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//! Asynchronous iteration.
//!
//! This module is an async version of [`std::iter`].
//!
//! [`std::iter`]: https://doc.rust-lang.org/std/iter/index.html
//!
//! # Examples
//!
//! ```
//! # async_std::task::block_on(async {
//! #
//! use async_std::prelude::*;
//! use async_std::stream;
//!
//! let mut s = stream::repeat(9).take(3);
//!
//! while let Some(v) = s.next().await {
//!     assert_eq!(v, 9);
//! }
//! #
//! # })
//! ```

mod all;
mod any;
mod chain;
mod cloned;
mod cmp;
mod copied;
mod cycle;
mod enumerate;
mod eq;
mod filter;
mod filter_map;
mod find;
mod find_map;
mod fold;
mod for_each;
mod fuse;
mod ge;
mod gt;
mod inspect;
mod last;
mod le;
mod lt;
mod map;
mod max_by;
mod max_by_key;
mod min;
mod min_by;
mod min_by_key;
mod ne;
mod next;
mod nth;
mod partial_cmp;
mod position;
mod scan;
mod skip;
mod skip_while;
mod step_by;
mod take;
mod take_while;
mod try_fold;
mod try_for_each;
mod zip;

use all::AllFuture;
use any::AnyFuture;
use cmp::CmpFuture;
use cycle::Cycle;
use enumerate::Enumerate;
use eq::EqFuture;
use filter_map::FilterMap;
use find::FindFuture;
use find_map::FindMapFuture;
use fold::FoldFuture;
use for_each::ForEachFuture;
use ge::GeFuture;
use gt::GtFuture;
use last::LastFuture;
use le::LeFuture;
use lt::LtFuture;
use max_by::MaxByFuture;
use max_by_key::MaxByKeyFuture;
use min::MinFuture;
use min_by::MinByFuture;
use min_by_key::MinByKeyFuture;
use ne::NeFuture;
use next::NextFuture;
use nth::NthFuture;
use partial_cmp::PartialCmpFuture;
use position::PositionFuture;
use try_fold::TryFoldFuture;
use try_for_each::TryForEachFuture;

pub use chain::Chain;
pub use cloned::Cloned;
pub use copied::Copied;
pub use filter::Filter;
pub use fuse::Fuse;
pub use inspect::Inspect;
pub use map::Map;
pub use scan::Scan;
pub use skip::Skip;
pub use skip_while::SkipWhile;
pub use step_by::StepBy;
pub use take::Take;
pub use take_while::TakeWhile;
pub use zip::Zip;

use std::cmp::Ordering;
use std::marker::PhantomData;

cfg_unstable! {
    use std::pin::Pin;
    use std::time::Duration;

    use crate::future::Future;
    use crate::stream::into_stream::IntoStream;
    use crate::stream::{FromStream, Product, Sum};

    pub use merge::Merge;
    pub use flatten::Flatten;
    pub use flat_map::FlatMap;
    pub use timeout::{TimeoutError, Timeout};

    mod merge;
    mod flatten;
    mod flat_map;
    mod timeout;
}

extension_trait! {
    use std::ops::{Deref, DerefMut};

    use crate::task::{Context, Poll};

    #[doc = r#"
        An asynchronous stream of values.

        This trait is a re-export of [`futures::stream::Stream`] and is an async version of
        [`std::iter::Iterator`].

        The [provided methods] do not really exist in the trait itself, but they become
        available when [`StreamExt`] from the [prelude] is imported:

        ```
        # #[allow(unused_imports)]
        use async_std::prelude::*;
        ```

        [`std::iter::Iterator`]: https://doc.rust-lang.org/std/iter/trait.Iterator.html
        [`futures::stream::Stream`]:
        https://docs.rs/futures-preview/0.3.0-alpha.17/futures/stream/trait.Stream.html
        [provided methods]: #provided-methods
        [`StreamExt`]: ../prelude/trait.StreamExt.html
        [prelude]: ../prelude/index.html
    "#]
    pub trait Stream {
        #[doc = r#"
            The type of items yielded by this stream.
        "#]
        type Item;

        #[doc = r#"
            Attempts to receive the next item from the stream.

            There are several possible return values:

            * `Poll::Pending` means this stream's next value is not ready yet.
            * `Poll::Ready(None)` means this stream has been exhausted.
            * `Poll::Ready(Some(item))` means `item` was received out of the stream.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use std::pin::Pin;

            use async_std::prelude::*;
            use async_std::stream;
            use async_std::task::{Context, Poll};

            fn increment(
                s: impl Stream<Item = i32> + Unpin,
            ) -> impl Stream<Item = i32> + Unpin {
                struct Increment<S>(S);

                impl<S: Stream<Item = i32> + Unpin> Stream for Increment<S> {
                    type Item = S::Item;

                    fn poll_next(
                        mut self: Pin<&mut Self>,
                        cx: &mut Context<'_>,
                    ) -> Poll<Option<Self::Item>> {
                        match Pin::new(&mut self.0).poll_next(cx) {
                            Poll::Pending => Poll::Pending,
                            Poll::Ready(None) => Poll::Ready(None),
                            Poll::Ready(Some(item)) => Poll::Ready(Some(item + 1)),
                        }
                    }
                }

                Increment(s)
            }

            let mut s = increment(stream::once(7));

            assert_eq!(s.next().await, Some(8));
            assert_eq!(s.next().await, None);
            #
            # }) }
            ```
        "#]
        fn poll_next(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>>;
    }

    #[doc = r#"
        Extension methods for [`Stream`].

        [`Stream`]: ../stream/trait.Stream.html
    "#]
    pub trait StreamExt: futures_core::stream::Stream {
        #[doc = r#"
            Advances the stream and returns the next value.

            Returns [`None`] when iteration is finished. Individual stream implementations may
            choose to resume iteration, and so calling `next()` again may or may not eventually
            start returning more values.

            [`None`]: https://doc.rust-lang.org/std/option/enum.Option.html#variant.None

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::once(7);

            assert_eq!(s.next().await, Some(7));
            assert_eq!(s.next().await, None);
            #
            # }) }
            ```
        "#]
        fn next(&mut self) -> impl Future<Output = Option<Self::Item>> + '_ [NextFuture<'_, Self>]
        where
            Self: Unpin,
        {
            NextFuture { stream: self }
        }

        #[doc = r#"
            Creates a stream that yields its first `n` elements.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::repeat(9).take(3);

            while let Some(v) = s.next().await {
                assert_eq!(v, 9);
            }
            #
            # }) }
            ```
        "#]
        fn take(self, n: usize) -> Take<Self>
        where
            Self: Sized,
        {
            Take {
                stream: self,
                remaining: n,
            }
        }

        #[doc = r#"
            Creates a stream that yields elements based on a predicate.

            # Examples
            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1, 2, 3, 4]);
            let mut s = s.take_while(|x| x < &3 );

            assert_eq!(s.next().await, Some(1));
            assert_eq!(s.next().await, Some(2));
            assert_eq!(s.next().await, None);

            #
            # }) }
        "#]
        fn take_while<P>(self, predicate: P) -> TakeWhile<Self, P, Self::Item>
        where
            Self: Sized,
            P: FnMut(&Self::Item) -> bool,
        {
            TakeWhile::new(self, predicate)
        }

        #[doc = r#"
            Creates a stream that yields each `step`th element.

            # Panics

            This method will panic if the given step is `0`.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![0u8, 1, 2, 3, 4]);
            let mut stepped = s.step_by(2);

            assert_eq!(stepped.next().await, Some(0));
            assert_eq!(stepped.next().await, Some(2));
            assert_eq!(stepped.next().await, Some(4));
            assert_eq!(stepped.next().await, None);

            #
            # }) }
            ```
        "#]
        fn step_by(self, step: usize) -> StepBy<Self>
        where
            Self: Sized,
        {
            StepBy::new(self, step)
        }

        #[doc = r#"
            Takes two streams and creates a new stream over both in sequence.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let first = stream::from_iter(vec![0u8, 1]);
            let second = stream::from_iter(vec![2, 3]);
            let mut c = first.chain(second);

            assert_eq!(c.next().await, Some(0));
            assert_eq!(c.next().await, Some(1));
            assert_eq!(c.next().await, Some(2));
            assert_eq!(c.next().await, Some(3));
            assert_eq!(c.next().await, None);

            #
            # }) }
            ```
        "#]
        fn chain<U>(self, other: U) -> Chain<Self, U>
        where
            Self: Sized,
            U: Stream<Item = Self::Item> + Sized,
        {
            Chain::new(self, other)
        }

            #[doc = r#"
            Creates an stream which copies all of its elements.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let v = stream::from_iter(vec![&1, &2, &3]);
                
            let mut v_cloned = v.cloned();
            
            assert_eq!(v_cloned.next().await, Some(1));
            assert_eq!(v_cloned.next().await, Some(2));
            assert_eq!(v_cloned.next().await, Some(3));
            assert_eq!(v_cloned.next().await, None);

            #
            # }) }
            ```
        "#]
        fn cloned<'a,T>(self) -> Cloned<Self>
        where
            Self: Sized + Stream<Item = &'a T>,
            T : 'a + Clone,
        {
            Cloned::new(self)
        }


        #[doc = r#"
            Creates an stream which copies all of its elements.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![&1, &2, &3]);
            let mut s_copied  = s.copied();

            assert_eq!(s_copied.next().await, Some(1));
            assert_eq!(s_copied.next().await, Some(2));
            assert_eq!(s_copied.next().await, Some(3));
            assert_eq!(s_copied.next().await, None);
            #
            # }) }
            ```
        "#]
        fn copied<'a,T>(self) -> Copied<Self>
        where
            Self: Sized + Stream<Item = &'a T>,
            T : 'a + Copy,
        {
            Copied::new(self)
        }

        #[doc = r#"
            Creates a stream that yields the provided values infinitely and in order.

            # Examples

            Basic usage:

            ```
            # async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::once(7).cycle();

            assert_eq!(s.next().await, Some(7));
            assert_eq!(s.next().await, Some(7));
            assert_eq!(s.next().await, Some(7));
            assert_eq!(s.next().await, Some(7));
            assert_eq!(s.next().await, Some(7));
            #
            # })
            ```
        "#]
        fn cycle(self) -> Cycle<Self, Self::Item>
            where
                Self: Sized,
                Self::Item: Clone,
        {
            Cycle::new(self)
        }

        #[doc = r#"
            Creates a stream that gives the current element's count as well as the next value.

            # Overflow behaviour.

            This combinator does no guarding against overflows.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec!['a', 'b', 'c']);
            let mut s = s.enumerate();

            assert_eq!(s.next().await, Some((0, 'a')));
            assert_eq!(s.next().await, Some((1, 'b')));
            assert_eq!(s.next().await, Some((2, 'c')));
            assert_eq!(s.next().await, None);

            #
            # }) }
            ```
        "#]
        fn enumerate(self) -> Enumerate<Self>
        where
            Self: Sized,
        {
            Enumerate::new(self)
        }

        #[doc = r#"
            Takes a closure and creates a stream that calls that closure on every element of this stream.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1, 2, 3]);
            let mut s = s.map(|x| 2 * x);

            assert_eq!(s.next().await, Some(2));
            assert_eq!(s.next().await, Some(4));
            assert_eq!(s.next().await, Some(6));
            assert_eq!(s.next().await, None);

            #
            # }) }
            ```
        "#]
        fn map<B, F>(self, f: F) -> Map<Self, F, Self::Item, B>
        where
            Self: Sized,
            F: FnMut(Self::Item) -> B,
        {
            Map::new(self, f)
        }

        #[doc = r#"
            A combinator that does something with each element in the stream, passing the value
            on.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1, 2, 3, 4, 5]);

            let sum = s
                    .inspect(|x| println!("about to filter {}", x))
                    .filter(|x| x % 2 == 0)
                    .inspect(|x| println!("made it through filter: {}", x))
                    .fold(0, |sum, i| sum + i).await;

            assert_eq!(sum, 6);
            #
            # }) }
            ```
        "#]
        fn inspect<F>(self, f: F) -> Inspect<Self, F, Self::Item>
        where
            Self: Sized,
            F: FnMut(&Self::Item),
        {
            Inspect::new(self, f)
        }

        #[doc = r#"
            Returns the last element of the stream.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1, 2, 3]);

            let last  = s.last().await;
            assert_eq!(last, Some(3));
            #
            # }) }
            ```

            An empty stream will return `None:
            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::stream;
            use crate::async_std::prelude::*;

            let s = stream::empty::<()>();

            let last  = s.last().await;
            assert_eq!(last, None);
            #
            # }) }
            ```

        "#]
        fn last(
            self,
        ) -> impl Future<Output = Option<Self::Item>> [LastFuture<Self, Self::Item>]
        where
            Self: Sized,
        {
            LastFuture::new(self)
        }

        #[doc = r#"
            Creates a stream which ends after the first `None`.

            After a stream returns `None`, future calls may or may not yield `Some(T)` again.
            `fuse()` adapts an iterator, ensuring that after a `None` is given, it will always
            return `None` forever.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::once(1).fuse();
            assert_eq!(s.next().await, Some(1));
            assert_eq!(s.next().await, None);
            assert_eq!(s.next().await, None);
            #
            # }) }
            ```
        "#]
        fn fuse(self) -> Fuse<Self>
        where
            Self: Sized,
        {
            Fuse {
                stream: self,
                done: false,
            }
        }

        #[doc = r#"
            Creates a stream that uses a predicate to determine if an element should be yielded.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1, 2, 3, 4]);
            let mut s = s.filter(|i| i % 2 == 0);

            assert_eq!(s.next().await, Some(2));
            assert_eq!(s.next().await, Some(4));
            assert_eq!(s.next().await, None);
            #
            # }) }
            ```
        "#]
        fn filter<P>(self, predicate: P) -> Filter<Self, P, Self::Item>
        where
            Self: Sized,
            P: FnMut(&Self::Item) -> bool,
        {
            Filter::new(self, predicate)
        }

        #[doc= r#"
            Creates an stream that works like map, but flattens nested structure.

            # Examples

            Basic usage:

            ```
            # async_std::task::block_on(async {

            use async_std::prelude::*;
            use async_std::stream::IntoStream;
            use async_std::stream;

            let inner1 = stream::from_iter(vec![1,2,3]);
            let inner2 = stream::from_iter(vec![4,5,6]);

            let s = stream::from_iter(vec![inner1, inner2]);

            let v :Vec<_> = s.flat_map(|s| s.into_stream()).collect().await;

            assert_eq!(v, vec![1,2,3,4,5,6]);

            # });
            ```
        "#]
        #[cfg(feature = "unstable")]
        #[cfg_attr(feature = "docs", doc(cfg(unstable)))]
        fn flat_map<U, F>(self, f: F) -> FlatMap<Self, U, Self::Item, F>
            where
                Self: Sized,
                U: IntoStream,
                F: FnMut(Self::Item) -> U,
        {
            FlatMap::new(self, f)
        }

        #[doc = r#"
            Creates an stream that flattens nested structure.

            # Examples

            Basic usage:

            ```
            # async_std::task::block_on(async {

            use async_std::prelude::*;
            use async_std::stream;

            let inner1 = stream::from_iter(vec![1u8,2,3]);
            let inner2 = stream::from_iter(vec![4u8,5,6]);
            let s  = stream::from_iter(vec![inner1, inner2]);

            let v: Vec<_> = s.flatten().collect().await;

            assert_eq!(v, vec![1,2,3,4,5,6]);

            # });
        "#]
        #[cfg(feature = "unstable")]
        #[cfg_attr(feature = "docs", doc(cfg(unstable)))]
        fn flatten(self) -> Flatten<Self, Self::Item>
        where
            Self: Sized,
            Self::Item: IntoStream,
        {
            Flatten::new(self)
        }

        #[doc = r#"
            Both filters and maps a stream.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #

            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec!["1", "lol", "3", "NaN", "5"]);

            let mut parsed = s.filter_map(|a| a.parse::<u32>().ok());

            let one = parsed.next().await;
            assert_eq!(one, Some(1));

            let three = parsed.next().await;
            assert_eq!(three, Some(3));

            let five = parsed.next().await;
            assert_eq!(five, Some(5));

            let end = parsed.next().await;
            assert_eq!(end, None);
            #
            # }) }
            ```
        "#]
        fn filter_map<B, F>(self, f: F) -> FilterMap<Self, F, Self::Item, B>
        where
            Self: Sized,
            F: FnMut(Self::Item) -> Option<B>,
        {
            FilterMap::new(self, f)
        }

         #[doc = r#"
            Returns the element that gives the minimum value with respect to the
            specified key function. If several elements are equally minimum,
            the first element is returned. If the stream is empty, `None` is returned.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1isize, 2, -3]);

            let min = s.clone().min_by_key(|x| x.abs()).await;
            assert_eq!(min, Some(1));

            let min = stream::empty::<isize>().min_by_key(|x| x.abs()).await;
            assert_eq!(min, None);
            #
            # }) }
            ```
        "#]
        fn min_by_key<K>(
            self,
            key_by: K,
        ) -> impl Future<Output = Option<Self::Item>> [MinByKeyFuture<Self, Self::Item, K>]
        where
            Self: Sized,
            Self::Item: Ord,
            K: FnMut(&Self::Item) -> Self::Item,
        {
            MinByKeyFuture::new(self, key_by)
        }

         #[doc = r#"
            Returns the element that gives the maximum value with respect to the
            specified key function. If several elements are equally maximum,
            the first element is returned. If the stream is empty, `None` is returned.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![-1isize, -2, -3]);

            let max = s.clone().max_by_key(|x| x.abs()).await;
            assert_eq!(max, Some(3));

            let max = stream::empty::<isize>().min_by_key(|x| x.abs()).await;
            assert_eq!(max, None);
            #
            # }) }
            ```
        "#]
        fn max_by_key<K>(
            self,
            key_by: K,
        ) -> impl Future<Output = Option<Self::Item>> [MaxByKeyFuture<Self, Self::Item, K>]
        where
            Self: Sized,
            Self::Item: Ord,
            K: FnMut(&Self::Item) -> Self::Item,
        {
            MaxByKeyFuture::new(self, key_by)
        }

        #[doc = r#"
            Returns the element that gives the minimum value with respect to the
            specified comparison function. If several elements are equally minimum,
            the first element is returned. If the stream is empty, `None` is returned.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1u8, 2, 3]);

            let min = s.clone().min_by(|x, y| x.cmp(y)).await;
            assert_eq!(min, Some(1));

            let min = s.min_by(|x, y| y.cmp(x)).await;
            assert_eq!(min, Some(3));

            let min = stream::empty::<u8>().min_by(|x, y| x.cmp(y)).await;
            assert_eq!(min, None);
            #
            # }) }
            ```
        "#]
        fn min_by<F>(
            self,
            compare: F,
        ) -> impl Future<Output = Option<Self::Item>> [MinByFuture<Self, F, Self::Item>]
        where
            Self: Sized,
            F: FnMut(&Self::Item, &Self::Item) -> Ordering,
        {
            MinByFuture::new(self, compare)
        }

        #[doc = r#"
            Returns the element that gives the minimum value. If several elements are equally minimum,
            the first element is returned. If the stream is empty, `None` is returned.

            # Examples

            ```ignore
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1usize, 2, 3]);

            let min = s.clone().min().await;
            assert_eq!(min, Some(1));

            let min = stream::empty::<usize>().min().await;
            assert_eq!(min, None);
            #
            # }) }
            ```
        "#]
        fn min<F>(
            self,
        ) -> impl Future<Output = Option<Self::Item>> [MinFuture<Self, F, Self::Item>]
        where
            Self: Sized,
            F: FnMut(&Self::Item, &Self::Item) -> Ordering,
        {
            MinFuture::new(self)
        }

         #[doc = r#"
            Returns the element that gives the maximum value with respect to the
            specified comparison function. If several elements are equally maximum,
            the first element is returned. If the stream is empty, `None` is returned.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1u8, 2, 3]);

            let max = s.clone().max_by(|x, y| x.cmp(y)).await;
            assert_eq!(max, Some(3));

            let max = s.max_by(|x, y| y.cmp(x)).await;
            assert_eq!(max, Some(1));

            let max = stream::empty::<usize>().max_by(|x, y| x.cmp(y)).await;
            assert_eq!(max, None);
            #
            # }) }
            ```
        "#]
        fn max_by<F>(
            self,
            compare: F,
        ) -> impl Future<Output = Option<Self::Item>> [MaxByFuture<Self, F, Self::Item>]
        where
            Self: Sized,
            F: FnMut(&Self::Item, &Self::Item) -> Ordering,
        {
            MaxByFuture::new(self, compare)
        }

        #[doc = r#"
            Returns the nth element of the stream.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::from_iter(vec![1u8, 2, 3]);

            let second = s.nth(1).await;
            assert_eq!(second, Some(2));
            #
            # }) }
            ```
            Calling `nth()` multiple times:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::stream;
            use async_std::prelude::*;

            let mut s = stream::from_iter(vec![1u8, 2, 3]);

            let second = s.nth(0).await;
            assert_eq!(second, Some(1));

            let second = s.nth(0).await;
            assert_eq!(second, Some(2));
            #
            # }) }
            ```
            Returning `None` if the stream finished before returning `n` elements:
            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s  = stream::from_iter(vec![1u8, 2, 3]);

            let fourth = s.nth(4).await;
            assert_eq!(fourth, None);
            #
            # }) }
            ```
        "#]
        fn nth(
            &mut self,
            n: usize,
        ) -> impl Future<Output = Option<Self::Item>> + '_ [NthFuture<'_, Self>]
        where
            Self: Sized,
        {
            NthFuture::new(self, n)
        }

        #[doc = r#"
            Tests if every element of the stream matches a predicate.

            `all()` takes a closure that returns `true` or `false`. It applies
            this closure to each element of the stream, and if they all return
            `true`, then so does `all()`. If any of them return `false`, it
            returns `false`.

            `all()` is short-circuiting; in other words, it will stop processing
            as soon as it finds a `false`, given that no matter what else happens,
            the result will also be `false`.

            An empty stream returns `true`.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::repeat::<u32>(42).take(3);
            assert!(s.all(|x| x ==  42).await);

            #
            # }) }
            ```

            Empty stream:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::empty::<u32>();
            assert!(s.all(|_| false).await);
            #
            # }) }
            ```
        "#]
        #[inline]
        fn all<F>(
            &mut self,
            f: F,
        ) -> impl Future<Output = bool> + '_ [AllFuture<'_, Self, F, Self::Item>]
        where
            Self: Unpin + Sized,
            F: FnMut(Self::Item) -> bool,
        {
            AllFuture {
                stream: self,
                result: true, // the default if the empty stream
                _marker: PhantomData,
                f,
            }
        }

        #[doc = r#"
            Searches for an element in a stream that satisfies a predicate.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::from_iter(vec![1u8, 2, 3]);
            let res = s.find(|x| *x == 2).await;
            assert_eq!(res, Some(2));
            #
            # }) }
            ```

            Resuming after a first find:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s= stream::from_iter(vec![1, 2, 3]);
            let res = s.find(|x| *x == 2).await;
            assert_eq!(res, Some(2));

            let next = s.next().await;
            assert_eq!(next, Some(3));
            #
            # }) }
            ```
        "#]
        fn find<P>(
            &mut self,
            p: P,
        ) -> impl Future<Output = Option<Self::Item>> + '_ [FindFuture<'_, Self, P, Self::Item>]
        where
            Self: Sized,
            P: FnMut(&Self::Item) -> bool,
        {
            FindFuture::new(self, p)
        }

        #[doc = r#"
            Applies function to the elements of stream and returns the first non-none result.

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::from_iter(vec!["lol", "NaN", "2", "5"]);
            let first_number = s.find_map(|s| s.parse().ok()).await;

            assert_eq!(first_number, Some(2));
            #
            # }) }
            ```
        "#]
        fn find_map<F, B>(
            &mut self,
            f: F,
        ) -> impl Future<Output = Option<B>> + '_ [FindMapFuture<'_, Self, F, Self::Item, B>]
        where
            Self: Sized,
            F: FnMut(Self::Item) -> Option<B>,
        {
            FindMapFuture::new(self, f)
        }

        #[doc = r#"
            A combinator that applies a function to every element in a stream
            producing a single, final value.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1u8, 2, 3]);
            let sum = s.fold(0, |acc, x| acc + x).await;

            assert_eq!(sum, 6);
            #
            # }) }
            ```
        "#]
        fn fold<B, F>(
            self,
            init: B,
            f: F,
        ) -> impl Future<Output = B> [FoldFuture<Self, F, Self::Item, B>]
        where
            Self: Sized,
            F: FnMut(B, Self::Item) -> B,
        {
            FoldFuture::new(self, init, f)
        }

        #[doc = r#"
            Call a closure on each element of the stream.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;
            use std::sync::mpsc::channel;

            let (tx, rx) = channel();

            let s = stream::from_iter(vec![1usize, 2, 3]);
            let sum = s.for_each(move |x| tx.clone().send(x).unwrap()).await;

            let v: Vec<_> = rx.iter().collect();

            assert_eq!(v, vec![1, 2, 3]);
            #
            # }) }
            ```
        "#]
        fn for_each<F>(
            self,
            f: F,
        ) -> impl Future<Output = ()> [ForEachFuture<Self, F, Self::Item>]
        where
            Self: Sized,
            F: FnMut(Self::Item),
        {
            ForEachFuture::new(self, f)
        }

        #[doc = r#"
            Tests if any element of the stream matches a predicate.

            `any()` takes a closure that returns `true` or `false`. It applies
            this closure to each element of the stream, and if any of them return
            `true`, then so does `any()`. If they all return `false`, it
            returns `false`.

            `any()` is short-circuiting; in other words, it will stop processing
            as soon as it finds a `true`, given that no matter what else happens,
            the result will also be `true`.

            An empty stream returns `false`.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::repeat::<u32>(42).take(3);
            assert!(s.any(|x| x ==  42).await);
            #
            # }) }
            ```

            Empty stream:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let mut s = stream::empty::<u32>();
            assert!(!s.any(|_| false).await);
            #
            # }) }
            ```
        "#]
        #[inline]
        fn any<F>(
            &mut self,
            f: F,
        ) -> impl Future<Output = bool> + '_ [AnyFuture<'_, Self, F, Self::Item>]
        where
            Self: Unpin + Sized,
            F: FnMut(Self::Item) -> bool,
        {
            AnyFuture {
                stream: self,
                result: false, // the default if the empty stream
                _marker: PhantomData,
                f,
            }
        }

        #[doc = r#"
            A stream adaptor similar to [`fold`] that holds internal state and produces a new
            stream.

            [`fold`]: #method.fold

            `scan()` takes two arguments: an initial value which seeds the internal state, and
            a closure with two arguments, the first being a mutable reference to the internal
            state and the second a stream element. The closure can assign to the internal state
            to share state between iterations.

            On iteration, the closure will be applied to each element of the stream and the
            return value from the closure, an `Option`, is yielded by the stream.

            ## Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1isize, 2, 3]);
            let mut s = s.scan(1, |state, x| {
                *state = *state * x;
                Some(-*state)
            });

            assert_eq!(s.next().await, Some(-1));
            assert_eq!(s.next().await, Some(-2));
            assert_eq!(s.next().await, Some(-6));
            assert_eq!(s.next().await, None);
            #
            # }) }
            ```
        "#]
        #[inline]
        fn scan<St, B, F>(self, initial_state: St, f: F) -> Scan<Self, St, F>
        where
            Self: Sized,
            F: FnMut(&mut St, Self::Item) -> Option<B>,
        {
            Scan::new(self, initial_state, f)
        }

        #[doc = r#"
            Combinator that `skip`s elements based on a predicate.

            Takes a closure argument. It will call this closure on every element in
            the stream and ignore elements until it returns `false`.

            After `false` is returned, `SkipWhile`'s job is over and all further
            elements in the strem are yielded.

            ## Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let a = stream::from_iter(vec![-1i32, 0, 1]);
            let mut s = a.skip_while(|x| x.is_negative());

            assert_eq!(s.next().await, Some(0));
            assert_eq!(s.next().await, Some(1));
            assert_eq!(s.next().await, None);
            #
            # }) }
            ```
        "#]
        fn skip_while<P>(self, predicate: P) -> SkipWhile<Self, P, Self::Item>
        where
            Self: Sized,
            P: FnMut(&Self::Item) -> bool,
        {
            SkipWhile::new(self, predicate)
        }

        #[doc = r#"
            Creates a combinator that skips the first `n` elements.

            ## Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1u8, 2, 3]);
            let mut skipped = s.skip(2);

            assert_eq!(skipped.next().await, Some(3));
            assert_eq!(skipped.next().await, None);
            #
            # }) }
            ```
        "#]
        fn skip(self, n: usize) -> Skip<Self>
        where
            Self: Sized,
        {
            Skip::new(self, n)
        }

        #[doc=r#"
            Await a stream or times out after a duration of time.

            If you want to await an I/O future consider using
            [`io::timeout`](../io/fn.timeout.html) instead.

            # Examples

            ```
            # fn main() -> std::io::Result<()> { async_std::task::block_on(async {
            #
            use std::time::Duration;

            use async_std::stream;
            use async_std::prelude::*;

            let mut s = stream::repeat(1).take(3).timeout(Duration::from_secs(1));

            while let Some(v) = s.next().await {
                assert_eq!(v, Ok(1));
            }
            #
            # Ok(()) }) }
            ```
        "#]
        #[cfg(any(feature = "unstable", feature = "docs"))]
        #[cfg_attr(feature = "docs", doc(cfg(unstable)))]
        fn timeout(self, dur: Duration) -> Timeout<Self>
        where
            Self: Stream + Sized,
        {
            Timeout::new(self, dur)
        }

        #[doc = r#"
            A combinator that applies a function as long as it returns successfully, producing a single, final value.
            Immediately returns the error when the function returns unsuccessfully.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1usize, 2, 3]);
            let sum = s.try_fold(0, |acc, v| {
                if (acc+v) % 2 == 1 {
                    Ok(v+3)
                } else {
                    Err("fail")
                }
            }).await;

            assert_eq!(sum, Err("fail"));
            #
            # }) }
            ```
        "#]
        fn try_fold<B, F, T, E>(
            self,
            init: T,
            f: F,
        ) -> impl Future<Output = Result<T, E>> [TryFoldFuture<Self, F, T>]
        where
            Self: Sized,
            F: FnMut(B, Self::Item) -> Result<T, E>,
        {
            TryFoldFuture::new(self, init, f)
        }

        #[doc = r#"
            Applies a falliable function to each element in a stream, stopping at first error and returning it.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use std::sync::mpsc::channel;
            use async_std::prelude::*;
            use async_std::stream;

            let (tx, rx) = channel();

            let s = stream::from_iter(vec![1u8, 2, 3]);
            let s = s.try_for_each(|v| {
                if v % 2 == 1 {
                    tx.clone().send(v).unwrap();
                    Ok(())
                } else {
                    Err("even")
                }
            });

            let res = s.await;
            drop(tx);
            let values: Vec<_> = rx.iter().collect();

            assert_eq!(values, vec![1]);
            assert_eq!(res, Err("even"));
            #
            # }) }
            ```
        "#]
        fn try_for_each<F, E>(
            self,
            f: F,
        ) -> impl Future<Output = E> [TryForEachFuture<Self, F, Self::Item, E>]
        where
            Self: Sized,
            F: FnMut(Self::Item) -> Result<(), E>,
        {
            TryForEachFuture::new(self, f)
        }

        #[doc = r#"
            'Zips up' two streams into a single stream of pairs.

            `zip()` returns a new stream that will iterate over two other streams, returning a
            tuple where the first element comes from the first stream, and the second element
            comes from the second stream.

            In other words, it zips two streams together, into a single one.

            If either stream returns [`None`], [`poll_next`] from the zipped stream will return
            [`None`]. If the first stream returns [`None`], `zip` will short-circuit and
            `poll_next` will not be called on the second stream.

            [`None`]: https://doc.rust-lang.org/std/option/enum.Option.html#variant.None
            [`poll_next`]: #tymethod.poll_next

            ## Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let l = stream::from_iter(vec![1u8, 2, 3]);
            let r = stream::from_iter(vec![4u8, 5, 6, 7]);
            let mut s = l.zip(r);

            assert_eq!(s.next().await, Some((1, 4)));
            assert_eq!(s.next().await, Some((2, 5)));
            assert_eq!(s.next().await, Some((3, 6)));
            assert_eq!(s.next().await, None);
            #
            # }) }
            ```
        "#]
        #[inline]
        fn zip<U>(self, other: U) -> Zip<Self, U>
        where
            Self: Sized + Stream,
            U: Stream,
        {
            Zip::new(self, other)
        }

        #[doc = r#"
            Transforms a stream into a collection.

            `collect()` can take anything streamable, and turn it into a relevant
            collection. This is one of the more powerful methods in the async
            standard library, used in a variety of contexts.

            The most basic pattern in which `collect()` is used is to turn one
            collection into another. You take a collection, call [`into_stream`] on it,
            do a bunch of transformations, and then `collect()` at the end.

            Because `collect()` is so general, it can cause problems with type
            inference. As such, `collect()` is one of the few times you'll see
            the syntax affectionately known as the 'turbofish': `::<>`. This
            helps the inference algorithm understand specifically which collection
            you're trying to collect into.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::repeat(9u8).take(3);
            let buf: Vec<u8> = s.collect().await;

            assert_eq!(buf, vec![9; 3]);

            // You can also collect streams of Result values
            // into any collection that implements FromStream
            let s = stream::repeat(Ok(9)).take(3);
            // We are using Vec here, but other collections
            // are supported as well
            let buf: Result<Vec<u8>, ()> = s.collect().await;

            assert_eq!(buf, Ok(vec![9; 3]));

            // The stream will stop on the first Err and
            // return that instead
            let s = stream::repeat(Err(5)).take(3);
            let buf: Result<Vec<u8>, u8> = s.collect().await;

            assert_eq!(buf, Err(5));
            #
            # }) }
            ```

            [`into_stream`]: trait.IntoStream.html#tymethod.into_stream
        "#]
        #[cfg(feature = "unstable")]
        #[cfg_attr(feature = "docs", doc(cfg(unstable)))]
        #[must_use = "if you really need to exhaust the iterator, consider `.for_each(drop)` instead (TODO)"]
        fn collect<'a, B>(
            self,
        ) -> impl Future<Output = B> + 'a [Pin<Box<dyn Future<Output = B> + 'a>>]
        where
            Self: Sized + 'a,
            B: FromStream<Self::Item>,
        {
            FromStream::from_stream(self)
        }

        #[doc = r#"
            Combines multiple streams into a single stream of all their outputs.

            Items are yielded as soon as they're received, and the stream continues yield until both
            streams have been exhausted.

            # Examples

            ```
            # async_std::task::block_on(async {
            use async_std::prelude::*;
            use async_std::stream;

            let a = stream::once(1u8);
            let b = stream::once(2u8);
            let c = stream::once(3u8);

            let mut s = a.merge(b).merge(c);

            assert_eq!(s.next().await, Some(1u8));
            assert_eq!(s.next().await, Some(2u8));
            assert_eq!(s.next().await, Some(3u8));
            assert_eq!(s.next().await, None);
            # });
            ```
        "#]
        #[cfg(feature = "unstable")]
        #[cfg_attr(feature = "docs", doc(cfg(unstable)))]
        fn merge<U>(self, other: U) -> Merge<Self, U>
        where
            Self: Sized,
            U: Stream<Item = Self::Item> + Sized,
        {
            Merge::new(self, other)
        }

        #[doc = r#"
            Lexicographically compares the elements of this `Stream` with those
            of another.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            use std::cmp::Ordering;

            let s1 = stream::from_iter(vec![1]);
            let s2 = stream::from_iter(vec![1, 2]);
            let s3 = stream::from_iter(vec![1, 2, 3]);
            let s4 = stream::from_iter(vec![1, 2, 4]);
            assert_eq!(s1.clone().partial_cmp(s1.clone()).await, Some(Ordering::Equal));
            assert_eq!(s1.clone().partial_cmp(s2.clone()).await, Some(Ordering::Less));
            assert_eq!(s2.clone().partial_cmp(s1.clone()).await, Some(Ordering::Greater));
            assert_eq!(s3.clone().partial_cmp(s4.clone()).await, Some(Ordering::Less));
            assert_eq!(s4.clone().partial_cmp(s3.clone()).await, Some(Ordering::Greater));
            #
            # }) }
            ```
        "#]
        fn partial_cmp<S>(
           self,
           other: S
        ) -> impl Future<Output = Option<Ordering>>  [PartialCmpFuture<Self, S>]
        where
            Self: Sized + Stream,
            S: Stream,
            <Self as Stream>::Item: PartialOrd<S::Item>,
        {
            PartialCmpFuture::new(self, other)
        }

        #[doc = r#"
            Searches for an element in a Stream that satisfies a predicate, returning
            its index.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![1usize, 2, 3]);
            let res = s.clone().position(|x| *x == 1).await;
            assert_eq!(res, Some(0));

            let res = s.clone().position(|x| *x == 2).await;
            assert_eq!(res, Some(1));

            let res = s.clone().position(|x| *x == 3).await;
            assert_eq!(res, Some(2));

            let res = s.clone().position(|x| *x == 4).await;
            assert_eq!(res, None);
            #
            # }) }
            ```
        "#]
        fn position<P>(
           self,
           predicate: P
        ) -> impl Future<Output = Option<usize>>  [PositionFuture<Self, P>]
        where
            Self: Sized,
            P: FnMut(&Self::Item) -> bool,
        {
            PositionFuture::new(self, predicate)
        }

        #[doc = r#"
            Lexicographically compares the elements of this `Stream` with those
            of another using 'Ord'.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;
            use std::cmp::Ordering;

            let s1 = stream::from_iter(vec![1]);
            let s2 = stream::from_iter(vec![1, 2]);
            let s3 = stream::from_iter(vec![1, 2, 3]);
            let s4 = stream::from_iter(vec![1, 2, 4]);

            assert_eq!(s1.clone().cmp(s1.clone()).await, Ordering::Equal);
            assert_eq!(s1.clone().cmp(s2.clone()).await, Ordering::Less);
            assert_eq!(s2.clone().cmp(s1.clone()).await, Ordering::Greater);
            assert_eq!(s3.clone().cmp(s4.clone()).await, Ordering::Less);
            assert_eq!(s4.clone().cmp(s3.clone()).await, Ordering::Greater);
            #
            # }) }
            ```
        "#]
        fn cmp<S>(
           self,
           other: S
        ) -> impl Future<Output = Ordering> [CmpFuture<Self, S>]
        where
            Self: Sized + Stream,
            S: Stream,
            <Self as Stream>::Item: Ord
        {
            CmpFuture::new(self, other)
        }

           #[doc = r#"
            Determines if the elements of this `Stream` are lexicographically
            not equal to those of another.
            # Examples
            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let single     = stream::from_iter(vec![1usize]);
            let single_ne  = stream::from_iter(vec![10usize]);
            let multi      = stream::from_iter(vec![1usize,2]);
            let multi_ne   = stream::from_iter(vec![1usize,5]);

            assert_eq!(single.clone().ne(single.clone()).await, false);
            assert_eq!(single_ne.clone().ne(single.clone()).await, true);
            assert_eq!(multi.clone().ne(single_ne.clone()).await, true);
            assert_eq!(multi_ne.clone().ne(multi.clone()).await, true);
            #
            # }) }
            ```
        "#]
        fn ne<S>(
           self,
           other: S
        ) -> impl Future<Output = bool> [NeFuture<Self, S>]
        where
            Self: Sized + Stream,
            S: Sized + Stream,
            <Self as Stream>::Item: PartialEq<S::Item>,
        {
            NeFuture::new(self, other)
        }

        #[doc = r#"
            Determines if the elements of this `Stream` are lexicographically
            greater than or equal to those of another.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let single    = stream::from_iter(vec![1]);
            let single_gt = stream::from_iter(vec![10]);
            let multi     = stream::from_iter(vec![1,2]);
            let multi_gt  = stream::from_iter(vec![1,5]);

            assert_eq!(single.clone().ge(single.clone()).await, true);
            assert_eq!(single_gt.clone().ge(single.clone()).await, true);
            assert_eq!(multi.clone().ge(single_gt.clone()).await, false);
            assert_eq!(multi_gt.clone().ge(multi.clone()).await, true);
            #
            # }) }
            ```
        "#]
        fn ge<S>(
           self,
           other: S
        ) -> impl Future<Output = bool> [GeFuture<Self, S>]
        where
            Self: Sized + Stream,
            S: Stream,
            <Self as Stream>::Item: PartialOrd<S::Item>,
        {
            GeFuture::new(self, other)
        }

        #[doc = r#"
            Determines if the elements of this `Stream` are lexicographically
            equal to those of another.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let single     = stream::from_iter(vec![1]);
            let single_eq  = stream::from_iter(vec![10]);
            let multi      = stream::from_iter(vec![1,2]);
            let multi_eq   = stream::from_iter(vec![1,5]);

            assert_eq!(single.clone().eq(single.clone()).await, true);
            assert_eq!(single_eq.clone().eq(single.clone()).await, false);
            assert_eq!(multi.clone().eq(single_eq.clone()).await, false);
            assert_eq!(multi_eq.clone().eq(multi.clone()).await, false);
            #
            # }) }
            ```
        "#]
        fn eq<S>(
           self,
           other: S
        ) -> impl Future<Output = bool> [EqFuture<Self, S>]
        where
            Self: Sized + Stream,
            S: Sized + Stream,
            <Self as Stream>::Item: PartialEq<S::Item>,
        {
            EqFuture::new(self, other)
        }

        #[doc = r#"
            Determines if the elements of this `Stream` are lexicographically
            greater than those of another.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let single = stream::from_iter(vec![1]);
            let single_gt = stream::from_iter(vec![10]);
            let multi = stream::from_iter(vec![1,2]);
            let multi_gt = stream::from_iter(vec![1,5]);

            assert_eq!(single.clone().gt(single.clone()).await, false);
            assert_eq!(single_gt.clone().gt(single.clone()).await, true);
            assert_eq!(multi.clone().gt(single_gt.clone()).await, false);
            assert_eq!(multi_gt.clone().gt(multi.clone()).await, true);
            #
            # }) }
            ```
        "#]
        fn gt<S>(
           self,
           other: S
        ) -> impl Future<Output = bool> [GtFuture<Self, S>]
        where
            Self: Sized + Stream,
            S: Stream,
            <Self as Stream>::Item: PartialOrd<S::Item>,
        {
            GtFuture::new(self, other)
        }

        #[doc = r#"
            Determines if the elements of this `Stream` are lexicographically
            less or equal to those of another.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let single = stream::from_iter(vec![1]);
            let single_gt = stream::from_iter(vec![10]);
            let multi = stream::from_iter(vec![1,2]);
            let multi_gt = stream::from_iter(vec![1,5]);

            assert_eq!(single.clone().le(single.clone()).await, true);
            assert_eq!(single.clone().le(single_gt.clone()).await, true);
            assert_eq!(multi.clone().le(single_gt.clone()).await, true);
            assert_eq!(multi_gt.clone().le(multi.clone()).await, false);
            #
            # }) }
            ```
        "#]
        fn le<S>(
           self,
           other: S
        ) -> impl Future<Output = bool> [LeFuture<Self, S>]
        where
            Self: Sized + Stream,
            S: Stream,
            <Self as Stream>::Item: PartialOrd<S::Item>,
        {
            LeFuture::new(self, other)
        }

        #[doc = r#"
            Determines if the elements of this `Stream` are lexicographically
            less than those of another.

            # Examples

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let single = stream::from_iter(vec![1]);
            let single_gt = stream::from_iter(vec![10]);
            let multi = stream::from_iter(vec![1,2]);
            let multi_gt = stream::from_iter(vec![1,5]);

            assert_eq!(single.clone().lt(single.clone()).await, false);
            assert_eq!(single.clone().lt(single_gt.clone()).await, true);
            assert_eq!(multi.clone().lt(single_gt.clone()).await, true);
            assert_eq!(multi_gt.clone().lt(multi.clone()).await, false);
            #
            # }) }
            ```
        "#]
        fn lt<S>(
           self,
           other: S
        ) -> impl Future<Output = bool> [LtFuture<Self, S>]
        where
            Self: Sized + Stream,
            S: Stream,
            <Self as Stream>::Item: PartialOrd<S::Item>,
        {
            LtFuture::new(self, other)
        }

        #[doc = r#"
            Sums the elements of an iterator.

            Takes each element, adds them together, and returns the result.

            An empty iterator returns the zero value of the type.

            # Panics

            When calling `sum()` and a primitive integer type is being returned, this
            method will panic if the computation overflows and debug assertions are
            enabled.

            # Examples

            Basic usage:

            ```
            # fn main() { async_std::task::block_on(async {
            #
            use async_std::prelude::*;
            use async_std::stream;

            let s = stream::from_iter(vec![0u8, 1, 2, 3, 4]);
            let sum: u8 = s.sum().await;

            assert_eq!(sum, 10);
            #
            # }) }
            ```
        "#]
        #[cfg(feature = "unstable")]
        #[cfg_attr(feature = "docs", doc(cfg(unstable)))]
        fn sum<'a, S>(
            self,
        ) -> impl Future<Output = S> + 'a [Pin<Box<dyn Future<Output = S> + 'a>>]
        where
            Self: Sized + Stream<Item = S> + 'a,
            S: Sum,
        {
            Sum::sum(self)
        }

        #[doc = r#"
            Iterates over the entire iterator, multiplying all the elements

            An empty iterator returns the one value of the type.

            # Panics

            When calling `product()` and a primitive integer type is being returned,
            method will panic if the computation overflows and debug assertions are
            enabled.

            # Examples

            This example calculates the factorial of n (i.e. the product of the numbers from 1 to
            n, inclusive):

            ```
            # fn main() { async_std::task::block_on(async {
            #
            async fn factorial(n: u32) -> u32 {
                use async_std::prelude::*;
                use async_std::stream;

                let s = stream::from_iter(1..=n);
                s.product().await
            }

            assert_eq!(factorial(0).await, 1);
            assert_eq!(factorial(1).await, 1);
            assert_eq!(factorial(5).await, 120);
            #
            # }) }
            ```
        "#]
        #[cfg(feature = "unstable")]
        #[cfg_attr(feature = "docs", doc(cfg(unstable)))]
        fn product<'a, P>(
            self,
        ) -> impl Future<Output = P> + 'a [Pin<Box<dyn Future<Output = P> + 'a>>]
        where
            Self: Sized + Stream<Item = P> + 'a,
            P: Product,
        {
            Product::product(self)
        }
    }

    impl<S: Stream + Unpin + ?Sized> Stream for Box<S> {
        type Item = S::Item;

        fn poll_next(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
            unreachable!("this impl only appears in the rendered docs")
        }
    }

    impl<S: Stream + Unpin + ?Sized> Stream for &mut S {
        type Item = S::Item;

        fn poll_next(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
            unreachable!("this impl only appears in the rendered docs")
        }
    }

    impl<P> Stream for Pin<P>
    where
        P: DerefMut + Unpin,
        <P as Deref>::Target: Stream,
    {
        type Item = <<P as Deref>::Target as Stream>::Item;

        fn poll_next(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
            unreachable!("this impl only appears in the rendered docs")
        }
    }

    impl<S: Stream> Stream for std::panic::AssertUnwindSafe<S> {
        type Item = S::Item;

        fn poll_next(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
            unreachable!("this impl only appears in the rendered docs")
        }
    }
}