// Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! Optionally nullable values (`Option` type) //! //! Type `Option` represents an optional value. //! //! Every `Option` value can either be `Some(T)` or `None`. Where in other //! languages you might use a nullable type, in Rust you would use an option //! type. //! //! Options are most commonly used with pattern matching to query the presence //! of a value and take action, always accounting for the `None` case. //! //! # Example //! //! ``` //! let msg = Some(~"howdy"); //! //! // Take a reference to the contained string //! match msg { //! Some(ref m) => println!("{}", *m), //! None => () //! } //! //! // Remove the contained string, destroying the Option //! let unwrapped_msg = match msg { //! Some(m) => m, //! None => ~"default message" //! }; //! ``` use any::Any; use clone::Clone; use cmp::{Eq, TotalEq, TotalOrd}; use default::Default; use iter::{Iterator, DoubleEndedIterator, FromIterator, ExactSize}; use kinds::Send; use mem; use vec; /// The option type #[deriving(Clone, Eq, Ord, TotalEq, TotalOrd, Show)] pub enum Option { /// No value None, /// Some value `T` Some(T) } ///////////////////////////////////////////////////////////////////////////// // Type implementation ///////////////////////////////////////////////////////////////////////////// impl Option { ///////////////////////////////////////////////////////////////////////// // Querying the contained values ///////////////////////////////////////////////////////////////////////// /// Returns true if the option contains a `Some` value #[inline] pub fn is_some(&self) -> bool { match *self { Some(_) => true, None => false } } /// Returns true if the option equals `None` #[inline] pub fn is_none(&self) -> bool { !self.is_some() } ///////////////////////////////////////////////////////////////////////// // Adapter for working with references ///////////////////////////////////////////////////////////////////////// /// Convert from `Option` to `Option<&T>` #[inline] pub fn as_ref<'r>(&'r self) -> Option<&'r T> { match *self { Some(ref x) => Some(x), None => None } } /// Convert from `Option` to `Option<&mut T>` #[inline] pub fn as_mut<'r>(&'r mut self) -> Option<&'r mut T> { match *self { Some(ref mut x) => Some(x), None => None } } /// Convert from `Option` to `&[T]` (without copying) #[inline] pub fn as_slice<'r>(&'r self) -> &'r [T] { match *self { Some(ref x) => vec::ref_slice(x), None => &[] } } /// Convert from `Option` to `&mut [T]` (without copying) #[inline] pub fn as_mut_slice<'r>(&'r mut self) -> &'r mut [T] { match *self { Some(ref mut x) => vec::mut_ref_slice(x), None => &mut [] } } ///////////////////////////////////////////////////////////////////////// // Getting to contained values ///////////////////////////////////////////////////////////////////////// /// Unwraps an option, yielding the content of a `Some` /// Fails if the value is a `None` with a custom failure message provided by `msg`. #[inline] pub fn expect(self, msg: M) -> T { match self { Some(val) => val, None => fail!(msg), } } /// Moves a value out of an option type and returns it. /// /// Useful primarily for getting strings, vectors and unique pointers out /// of option types without copying them. /// /// # Failure /// /// Fails if the value equals `None`. /// /// # Safety note /// /// In general, because this function may fail, its use is discouraged. /// Instead, prefer to use pattern matching and handle the `None` /// case explicitly. #[inline] pub fn unwrap(self) -> T { match self { Some(val) => val, None => fail!("called `Option::unwrap()` on a `None` value"), } } /// Returns the contained value or a default #[inline] pub fn unwrap_or(self, def: T) -> T { match self { Some(x) => x, None => def } } /// Returns the contained value or computes it from a closure #[inline] pub fn unwrap_or_else(self, f: || -> T) -> T { match self { Some(x) => x, None => f() } } ///////////////////////////////////////////////////////////////////////// // Transforming contained values ///////////////////////////////////////////////////////////////////////// /// Maps an `Option` to `Option` by applying a function to a contained value. #[inline] pub fn map(self, f: |T| -> U) -> Option { match self { Some(x) => Some(f(x)), None => None } } /// Applies a function to the contained value or returns a default. #[inline] pub fn map_or(self, def: U, f: |T| -> U) -> U { match self { None => def, Some(t) => f(t) } } /// Apply a function to the contained value or do nothing. /// Returns true if the contained value was mutated. pub fn mutate(&mut self, f: |T| -> T) -> bool { if self.is_some() { *self = Some(f(self.take_unwrap())); true } else { false } } /// Apply a function to the contained value or set it to a default. /// Returns true if the contained value was mutated, or false if set to the default. pub fn mutate_or_set(&mut self, def: T, f: |T| -> T) -> bool { if self.is_some() { *self = Some(f(self.take_unwrap())); true } else { *self = Some(def); false } } ///////////////////////////////////////////////////////////////////////// // Iterator constructors ///////////////////////////////////////////////////////////////////////// /// Return an iterator over the possibly contained value #[inline] pub fn iter<'r>(&'r self) -> Item<&'r T> { Item{opt: self.as_ref()} } /// Return a mutable iterator over the possibly contained value #[inline] pub fn mut_iter<'r>(&'r mut self) -> Item<&'r mut T> { Item{opt: self.as_mut()} } /// Return a consuming iterator over the possibly contained value #[inline] pub fn move_iter(self) -> Item { Item{opt: self} } ///////////////////////////////////////////////////////////////////////// // Boolean operations on the values, eager and lazy ///////////////////////////////////////////////////////////////////////// /// Returns `None` if the option is `None`, otherwise returns `optb`. #[inline] pub fn and(self, optb: Option) -> Option { match self { Some(_) => optb, None => None, } } /// Returns `None` if the option is `None`, otherwise calls `f` with the /// wrapped value and returns the result. #[inline] pub fn and_then(self, f: |T| -> Option) -> Option { match self { Some(x) => f(x), None => None, } } /// Returns the option if it contains a value, otherwise returns `optb`. #[inline] pub fn or(self, optb: Option) -> Option { match self { Some(_) => self, None => optb } } /// Returns the option if it contains a value, otherwise calls `f` and /// returns the result. #[inline] pub fn or_else(self, f: || -> Option) -> Option { match self { Some(_) => self, None => f(), } } ///////////////////////////////////////////////////////////////////////// // Misc ///////////////////////////////////////////////////////////////////////// /// Take the value out of the option, leaving a `None` in its place. #[inline] pub fn take(&mut self) -> Option { mem::replace(self, None) } /// Filters an optional value using a given function. #[inline(always)] pub fn filtered(self, f: |t: &T| -> bool) -> Option { match self { Some(x) => if f(&x) {Some(x)} else {None}, None => None } } /// Applies a function zero or more times until the result is `None`. #[inline] pub fn while_some(self, f: |v: T| -> Option) { let mut opt = self; loop { match opt { Some(x) => opt = f(x), None => break } } } ///////////////////////////////////////////////////////////////////////// // Common special cases ///////////////////////////////////////////////////////////////////////// /// The option dance. Moves a value out of an option type and returns it, /// replacing the original with `None`. /// /// # Failure /// /// Fails if the value equals `None`. #[inline] pub fn take_unwrap(&mut self) -> T { match self.take() { Some(x) => x, None => fail!("called `Option::take_unwrap()` on a `None` value") } } /// Gets an immutable reference to the value inside an option. /// /// # Failure /// /// Fails if the value equals `None` /// /// # Safety note /// /// In general, because this function may fail, its use is discouraged /// (calling `get` on `None` is akin to dereferencing a null pointer). /// Instead, prefer to use pattern matching and handle the `None` /// case explicitly. #[inline] pub fn get_ref<'a>(&'a self) -> &'a T { match *self { Some(ref x) => x, None => fail!("called `Option::get_ref()` on a `None` value"), } } /// Gets a mutable reference to the value inside an option. /// /// # Failure /// /// Fails if the value equals `None` /// /// # Safety note /// /// In general, because this function may fail, its use is discouraged /// (calling `get` on `None` is akin to dereferencing a null pointer). /// Instead, prefer to use pattern matching and handle the `None` /// case explicitly. #[inline] pub fn get_mut_ref<'a>(&'a mut self) -> &'a mut T { match *self { Some(ref mut x) => x, None => fail!("called `Option::get_mut_ref()` on a `None` value"), } } } impl Option { /// Returns the contained value or default (for this type) #[inline] pub fn unwrap_or_default(self) -> T { match self { Some(x) => x, None => Default::default() } } } ///////////////////////////////////////////////////////////////////////////// // Trait implementations ///////////////////////////////////////////////////////////////////////////// impl Default for Option { #[inline] fn default() -> Option { None } } ///////////////////////////////////////////////////////////////////////////// // The Option Iterator ///////////////////////////////////////////////////////////////////////////// /// An iterator that yields either one or zero elements #[deriving(Clone)] pub struct Item { priv opt: Option } impl Iterator for Item { #[inline] fn next(&mut self) -> Option { self.opt.take() } #[inline] fn size_hint(&self) -> (uint, Option) { match self.opt { Some(_) => (1, Some(1)), None => (0, Some(0)), } } } impl DoubleEndedIterator for Item { #[inline] fn next_back(&mut self) -> Option { self.opt.take() } } impl ExactSize for Item {} ///////////////////////////////////////////////////////////////////////////// // Free functions ///////////////////////////////////////////////////////////////////////////// /// 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 /// vector containing the values of each `Option` is returned. /// /// Here is an example which increments every integer in a vector, /// checking for overflow: /// /// fn inc_conditionally(x: uint) -> Option { /// if x == uint::MAX { return None; } /// else { return Some(x+1u); } /// } /// let v = [1u, 2, 3]; /// let res = collect(v.iter().map(|&x| inc_conditionally(x))); /// assert!(res == Some(~[2u, 3, 4])); #[inline] pub fn collect>, V: FromIterator>(iter: Iter) -> Option { // FIXME(#11084): This should be twice as fast once this bug is closed. let mut iter = iter.scan(false, |state, x| { match x { Some(x) => Some(x), None => { *state = true; None } } }); let v: V = FromIterator::from_iterator(&mut iter); if iter.state { None } else { Some(v) } } ///////////////////////////////////////////////////////////////////////////// // Tests ///////////////////////////////////////////////////////////////////////////// #[cfg(test)] mod tests { use super::*; use prelude::*; use iter::range; use str::StrSlice; use kinds::marker; use vec::ImmutableVector; #[test] fn test_get_ptr() { unsafe { let x = ~0; let addr_x: *int = ::cast::transmute(&*x); let opt = Some(x); let y = opt.unwrap(); let addr_y: *int = ::cast::transmute(&*y); assert_eq!(addr_x, addr_y); } } #[test] fn test_get_str() { let x = ~"test"; let addr_x = x.as_ptr(); let opt = Some(x); let y = opt.unwrap(); let addr_y = y.as_ptr(); assert_eq!(addr_x, addr_y); } #[test] fn test_get_resource() { use rc::Rc; use cell::RefCell; struct R { i: Rc>, } #[unsafe_destructor] impl ::ops::Drop for R { fn drop(&mut self) { let ii = self.i.deref(); ii.set(ii.get() + 1); } } fn R(i: Rc>) -> R { R { i: i } } let i = Rc::new(RefCell::new(0)); { let x = R(i.clone()); let opt = Some(x); let _y = opt.unwrap(); } assert_eq!(i.deref().get(), 1); } #[test] fn test_option_dance() { let x = Some(()); let mut y = Some(5); let mut y2 = 0; for _x in x.iter() { y2 = y.take_unwrap(); } assert_eq!(y2, 5); assert!(y.is_none()); } #[test] #[should_fail] fn test_option_too_much_dance() { let mut y = Some(marker::NoPod); let _y2 = y.take_unwrap(); let _y3 = y.take_unwrap(); } #[test] fn test_and() { let x: Option = Some(1); assert_eq!(x.and(Some(2)), Some(2)); assert_eq!(x.and(None::), None); let x: Option = None; assert_eq!(x.and(Some(2)), None); assert_eq!(x.and(None::), None); } #[test] fn test_and_then() { let x: Option = Some(1); assert_eq!(x.and_then(|x| Some(x + 1)), Some(2)); assert_eq!(x.and_then(|_| None::), None); let x: Option = None; assert_eq!(x.and_then(|x| Some(x + 1)), None); assert_eq!(x.and_then(|_| None::), None); } #[test] fn test_or() { let x: Option = Some(1); assert_eq!(x.or(Some(2)), Some(1)); assert_eq!(x.or(None), Some(1)); let x: Option = None; assert_eq!(x.or(Some(2)), Some(2)); assert_eq!(x.or(None), None); } #[test] fn test_or_else() { let x: Option = Some(1); assert_eq!(x.or_else(|| Some(2)), Some(1)); assert_eq!(x.or_else(|| None), Some(1)); let x: Option = None; assert_eq!(x.or_else(|| Some(2)), Some(2)); assert_eq!(x.or_else(|| None), None); } #[test] fn test_option_while_some() { let mut i = 0; Some(10).while_some(|j| { i += 1; if j > 0 { Some(j-1) } else { None } }); assert_eq!(i, 11); } #[test] fn test_unwrap() { assert_eq!(Some(1).unwrap(), 1); assert_eq!(Some(~"hello").unwrap(), ~"hello"); } #[test] #[should_fail] fn test_unwrap_fail1() { let x: Option = None; x.unwrap(); } #[test] #[should_fail] fn test_unwrap_fail2() { let x: Option<~str> = None; x.unwrap(); } #[test] fn test_unwrap_or() { let x: Option = Some(1); assert_eq!(x.unwrap_or(2), 1); let x: Option = None; assert_eq!(x.unwrap_or(2), 2); } #[test] fn test_unwrap_or_else() { let x: Option = Some(1); assert_eq!(x.unwrap_or_else(|| 2), 1); let x: Option = None; assert_eq!(x.unwrap_or_else(|| 2), 2); } #[test] fn test_filtered() { let some_stuff = Some(42); let modified_stuff = some_stuff.filtered(|&x| {x < 10}); assert_eq!(some_stuff.unwrap(), 42); assert!(modified_stuff.is_none()); } #[test] fn test_iter() { let val = 5; let x = Some(val); let mut it = x.iter(); assert_eq!(it.size_hint(), (1, Some(1))); assert_eq!(it.next(), Some(&val)); assert_eq!(it.size_hint(), (0, Some(0))); assert!(it.next().is_none()); } #[test] fn test_mut_iter() { let val = 5; let new_val = 11; let mut x = Some(val); { let mut it = x.mut_iter(); assert_eq!(it.size_hint(), (1, Some(1))); match it.next() { Some(interior) => { assert_eq!(*interior, val); *interior = new_val; } None => assert!(false), } assert_eq!(it.size_hint(), (0, Some(0))); assert!(it.next().is_none()); } assert_eq!(x, Some(new_val)); } #[test] fn test_ord() { let small = Some(1.0); let big = Some(5.0); let nan = Some(0.0/0.0); assert!(!(nan < big)); assert!(!(nan > big)); assert!(small < big); assert!(None < big); assert!(big > None); } #[test] fn test_mutate() { let mut x = Some(3i); assert!(x.mutate(|i| i+1)); assert_eq!(x, Some(4i)); assert!(x.mutate_or_set(0, |i| i+1)); assert_eq!(x, Some(5i)); x = None; assert!(!x.mutate(|i| i+1)); assert_eq!(x, None); assert!(!x.mutate_or_set(0i, |i| i+1)); assert_eq!(x, Some(0i)); } #[test] fn test_collect() { let v: Option<~[int]> = collect(range(0, 0) .map(|_| Some(0))); assert_eq!(v, Some(~[])); let v: Option<~[int]> = collect(range(0, 3) .map(|x| Some(x))); assert_eq!(v, Some(~[0, 1, 2])); let v: Option<~[int]> = collect(range(0, 3) .map(|x| if x > 1 { None } else { Some(x) })); assert_eq!(v, None); // test that it does not take more elements than it needs let functions = [|| Some(()), || None, || fail!()]; let v: Option<~[()]> = collect(functions.iter().map(|f| (*f)())); assert_eq!(v, None); } }