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//! The enum [`Either`] with variants `Left` and `Right` is a general purpose //! sum type with two cases. //! //! [`Either`]: enum.Either.html //! //! **Crate features:** //! //! * `"use_std"` //! Enabled by default. Disable to make the library `#![no_std]`. //! //! * `"serde"` //! Disabled by default. Enable to `#[derive(Serialize, Deserialize)]` for `Either` //! #![doc(html_root_url = "https://docs.rs/either/1/")] #![cfg_attr(all(not(test), not(feature = "use_std")), no_std)] #[cfg(all(not(test), not(feature = "use_std")))] extern crate core as std; #[cfg(feature = "serde")] #[macro_use] extern crate serde; use std::convert::{AsRef, AsMut}; use std::fmt; use std::iter; use std::ops::Deref; use std::ops::DerefMut; #[cfg(any(test, feature = "use_std"))] use std::io::{self, Write, Read, BufRead}; #[cfg(any(test, feature = "use_std"))] use std::error::Error; pub use Either::{Left, Right}; /// The enum `Either` with variants `Left` and `Right` is a general purpose /// sum type with two cases. /// /// The `Either` type is symmetric and treats its variants the same way, without /// preference. /// (For representing success or error, use the regular `Result` enum instead.) #[cfg_attr(feature = "serde", derive(Serialize, Deserialize))] #[derive(Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash, Debug)] pub enum Either<L, R> { /// A value of type `L`. Left(L), /// A value of type `R`. Right(R), } macro_rules! either { ($value:expr, $pattern:pat => $result:expr) => ( match $value { Either::Left($pattern) => $result, Either::Right($pattern) => $result, } ) } /// Macro for unwrapping the left side of an `Either`, which fails early /// with the opposite side. Can only be used in functions that return /// `Either` because of the early return of `Right` that it provides. /// /// See also `try_right!` for its dual, which applies the same just to the /// right side. /// /// # Example /// /// ``` /// #[macro_use] extern crate either; /// use either::{Either, Left, Right}; /// /// fn twice(wrapper: Either<u32, &str>) -> Either<u32, &str> { /// let value = try_left!(wrapper); /// Left(value * 2) /// } /// /// fn main() { /// assert_eq!(twice(Left(2)), Left(4)); /// assert_eq!(twice(Right("ups")), Right("ups")); /// } /// ``` #[macro_export] macro_rules! try_left { ($expr:expr) => ( match $expr { $crate::Left(val) => val, $crate::Right(err) => return $crate::Right(::std::convert::From::from(err)) } ) } /// Dual to `try_left!`, see its documentation for more information. #[macro_export] macro_rules! try_right { ($expr:expr) => ( match $expr { $crate::Left(err) => return $crate::Left(::std::convert::From::from(err)), $crate::Right(val) => val } ) } impl<L, R> Either<L, R> { /// Return true if the value is the `Left` variant. /// /// ``` /// use either::*; /// /// let values = [Left(1), Right("the right value")]; /// assert_eq!(values[0].is_left(), true); /// assert_eq!(values[1].is_left(), false); /// ``` pub fn is_left(&self) -> bool { match *self { Left(_) => true, Right(_) => false, } } /// Return true if the value is the `Right` variant. /// /// ``` /// use either::*; /// /// let values = [Left(1), Right("the right value")]; /// assert_eq!(values[0].is_right(), false); /// assert_eq!(values[1].is_right(), true); /// ``` pub fn is_right(&self) -> bool { !self.is_left() } /// Convert the left side of `Either<L, R>` to an `Option<L>`. /// /// ``` /// use either::*; /// /// let left: Either<_, ()> = Left("some value"); /// assert_eq!(left.left(), Some("some value")); /// /// let right: Either<(), _> = Right(321); /// assert_eq!(right.left(), None); /// ``` pub fn left(self) -> Option<L> { match self { Left(l) => Some(l), Right(_) => None, } } /// Convert the right side of `Either<L, R>` to an `Option<R>`. /// /// ``` /// use either::*; /// /// let left: Either<_, ()> = Left("some value"); /// assert_eq!(left.right(), None); /// /// let right: Either<(), _> = Right(321); /// assert_eq!(right.right(), Some(321)); /// ``` pub fn right(self) -> Option<R> { match self { Left(_) => None, Right(r) => Some(r), } } /// Convert `&Either<L, R>` to `Either<&L, &R>`. /// /// ``` /// use either::*; /// /// let left: Either<_, ()> = Left("some value"); /// assert_eq!(left.as_ref(), Left(&"some value")); /// /// let right: Either<(), _> = Right("some value"); /// assert_eq!(right.as_ref(), Right(&"some value")); /// ``` pub fn as_ref(&self) -> Either<&L, &R> { match *self { Left(ref inner) => Left(inner), Right(ref inner) => Right(inner), } } /// Convert `&mut Either<L, R>` to `Either<&mut L, &mut R>`. /// /// ``` /// use either::*; /// /// fn mutate_left(value: &mut Either<u32, u32>) { /// if let Some(l) = value.as_mut().left() { /// *l = 999; /// } /// } /// /// let mut left = Left(123); /// let mut right = Right(123); /// mutate_left(&mut left); /// mutate_left(&mut right); /// assert_eq!(left, Left(999)); /// assert_eq!(right, Right(123)); /// ``` pub fn as_mut(&mut self) -> Either<&mut L, &mut R> { match *self { Left(ref mut inner) => Left(inner), Right(ref mut inner) => Right(inner), } } /// Convert `Either<L, R>` to `Either<R, L>`. /// /// ``` /// use either::*; /// /// let left: Either<_, ()> = Left(123); /// assert_eq!(left.flip(), Right(123)); /// /// let right: Either<(), _> = Right("some value"); /// assert_eq!(right.flip(), Left("some value")); /// ``` pub fn flip(self) -> Either<R, L> { match self { Left(l) => Right(l), Right(r) => Left(r), } } /// Apply the function `f` on the value in the `Left` variant if it is present rewrapping the /// result in `Left`. /// /// ``` /// use either::*; /// /// let left: Either<_, u32> = Left(123); /// assert_eq!(left.map_left(|x| x * 2), Left(246)); /// /// let right: Either<u32, _> = Right(123); /// assert_eq!(right.map_left(|x| x * 2), Right(123)); /// ``` pub fn map_left<F, M>(self, f: F) -> Either<M, R> where F: FnOnce(L) -> M { match self { Left(l) => Left(f(l)), Right(r) => Right(r), } } /// Apply the function `f` on the value in the `Right` variant if it is present rewrapping the /// result in `Right`. /// /// ``` /// use either::*; /// /// let left: Either<_, u32> = Left(123); /// assert_eq!(left.map_right(|x| x * 2), Left(123)); /// /// let right: Either<u32, _> = Right(123); /// assert_eq!(right.map_right(|x| x * 2), Right(246)); /// ``` pub fn map_right<F, S>(self, f: F) -> Either<L, S> where F: FnOnce(R) -> S { match self { Left(l) => Left(l), Right(r) => Right(f(r)), } } /// Apply one of two functions depending on contents, unifying their result. If the value is /// `Left(L)` then the first function `f` is applied; if it is `Right(R)` then the second /// function `g` is applied. /// /// ``` /// use either::*; /// /// fn square(n: u32) -> i32 { (n * n) as i32 } /// fn negate(n: i32) -> i32 { -n } /// /// let left: Either<u32, i32> = Left(4); /// assert_eq!(left.either(square, negate), 16); /// /// let right: Either<u32, i32> = Right(-4); /// assert_eq!(right.either(square, negate), 4); /// ``` pub fn either<F, G, T>(self, f: F, g: G) -> T where F: FnOnce(L) -> T, G: FnOnce(R) -> T { match self { Left(l) => f(l), Right(r) => g(r), } } /// Like `either`, but provide some context to whichever of the /// functions ends up being called. /// /// ``` /// // In this example, the context is a mutable reference /// use either::*; /// /// let mut result = Vec::new(); /// /// let values = vec![Left(2), Right(2.7)]; /// /// for value in values { /// value.either_with(&mut result, /// |ctx, integer| ctx.push(integer), /// |ctx, real| ctx.push(f64::round(real) as i32)); /// } /// /// assert_eq!(result, vec![2, 3]); /// ``` pub fn either_with<Ctx, F, G, T>(self, ctx: Ctx, f: F, g: G) -> T where F: FnOnce(Ctx, L) -> T, G: FnOnce(Ctx, R) -> T { match self { Left(l) => f(ctx, l), Right(r) => g(ctx, r), } } /// Apply the function `f` on the value in the `Left` variant if it is present. /// /// ``` /// use either::*; /// /// let left: Either<_, u32> = Left(123); /// assert_eq!(left.left_and_then::<_,()>(|x| Right(x * 2)), Right(246)); /// /// let right: Either<u32, _> = Right(123); /// assert_eq!(right.left_and_then(|x| Right::<(), _>(x * 2)), Right(123)); /// ``` pub fn left_and_then<F, S>(self, f: F) -> Either<S, R> where F: FnOnce(L) -> Either<S, R> { match self { Left(l) => f(l), Right(r) => Right(r), } } /// Apply the function `f` on the value in the `Right` variant if it is present. /// /// ``` /// use either::*; /// /// let left: Either<_, u32> = Left(123); /// assert_eq!(left.right_and_then(|x| Right(x * 2)), Left(123)); /// /// let right: Either<u32, _> = Right(123); /// assert_eq!(right.right_and_then(|x| Right(x * 2)), Right(246)); /// ``` pub fn right_and_then<F, S>(self, f: F) -> Either<L, S> where F: FnOnce(R) -> Either<L, S> { match self { Left(l) => Left(l), Right(r) => f(r), } } /// Convert the inner value to an iterator. /// /// ``` /// use either::*; /// /// let left: Either<_, Vec<u32>> = Left(vec![1, 2, 3, 4, 5]); /// let mut right: Either<Vec<u32>, _> = Right(vec![]); /// right.extend(left.into_iter()); /// assert_eq!(right, Right(vec![1, 2, 3, 4, 5])); /// ``` pub fn into_iter(self) -> Either<L::IntoIter, R::IntoIter> where L: IntoIterator, R: IntoIterator<Item = L::Item> { match self { Left(l) => Left(l.into_iter()), Right(r) => Right(r.into_iter()), } } } impl<T, L, R> Either<(T, L), (T, R)> { /// Factor out a homogeneous type from an either of pairs. /// /// Here, the homogeneous type is the first element of the pairs. /// /// ``` /// use either::*; /// let left: Either<_, (u32, String)> = Left((123, vec![0])); /// assert_eq!(left.factor_first().0, 123); /// /// let right: Either<(u32, Vec<u8>), _> = Right((123, String::new())); /// assert_eq!(right.factor_first().0, 123); /// ``` pub fn factor_first(self) -> (T, Either<L, R>) { match self { Left((t, l)) => (t, Left(l)), Right((t, r)) => (t, Right(r)), } } } impl<T, L, R> Either<(L, T), (R, T)> { /// Factor out a homogeneous type from an either of pairs. /// /// Here, the homogeneous type is the second element of the pairs. /// /// ``` /// use either::*; /// let left: Either<_, (String, u32)> = Left((vec![0], 123)); /// assert_eq!(left.factor_second().1, 123); /// /// let right: Either<(Vec<u8>, u32), _> = Right((String::new(), 123)); /// assert_eq!(right.factor_second().1, 123); /// ``` pub fn factor_second(self) -> (Either<L, R>, T) { match self { Left((l, t)) => (Left(l), t), Right((r, t)) => (Right(r), t), } } } impl<T> Either<T, T> { /// Extract the value of an either over two equivalent types. /// /// ``` /// use either::*; /// /// let left: Either<_, u32> = Left(123); /// assert_eq!(left.into_inner(), 123); /// /// let right: Either<u32, _> = Right(123); /// assert_eq!(right.into_inner(), 123); /// ``` pub fn into_inner(self) -> T { either!(self, inner => inner) } } /// Convert from `Result` to `Either` with `Ok => Right` and `Err => Left`. impl<L, R> From<Result<R, L>> for Either<L, R> { fn from(r: Result<R, L>) -> Self { match r { Err(e) => Left(e), Ok(o) => Right(o), } } } /// Convert from `Either` to `Result` with `Right => Ok` and `Left => Err`. impl<L, R> Into<Result<R, L>> for Either<L, R> { fn into(self) -> Result<R, L> { match self { Left(l) => Err(l), Right(r) => Ok(r), } } } impl<L, R, A> Extend<A> for Either<L, R> where L: Extend<A>, R: Extend<A> { fn extend<T>(&mut self, iter: T) where T: IntoIterator<Item=A> { either!(*self, ref mut inner => inner.extend(iter)) } } /// `Either<L, R>` is an iterator if both `L` and `R` are iterators. impl<L, R> Iterator for Either<L, R> where L: Iterator, R: Iterator<Item=L::Item> { type Item = L::Item; fn next(&mut self) -> Option<Self::Item> { either!(*self, ref mut inner => inner.next()) } fn size_hint(&self) -> (usize, Option<usize>) { either!(*self, ref inner => inner.size_hint()) } fn fold<Acc, G>(self, init: Acc, f: G) -> Acc where G: FnMut(Acc, Self::Item) -> Acc, { either!(self, inner => inner.fold(init, f)) } fn count(self) -> usize { either!(self, inner => inner.count()) } fn last(self) -> Option<Self::Item> { either!(self, inner => inner.last()) } fn nth(&mut self, n: usize) -> Option<Self::Item> { either!(*self, ref mut inner => inner.nth(n)) } fn collect<B>(self) -> B where B: iter::FromIterator<Self::Item> { either!(self, inner => inner.collect()) } fn all<F>(&mut self, f: F) -> bool where F: FnMut(Self::Item) -> bool { either!(*self, ref mut inner => inner.all(f)) } } impl<L, R> DoubleEndedIterator for Either<L, R> where L: DoubleEndedIterator, R: DoubleEndedIterator<Item=L::Item> { fn next_back(&mut self) -> Option<Self::Item> { either!(*self, ref mut inner => inner.next_back()) } } impl<L, R> ExactSizeIterator for Either<L, R> where L: ExactSizeIterator, R: ExactSizeIterator<Item=L::Item> { } #[cfg(any(test, feature = "use_std"))] /// `Either<L, R>` implements `Read` if both `L` and `R` do. /// /// Requires crate feature `"use_std"` impl<L, R> Read for Either<L, R> where L: Read, R: Read { fn read(&mut self, buf: &mut [u8]) -> io::Result<usize> { either!(*self, ref mut inner => inner.read(buf)) } fn read_to_end(&mut self, buf: &mut Vec<u8>) -> io::Result<usize> { either!(*self, ref mut inner => inner.read_to_end(buf)) } } #[cfg(any(test, feature = "use_std"))] /// Requires crate feature `"use_std"` impl<L, R> BufRead for Either<L, R> where L: BufRead, R: BufRead { fn fill_buf(&mut self) -> io::Result<&[u8]> { either!(*self, ref mut inner => inner.fill_buf()) } fn consume(&mut self, amt: usize) { either!(*self, ref mut inner => inner.consume(amt)) } } #[cfg(any(test, feature = "use_std"))] /// `Either<L, R>` implements `Write` if both `L` and `R` do. /// /// Requires crate feature `"use_std"` impl<L, R> Write for Either<L, R> where L: Write, R: Write { fn write(&mut self, buf: &[u8]) -> io::Result<usize> { either!(*self, ref mut inner => inner.write(buf)) } fn flush(&mut self) -> io::Result<()> { either!(*self, ref mut inner => inner.flush()) } } impl<L, R, Target> AsRef<Target> for Either<L, R> where L: AsRef<Target>, R: AsRef<Target> { fn as_ref(&self) -> &Target { either!(*self, ref inner => inner.as_ref()) } } macro_rules! impl_specific_ref_and_mut { ($t:ty, $($attr:meta),* ) => { $(#[$attr])* impl<L, R> AsRef<$t> for Either<L, R> where L: AsRef<$t>, R: AsRef<$t> { fn as_ref(&self) -> &$t { either!(*self, ref inner => inner.as_ref()) } } $(#[$attr])* impl<L, R> AsMut<$t> for Either<L, R> where L: AsMut<$t>, R: AsMut<$t> { fn as_mut(&mut self) -> &mut $t { either!(*self, ref mut inner => inner.as_mut()) } } }; } impl_specific_ref_and_mut!(str,); impl_specific_ref_and_mut!( ::std::path::Path, cfg(feature = "use_std"), doc = "Requires crate feature `use_std`." ); impl_specific_ref_and_mut!( ::std::ffi::OsStr, cfg(feature = "use_std"), doc = "Requires crate feature `use_std`." ); impl_specific_ref_and_mut!( ::std::ffi::CStr, cfg(feature = "use_std"), doc = "Requires crate feature `use_std`." ); impl<L, R, Target> AsRef<[Target]> for Either<L, R> where L: AsRef<[Target]>, R: AsRef<[Target]> { fn as_ref(&self) -> &[Target] { either!(*self, ref inner => inner.as_ref()) } } impl<L, R, Target> AsMut<Target> for Either<L, R> where L: AsMut<Target>, R: AsMut<Target> { fn as_mut(&mut self) -> &mut Target { either!(*self, ref mut inner => inner.as_mut()) } } impl<L, R, Target> AsMut<[Target]> for Either<L, R> where L: AsMut<[Target]>, R: AsMut<[Target]> { fn as_mut(&mut self) -> &mut [Target] { either!(*self, ref mut inner => inner.as_mut()) } } impl<L, R> Deref for Either<L, R> where L: Deref, R: Deref<Target=L::Target> { type Target = L::Target; fn deref(&self) -> &Self::Target { either!(*self, ref inner => &*inner) } } impl<L, R> DerefMut for Either<L, R> where L: DerefMut, R: DerefMut<Target=L::Target> { fn deref_mut(&mut self) -> &mut Self::Target { either!(*self, ref mut inner => &mut *inner) } } #[cfg(any(test, feature = "use_std"))] /// `Either` implements `Error` if *both* `L` and `R` implement it. impl<L, R> Error for Either<L, R> where L: Error, R: Error { fn description(&self) -> &str { either!(*self, ref inner => inner.description()) } fn cause(&self) -> Option<&Error> { either!(*self, ref inner => inner.cause()) } } impl<L, R> fmt::Display for Either<L, R> where L: fmt::Display, R: fmt::Display { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { either!(*self, ref inner => inner.fmt(f)) } } #[test] fn basic() { let mut e = Left(2); let r = Right(2); assert_eq!(e, Left(2)); e = r; assert_eq!(e, Right(2)); assert_eq!(e.left(), None); assert_eq!(e.right(), Some(2)); assert_eq!(e.as_ref().right(), Some(&2)); assert_eq!(e.as_mut().right(), Some(&mut 2)); } #[test] fn macros() { fn a() -> Either<u32, u32> { let x: u32 = try_left!(Right(1337u32)); Left(x * 2) } assert_eq!(a(), Right(1337)); fn b() -> Either<String, &'static str> { Right(try_right!(Left("foo bar"))) } assert_eq!(b(), Left(String::from("foo bar"))); } #[test] fn deref() { fn is_str(_: &str) {} let value: Either<String, &str> = Left(String::from("test")); is_str(&*value); } #[test] fn iter() { let x = 3; let mut iter = match x { 1...3 => Left(0..10), _ => Right(17..), }; assert_eq!(iter.next(), Some(0)); assert_eq!(iter.count(), 9); } #[test] fn read_write() { use std::io; let use_stdio = false; let mockdata = [0xff; 256]; let mut reader = if use_stdio { Left(io::stdin()) } else { Right(&mockdata[..]) }; let mut buf = [0u8; 16]; assert_eq!(reader.read(&mut buf).unwrap(), buf.len()); assert_eq!(&buf, &mockdata[..buf.len()]); let mut mockbuf = [0u8; 256]; let mut writer = if use_stdio { Left(io::stdout()) } else { Right(&mut mockbuf[..]) }; let buf = [1u8; 16]; assert_eq!(writer.write(&buf).unwrap(), buf.len()); } #[test] fn error() { let invalid_utf8 = b"\xff"; let res = || -> Result<_, Either<_, _>> { try!(::std::str::from_utf8(invalid_utf8).map_err(Left)); try!("x".parse::<i32>().map_err(Right)); Ok(()) }(); assert!(res.is_err()); res.unwrap_err().description(); // make sure this can be called } /// A helper macro to check if AsRef and AsMut are implemented for a given type. macro_rules! check_t { ($t:ty) => {{ fn check_ref<T: AsRef<$t>>() {} fn propagate_ref<T1: AsRef<$t>, T2: AsRef<$t>>() { check_ref::<Either<T1, T2>>() } fn check_mut<T: AsMut<$t>>() {} fn propagate_mut<T1: AsMut<$t>, T2: AsMut<$t>>() { check_mut::<Either<T1, T2>>() } }}; } // This "unused" method is here to ensure that compilation doesn't fail on given types. fn _unsized_ref_propagation() { check_t!(str); fn check_array_ref<T: AsRef<[Item]>, Item>() {} fn check_array_mut<T: AsMut<[Item]>, Item>() {} fn propagate_array_ref<T1: AsRef<[Item]>, T2: AsRef<[Item]>, Item>() { check_array_ref::<Either<T1, T2>, _>() } fn propagate_array_mut<T1: AsMut<[Item]>, T2: AsMut<[Item]>, Item>() { check_array_mut::<Either<T1, T2>, _>() } } // This "unused" method is here to ensure that compilation doesn't fail on given types. #[cfg(feature = "use_std")] fn _unsized_std_propagation() { check_t!(::std::path::Path); check_t!(::std::ffi::OsStr); check_t!(::std::ffi::CStr); }