCount<LANES>: SupportedLaneCount,
impl<T, const LANES: usize> From<Mask<T, LANES>> for [bool; LANES] where
T: MaskElement,
LaneCount<LANES>: SupportedLaneCount,
impl<T, const LANES: usize> From<Mask<T, LANES>> for [bool; LANES] where
T: MaskElement,
LaneCount<LANES>: SupportedLaneCount,
impl<T, const LANES: usize> From<Simd<T, LANES>> for [T; LANES] where
LaneCount<LANES>: SupportedLaneCount,
T: SimdElement,
impl<T, const LANES: usize> From<Simd<T, LANES>> for [T; LANES] where
LaneCount<LANES>: SupportedLaneCount,
T: SimdElement,
The hash of an array is the same as that of the corresponding slice,
as required by the Borrow
implementation.
#![feature(build_hasher_simple_hash_one)]
use std::hash::BuildHasher;
let b = std::collections::hash_map::RandomState::new();
let a: [u8; 3] = [0xa8, 0x3c, 0x09];
let s: &[u8] = &[0xa8, 0x3c, 0x09];
assert_eq!(b.hash_one(a), b.hash_one(s));
RunCreates a consuming iterator, that is, one that moves each value out of
the array (from start to end). The array cannot be used after calling
this unless T
implements Copy
, so the whole array is copied.
Arrays have special behavior when calling .into_iter()
prior to the
2021 edition – see the array Editions section for more information.
type Item = T
type Item = T
The type of the elements being iterated over.
Implements comparison of arrays lexicographically.
This method returns an ordering between self
and other
values if one exists. Read more
This method tests less than (for self
and other
) and is used by the <
operator. Read more
This method tests less than or equal to (for self
and other
) and is used by the <=
operator. Read more
This method tests greater than or equal to (for self
and other
) and is used by the >=
operator. Read more
Searches for chars that are equal to any of the char
s in the array.
Examples
assert_eq!("Hello world".find(['l', 'l']), Some(2));
assert_eq!("Hello world".find(['l', 'l']), Some(2));
RunChecks whether the pattern matches anywhere in the haystack
Checks whether the pattern matches at the front of the haystack
Removes the pattern from the front of haystack, if it matches.
fn is_suffix_of(self, haystack: &'a str) -> bool where
CharArraySearcher<'a, N>: ReverseSearcher<'a>,
fn is_suffix_of(self, haystack: &'a str) -> bool where
CharArraySearcher<'a, N>: ReverseSearcher<'a>,
Checks whether the pattern matches at the back of the haystack
fn strip_suffix_of(self, haystack: &'a str) -> Option<&'a str> where
CharArraySearcher<'a, N>: ReverseSearcher<'a>,
fn strip_suffix_of(self, haystack: &'a str) -> Option<&'a str> where
CharArraySearcher<'a, N>: ReverseSearcher<'a>,
Removes the pattern from the back of haystack, if it matches.
Searches for chars that are equal to any of the char
s in the array.
Examples
assert_eq!("Hello world".find(&['l', 'l']), Some(2));
assert_eq!("Hello world".find(&['l', 'l']), Some(2));
RunChecks whether the pattern matches anywhere in the haystack
Checks whether the pattern matches at the front of the haystack
Removes the pattern from the front of haystack, if it matches.
fn is_suffix_of(self, haystack: &'a str) -> bool where
CharArrayRefSearcher<'a, 'b, N>: ReverseSearcher<'a>,
fn is_suffix_of(self, haystack: &'a str) -> bool where
CharArrayRefSearcher<'a, 'b, N>: ReverseSearcher<'a>,
Checks whether the pattern matches at the back of the haystack
fn strip_suffix_of(self, haystack: &'a str) -> Option<&'a str> where
CharArrayRefSearcher<'a, 'b, N>: ReverseSearcher<'a>,
fn strip_suffix_of(self, haystack: &'a str) -> Option<&'a str> where
CharArrayRefSearcher<'a, 'b, N>: ReverseSearcher<'a>,
Removes the pattern from the back of haystack, if it matches.
type Error = TryFromSliceError
type Error = TryFromSliceError
The type returned in the event of a conversion error.
type Error = TryFromSliceError
type Error = TryFromSliceError
The type returned in the event of a conversion error.
type Error = TryFromSliceError
type Error = TryFromSliceError
The type returned in the event of a conversion error.
type Error = TryFromSliceError
type Error = TryFromSliceError
The type returned in the event of a conversion error.