Module sexually_transmitted_disease::option1.0.0[][src]

Expand description

Optional values.

Type Option represents an optional value: every Option is either Some and contains a value, or None, and does not. Option types are very common in Rust code, as they have a number of uses:

  • Initial values
  • Return values for functions that are not defined over their entire input range (partial functions)
  • Return value for otherwise reporting simple errors, where None is returned on error
  • Optional struct fields
  • Struct fields that can be loaned or “taken”
  • Optional function arguments
  • Nullable pointers
  • Swapping things out of difficult situations

Options are commonly paired with pattern matching to query the presence of a value and take action, always accounting for the None case.

fn divide(numerator: f64, denominator: f64) -> Option<f64> {
    if denominator == 0.0 {
        None
    } else {
        Some(numerator / denominator)
    }
}

// The return value of the function is an option
let result = divide(2.0, 3.0);

// Pattern match to retrieve the value
match result {
    // The division was valid
    Some(x) => println!("Result: {}", x),
    // The division was invalid
    None    => println!("Cannot divide by 0"),
}

Options and pointers (“nullable” pointers)

Rust’s pointer types must always point to a valid location; there are no “null” references. Instead, Rust has optional pointers, like the optional owned box, Option<Box<T>>.

The following example uses Option to create an optional box of i32. Notice that in order to use the inner i32 value first, the check_optional function needs to use pattern matching to determine whether the box has a value (i.e., it is Some(...)) or not (None).

let optional = None;
check_optional(optional);

let optional = Some(Box::new(9000));
check_optional(optional);

fn check_optional(optional: Option<Box<i32>>) {
    match optional {
        Some(p) => println!("has value {}", p),
        None => println!("has no value"),
    }
}

Representation

Rust guarantees to optimize the following types T such that Option<T> has the same size as T:

This is called the “null pointer optimization” or NPO.

It is further guaranteed that, for the cases above, one can mem::transmute from all valid values of T to Option<T> and from Some::<T>(_) to T (but transmuting None::<T> to T is undefined behaviour).

Examples

Basic pattern matching on Option:

let msg = Some("howdy");

// Take a reference to the contained string
if let Some(m) = &msg {
    println!("{}", *m);
}

// Remove the contained string, destroying the Option
let unwrapped_msg = msg.unwrap_or("default message");

Initialize a result to None before a loop:

enum Kingdom { Plant(u32, &'static str), Animal(u32, &'static str) }

// A list of data to search through.
let all_the_big_things = [
    Kingdom::Plant(250, "redwood"),
    Kingdom::Plant(230, "noble fir"),
    Kingdom::Plant(229, "sugar pine"),
    Kingdom::Animal(25, "blue whale"),
    Kingdom::Animal(19, "fin whale"),
    Kingdom::Animal(15, "north pacific right whale"),
];

// We're going to search for the name of the biggest animal,
// but to start with we've just got `None`.
let mut name_of_biggest_animal = None;
let mut size_of_biggest_animal = 0;
for big_thing in &all_the_big_things {
    match *big_thing {
        Kingdom::Animal(size, name) if size > size_of_biggest_animal => {
            // Now we've found the name of some big animal
            size_of_biggest_animal = size;
            name_of_biggest_animal = Some(name);
        }
        Kingdom::Animal(..) | Kingdom::Plant(..) => ()
    }
}

match name_of_biggest_animal {
    Some(name) => println!("the biggest animal is {}", name),
    None => println!("there are no animals :("),
}

Structs

IntoIter

An iterator over the value in Some variant of an Option.

Iter

An iterator over a reference to the Some variant of an Option.

IterMut

An iterator over a mutable reference to the Some variant of an Option.

Enums

Option

The Option type. See the module level documentation for more.