pub enum Option<T> {
None,
Some(T),
}The Option type. See the module level documentation for more.
No value.
§1.0.0Some value of type T.
Returns true if the option is a Some value.
let x: Option<u32> = Some(2);
assert_eq!(x.is_some(), true);
let x: Option<u32> = None;
assert_eq!(x.is_some(), false);Returns true if the option is a Some and the value inside of it matches a predicate.
let x: Option<u32> = Some(2);
assert_eq!(x.is_some_and(|x| x > 1), true);
let x: Option<u32> = Some(0);
assert_eq!(x.is_some_and(|x| x > 1), false);
let x: Option<u32> = None;
assert_eq!(x.is_some_and(|x| x > 1), false);
let x: Option<String> = Some("ownership".to_string());
assert_eq!(x.as_ref().is_some_and(|x| x.len() > 1), true);
println!("still alive {:?}", x);Returns true if the option is a None value.
let x: Option<u32> = Some(2);
assert_eq!(x.is_none(), false);
let x: Option<u32> = None;
assert_eq!(x.is_none(), true);Returns true if the option is a None or the value inside of it matches a predicate.
let x: Option<u32> = Some(2);
assert_eq!(x.is_none_or(|x| x > 1), true);
let x: Option<u32> = Some(0);
assert_eq!(x.is_none_or(|x| x > 1), false);
let x: Option<u32> = None;
assert_eq!(x.is_none_or(|x| x > 1), true);
let x: Option<String> = Some("ownership".to_string());
assert_eq!(x.as_ref().is_none_or(|x| x.len() > 1), true);
println!("still alive {:?}", x);Converts from &Option<T> to Option<&T>.
Calculates the length of an Option<String> as an Option<usize> without moving the String. The map method takes the self argument by value, consuming the original, so this technique uses as_ref to first take an Option to a reference to the value inside the original.
let text: Option<String> = Some("Hello, world!".to_string());
let text_length: Option<usize> = text.as_ref().map(|s| s.len());
println!("still can print text: {text:?}");Converts from &mut Option<T> to Option<&mut T>.
let mut x = Some(2);
match x.as_mut() {
Some(v) => *v = 42,
None => {},
}
assert_eq!(x, Some(42));Converts from Pin<&Option<T>> to Option<Pin<&T>>.
Converts from Pin<&mut Option<T>> to Option<Pin<&mut T>>.
Returns a slice of the contained value, if any. If this is None, an empty slice is returned. This can be useful to have a single type of iterator over an Option or slice.
Note: Should you have an Option<&T> and wish to get a slice of T, you can unpack it via opt.map_or(&[], std::slice::from_ref).
assert_eq!(
[Some(1234).as_slice(), None.as_slice()],
[&[1234][..], &[][..]],
);The inverse of this function is (discounting borrowing) [_]::first:
for i in [Some(1234_u16), None] {
assert_eq!(i.as_ref(), i.as_slice().first());
}Returns a mutable slice of the contained value, if any. If this is None, an empty slice is returned. This can be useful to have a single type of iterator over an Option or slice.
Note: Should you have an Option<&mut T> instead of a &mut Option<T>, which this method takes, you can obtain a mutable slice via opt.map_or(&mut [], std::slice::from_mut).
assert_eq!(
[Some(1234).as_mut_slice(), None.as_mut_slice()],
[&mut [1234][..], &mut [][..]],
);The result is a mutable slice of zero or one items that points into our original Option:
let mut x = Some(1234);
x.as_mut_slice()[0] += 1;
assert_eq!(x, Some(1235));The inverse of this method (discounting borrowing) is [_]::first_mut:
assert_eq!(Some(123).as_mut_slice().first_mut(), Some(&mut 123))Returns the contained Some value, consuming the self value.
Panics if the value is a None with a custom panic message provided by msg.
let x = Some("value");
assert_eq!(x.expect("fruits are healthy"), "value");let x: Option<&str> = None;
x.expect("fruits are healthy"); We recommend that expect messages are used to describe the reason you expect the Option should be Some.
let item = slice.get(0)
.expect("slice should not be empty");Hint: If youâre having trouble remembering how to phrase expect error messages remember to focus on the word âshouldâ as in âenv variable should be set by blahâ or âthe given binary should be available and executable by the current userâ.
For more detail on expect message styles and the reasoning behind our recommendation please refer to the section on âCommon Message Stylesâ in the std::error module docs.
Returns the contained Some value, consuming the self value.
Because this function may panic, its use is generally discouraged. Panics are meant for unrecoverable errors, and may abort the entire program.
Instead, prefer to use pattern matching and handle the None case explicitly, or call unwrap_or, unwrap_or_else, or unwrap_or_default. In functions returning Option, you can use the ? (try) operator.
Panics if the self value equals None.
let x = Some("air");
assert_eq!(x.unwrap(), "air");let x: Option<&str> = None;
assert_eq!(x.unwrap(), "air"); Returns the contained Some value or a provided default.
Arguments passed to unwrap_or are eagerly evaluated; if you are passing the result of a function call, it is recommended to use unwrap_or_else, which is lazily evaluated.
assert_eq!(Some("car").unwrap_or("bike"), "car");
assert_eq!(None.unwrap_or("bike"), "bike");Returns the contained Some value or computes it from a closure.
let k = 10;
assert_eq!(Some(4).unwrap_or_else(|| 2 * k), 4);
assert_eq!(None.unwrap_or_else(|| 2 * k), 20);Returns the contained Some value or a default.
Consumes the self argument then, if Some, returns the contained value, otherwise if None, returns the default value for that type.
let x: Option<u32> = None;
let y: Option<u32> = Some(12);
assert_eq!(x.unwrap_or_default(), 0);
assert_eq!(y.unwrap_or_default(), 12);Returns the contained Some value, consuming the self value, without checking that the value is not None.
Calling this method on None is undefined behavior.
let x = Some("air");
assert_eq!(unsafe { x.unwrap_unchecked() }, "air");let x: Option<&str> = None;
assert_eq!(unsafe { x.unwrap_unchecked() }, "air"); Maps an Option<T> to Option<U> by applying a function to a contained value (if Some) or returns None (if None).
Calculates the length of an Option<String> as an Option<usize>, consuming the original:
let maybe_some_string = Some(String::from("Hello, World!"));
let maybe_some_len = maybe_some_string.map(|s| s.len());
assert_eq!(maybe_some_len, Some(13));
let x: Option<&str> = None;
assert_eq!(x.map(|s| s.len()), None);Calls a function with a reference to the contained value if Some.
Returns the original option.
§Exampleslet list = vec![1, 2, 3];
let x = list
.get(1)
.inspect(|x| println!("got: {x}"))
.expect("list should be long enough");
list.get(5).inspect(|x| println!("got: {x}"));Returns the provided default result (if none), or applies a function to the contained value (if any).
Arguments passed to map_or are eagerly evaluated; if you are passing the result of a function call, it is recommended to use map_or_else, which is lazily evaluated.
let x = Some("foo");
assert_eq!(x.map_or(42, |v| v.len()), 3);
let x: Option<&str> = None;
assert_eq!(x.map_or(42, |v| v.len()), 42);Computes a default function result (if none), or applies a different function to the contained value (if any).
§Basic exampleslet k = 21;
let x = Some("foo");
assert_eq!(x.map_or_else(|| 2 * k, |v| v.len()), 3);
let x: Option<&str> = None;
assert_eq!(x.map_or_else(|| 2 * k, |v| v.len()), 42);A somewhat common occurrence when dealing with optional values in combination with Result<T, E> is the case where one wants to invoke a fallible fallback if the option is not present. This example parses a command line argument (if present), or the contents of a file to an integer. However, unlike accessing the command line argument, reading the file is fallible, so it must be wrapped with Ok.
let v: u64 = std::env::args()
.nth(1)
.map_or_else(|| std::fs::read_to_string("/etc/someconfig.conf"), Ok)?
.parse()?;result_option_map_or_default #138099)
Maps an Option<T> to a U by applying function f to the contained value if the option is Some, otherwise if None, returns the default value for the type U.
#![feature(result_option_map_or_default)]
let x: Option<&str> = Some("hi");
let y: Option<&str> = None;
assert_eq!(x.map_or_default(|x| x.len()), 2);
assert_eq!(y.map_or_default(|y| y.len()), 0);Transforms the Option<T> into a Result<T, E>, mapping Some(v) to Ok(v) and None to Err(err).
Arguments passed to ok_or are eagerly evaluated; if you are passing the result of a function call, it is recommended to use ok_or_else, which is lazily evaluated.
let x = Some("foo");
assert_eq!(x.ok_or(0), Ok("foo"));
let x: Option<&str> = None;
assert_eq!(x.ok_or(0), Err(0));Transforms the Option<T> into a Result<T, E>, mapping Some(v) to Ok(v) and None to Err(err()).
let x = Some("foo");
assert_eq!(x.ok_or_else(|| 0), Ok("foo"));
let x: Option<&str> = None;
assert_eq!(x.ok_or_else(|| 0), Err(0));Converts from Option<T> (or &Option<T>) to Option<&T::Target>.
Leaves the original Option in-place, creating a new one with a reference to the original one, additionally coercing the contents via Deref.
let x: Option<String> = Some("hey".to_owned());
assert_eq!(x.as_deref(), Some("hey"));
let x: Option<String> = None;
assert_eq!(x.as_deref(), None);Converts from Option<T> (or &mut Option<T>) to Option<&mut T::Target>.
Leaves the original Option in-place, creating a new one containing a mutable reference to the inner typeâs Deref::Target type.
let mut x: Option<String> = Some("hey".to_owned());
assert_eq!(x.as_deref_mut().map(|x| {
x.make_ascii_uppercase();
x
}), Some("HEY".to_owned().as_mut_str()));Returns an iterator over the possibly contained value.
§Exampleslet x = Some(4);
assert_eq!(x.iter().next(), Some(&4));
let x: Option<u32> = None;
assert_eq!(x.iter().next(), None);Returns a mutable iterator over the possibly contained value.
§Exampleslet mut x = Some(4);
match x.iter_mut().next() {
Some(v) => *v = 42,
None => {},
}
assert_eq!(x, Some(42));
let mut x: Option<u32> = None;
assert_eq!(x.iter_mut().next(), None);Returns None if the option is None, otherwise returns optb.
Arguments passed to and are eagerly evaluated; if you are passing the result of a function call, it is recommended to use and_then, which is lazily evaluated.
let x = Some(2);
let y: Option<&str> = None;
assert_eq!(x.and(y), None);
let x: Option<u32> = None;
let y = Some("foo");
assert_eq!(x.and(y), None);
let x = Some(2);
let y = Some("foo");
assert_eq!(x.and(y), Some("foo"));
let x: Option<u32> = None;
let y: Option<&str> = None;
assert_eq!(x.and(y), None);Returns None if the option is None, otherwise calls f with the wrapped value and returns the result.
Some languages call this operation flatmap.
§Examplesfn sq_then_to_string(x: u32) -> Option<String> {
x.checked_mul(x).map(|sq| sq.to_string())
}
assert_eq!(Some(2).and_then(sq_then_to_string), Some(4.to_string()));
assert_eq!(Some(1_000_000).and_then(sq_then_to_string), None); assert_eq!(None.and_then(sq_then_to_string), None);Often used to chain fallible operations that may return None.
let arr_2d = [["A0", "A1"], ["B0", "B1"]];
let item_0_1 = arr_2d.get(0).and_then(|row| row.get(1));
assert_eq!(item_0_1, Some(&"A1"));
let item_2_0 = arr_2d.get(2).and_then(|row| row.get(0));
assert_eq!(item_2_0, None);Returns None if the option is None, otherwise calls predicate with the wrapped value and returns:
Some(t) if predicate returns true (where t is the wrapped value), andNone if predicate returns false.This function works similar to Iterator::filter(). You can imagine the Option<T> being an iterator over one or zero elements. filter() lets you decide which elements to keep.
fn is_even(n: &i32) -> bool {
n % 2 == 0
}
assert_eq!(None.filter(is_even), None);
assert_eq!(Some(3).filter(is_even), None);
assert_eq!(Some(4).filter(is_even), Some(4));Returns the option if it contains a value, otherwise returns optb.
Arguments passed to or are eagerly evaluated; if you are passing the result of a function call, it is recommended to use or_else, which is lazily evaluated.
let x = Some(2);
let y = None;
assert_eq!(x.or(y), Some(2));
let x = None;
let y = Some(100);
assert_eq!(x.or(y), Some(100));
let x = Some(2);
let y = Some(100);
assert_eq!(x.or(y), Some(2));
let x: Option<u32> = None;
let y = None;
assert_eq!(x.or(y), None);Returns the option if it contains a value, otherwise calls f and returns the result.
fn nobody() -> Option<&'static str> { None }
fn vikings() -> Option<&'static str> { Some("vikings") }
assert_eq!(Some("barbarians").or_else(vikings), Some("barbarians"));
assert_eq!(None.or_else(vikings), Some("vikings"));
assert_eq!(None.or_else(nobody), None);Returns Some if exactly one of self, optb is Some, otherwise returns None.
let x = Some(2);
let y: Option<u32> = None;
assert_eq!(x.xor(y), Some(2));
let x: Option<u32> = None;
let y = Some(2);
assert_eq!(x.xor(y), Some(2));
let x = Some(2);
let y = Some(2);
assert_eq!(x.xor(y), None);
let x: Option<u32> = None;
let y: Option<u32> = None;
assert_eq!(x.xor(y), None);Inserts value into the option, then returns a mutable reference to it.
If the option already contains a value, the old value is dropped.
See also Option::get_or_insert, which doesnât update the value if the option already contains Some.
let mut opt = None;
let val = opt.insert(1);
assert_eq!(*val, 1);
assert_eq!(opt.unwrap(), 1);
let val = opt.insert(2);
assert_eq!(*val, 2);
*val = 3;
assert_eq!(opt.unwrap(), 3);Inserts value into the option if it is None, then returns a mutable reference to the contained value.
See also Option::insert, which updates the value even if the option already contains Some.
let mut x = None;
{
let y: &mut u32 = x.get_or_insert(5);
assert_eq!(y, &5);
*y = 7;
}
assert_eq!(x, Some(7));Inserts the default value into the option if it is None, then returns a mutable reference to the contained value.
let mut x = None;
{
let y: &mut u32 = x.get_or_insert_default();
assert_eq!(y, &0);
*y = 7;
}
assert_eq!(x, Some(7));Inserts a value computed from f into the option if it is None, then returns a mutable reference to the contained value.
let mut x = None;
{
let y: &mut u32 = x.get_or_insert_with(|| 5);
assert_eq!(y, &5);
*y = 7;
}
assert_eq!(x, Some(7));Takes the value out of the option, leaving a None in its place.
let mut x = Some(2);
let y = x.take();
assert_eq!(x, None);
assert_eq!(y, Some(2));
let mut x: Option<u32> = None;
let y = x.take();
assert_eq!(x, None);
assert_eq!(y, None);Takes the value out of the option, but only if the predicate evaluates to true on a mutable reference to the value.
In other words, replaces self with None if the predicate returns true. This method operates similar to Option::take but conditional.
let mut x = Some(42);
let prev = x.take_if(|v| if *v == 42 {
*v += 1;
false
} else {
false
});
assert_eq!(x, Some(43));
assert_eq!(prev, None);
let prev = x.take_if(|v| *v == 43);
assert_eq!(x, None);
assert_eq!(prev, Some(43));Replaces the actual value in the option by the value given in parameter, returning the old value if present, leaving a Some in its place without deinitializing either one.
let mut x = Some(2);
let old = x.replace(5);
assert_eq!(x, Some(5));
assert_eq!(old, Some(2));
let mut x = None;
let old = x.replace(3);
assert_eq!(x, Some(3));
assert_eq!(old, None);Zips self with another Option.
If self is Some(s) and other is Some(o), this method returns Some((s, o)). Otherwise, None is returned.
let x = Some(1);
let y = Some("hi");
let z = None::<u8>;
assert_eq!(x.zip(y), Some((1, "hi")));
assert_eq!(x.zip(z), None);option_zip #70086)
Zips self and another Option with function f.
If self is Some(s) and other is Some(o), this method returns Some(f(s, o)). Otherwise, None is returned.
#![feature(option_zip)]
#[derive(Debug, PartialEq)]
struct Point {
x: f64,
y: f64,
}
impl Point {
fn new(x: f64, y: f64) -> Self {
Self { x, y }
}
}
let x = Some(17.5);
let y = Some(42.7);
assert_eq!(x.zip_with(y, Point::new), Some(Point { x: 17.5, y: 42.7 }));
assert_eq!(x.zip_with(None, Point::new), None);Unzips an option containing a tuple of two options.
If self is Some((a, b)) this method returns (Some(a), Some(b)). Otherwise, (None, None) is returned.
let x = Some((1, "hi"));
let y = None::<(u8, u32)>;
assert_eq!(x.unzip(), (Some(1), Some("hi")));
assert_eq!(y.unzip(), (None, None));Maps an Option<&T> to an Option<T> by copying the contents of the option.
let x = 12;
let opt_x = Some(&x);
assert_eq!(opt_x, Some(&12));
let copied = opt_x.copied();
assert_eq!(copied, Some(12));Maps an Option<&T> to an Option<T> by cloning the contents of the option.
let x = 12;
let opt_x = Some(&x);
assert_eq!(opt_x, Some(&12));
let cloned = opt_x.cloned();
assert_eq!(cloned, Some(12));Maps an Option<&mut T> to an Option<T> by copying the contents of the option.
let mut x = 12;
let opt_x = Some(&mut x);
assert_eq!(opt_x, Some(&mut 12));
let copied = opt_x.copied();
assert_eq!(copied, Some(12));Maps an Option<&mut T> to an Option<T> by cloning the contents of the option.
let mut x = 12;
let opt_x = Some(&mut x);
assert_eq!(opt_x, Some(&mut 12));
let cloned = opt_x.cloned();
assert_eq!(cloned, Some(12));Transposes an Option of a Result into a Result of an Option.
None will be mapped to Ok(None). Some(Ok(_)) and Some(Err(_)) will be mapped to Ok(Some(_)) and Err(_).
#[derive(Debug, Eq, PartialEq)]
struct SomeErr;
let x: Result<Option<i32>, SomeErr> = Ok(Some(5));
let y: Option<Result<i32, SomeErr>> = Some(Ok(5));
assert_eq!(x, y.transpose());Converts from Option<Option<T>> to Option<T>.
Basic usage:
let x: Option<Option<u32>> = Some(Some(6));
assert_eq!(Some(6), x.flatten());
let x: Option<Option<u32>> = Some(None);
assert_eq!(None, x.flatten());
let x: Option<Option<u32>> = None;
assert_eq!(None, x.flatten());Flattening only removes one level of nesting at a time:
let x: Option<Option<Option<u32>>> = Some(Some(Some(6)));
assert_eq!(Some(Some(6)), x.flatten());
assert_eq!(Some(6), x.flatten().flatten());Returns None.
let opt: Option<u32> = Option::default();
assert!(opt.is_none());Converts from &Option<T> to Option<&T>.
Converts an Option<String> into an Option<usize>, preserving the original. The map method takes the self argument by value, consuming the original, so this technique uses from to first take an Option to a reference to the value inside the original.
let s: Option<String> = Some(String::from("Hello, Rustaceans!"));
let o: Option<usize> = Option::from(&s).map(|ss: &String| ss.len());
println!("Can still print s: {s:?}");
assert_eq!(o, Some(18));Converts from &mut Option<T> to Option<&mut T>
let mut s = Some(String::from("Hello"));
let o: Option<&mut String> = Option::from(&mut s);
match o {
Some(t) => *t = String::from("Hello, Rustaceans!"),
None => (),
}
assert_eq!(s, Some(String::from("Hello, Rustaceans!")));Moves val into a new Some.
let o: Option<u8> = Option::from(67);
assert_eq!(Some(67), o);Takes each element in the Iterator: if it is None, no further elements are taken, and the None is returned. Should no None occur, a container of type V containing the values of each Option is returned.
Here is an example which increments every integer in a vector. We use the checked variant of add that returns None when the calculation would result in an overflow.
let items = vec![0_u16, 1, 2];
let res: Option<Vec<u16>> = items
.iter()
.map(|x| x.checked_add(1))
.collect();
assert_eq!(res, Some(vec![1, 2, 3]));As you can see, this will return the expected, valid items.
Here is another example that tries to subtract one from another list of integers, this time checking for underflow:
let items = vec![2_u16, 1, 0];
let res: Option<Vec<u16>> = items
.iter()
.map(|x| x.checked_sub(1))
.collect();
assert_eq!(res, None);Since the last element is zero, it would underflow. Thus, the resulting value is None.
Here is a variation on the previous example, showing that no further elements are taken from iter after the first None.
let items = vec![3_u16, 2, 1, 10];
let mut shared = 0;
let res: Option<Vec<u16>> = items
.iter()
.map(|x| { shared += x; x.checked_sub(2) })
.collect();
assert_eq!(res, None);
assert_eq!(shared, 6);Since the third element caused an underflow, no further elements were taken, so the final value of shared is 6 (= 3 + 2 + 1), not 16.
try_trait_v2 #84277)
Constructs the type from a compatible
Residual
type.
Read more Source§ Source§ ð¬This is a nightly-only experimental API. (try_trait_v2 #84277)
Constructs the type from a compatible
Residual
type.
Read more 1.0.0 · Source§ 1.4.0 · Source§ Source§The type of the elements being iterated over.
Source§Which kind of iterator are we turning this into?
Source§ 1.4.0 · Source§ Source§The type of the elements being iterated over.
Source§Which kind of iterator are we turning this into?
Source§ 1.0.0 · Source§ Source§Returns a consuming iterator over the possibly contained value.
§Exampleslet x = Some("string");
let v: Vec<&str> = x.into_iter().collect();
assert_eq!(v, ["string"]);
let x = None;
let v: Vec<&str> = x.into_iter().collect();
assert!(v.is_empty());The type of the elements being iterated over.
Source§Which kind of iterator are we turning this into?
1.0.0 · Source§ 1.0.0 (const: unstable) · Source§ Source§Tests for self and other values to be equal, and is used by ==.
Tests for !=. The default implementation is almost always sufficient, and should not be overridden without very good reason.
This method returns an ordering between
self
and
other
values if one exists.
Read more 1.0.0 · Source§Tests less than (for
self
and
other
) and is used by the
<
operator.
Read more 1.0.0 · Source§Tests less than or equal to (for
self
and
other
) and is used by the
<=
operator.
Read more 1.0.0 · Source§Tests greater than (for
self
and
other
) and is used by the
>
operator.
Read more 1.0.0 · Source§Tests greater than or equal to (for
self
and
other
) and is used by the
>=
operator.
Read more 1.37.0 · Source§ Source§Takes each element in the Iterator: if it is a None, no further elements are taken, and the None is returned. Should no None occur, the product of all elements is returned.
This multiplies each number in a vector of strings, if a string could not be parsed the operation returns None:
let nums = vec!["5", "10", "1", "2"];
let total: Option<usize> = nums.iter().map(|w| w.parse::<usize>().ok()).product();
assert_eq!(total, Some(100));
let nums = vec!["5", "10", "one", "2"];
let total: Option<usize> = nums.iter().map(|w| w.parse::<usize>().ok()).product();
assert_eq!(total, None);try_trait_v2_residual #91285)
The âreturnâ type of this meta-function.
1.37.0 · Source§ Source§Takes each element in the Iterator: if it is a None, no further elements are taken, and the None is returned. Should no None occur, the sum of all elements is returned.
This sums up the position of the character âaâ in a vector of strings, if a word did not have the character âaâ the operation returns None:
let words = vec!["have", "a", "great", "day"];
let total: Option<usize> = words.iter().map(|w| w.find('a')).sum();
assert_eq!(total, Some(5));
let words = vec!["have", "a", "good", "day"];
let total: Option<usize> = words.iter().map(|w| w.find('a')).sum();
assert_eq!(total, None);try_trait_v2 #84277)
The type of the value produced by ? when not short-circuiting.
try_trait_v2 #84277) Source§ ð¬This is a nightly-only experimental API. (try_trait_v2 #84277)
Constructs the type from its
Output
type.
Read more Source§ ð¬This is a nightly-only experimental API. (try_trait_v2 #84277) 1.0.0 · Source§ 1.0.0 · Source§ 1.0.0 · Source§ Source§
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