third_party/rust_crates/vendor/itertools/src/rciter_impl.rs - fuchsia - Git at Google


 use std::iter::IntoIterator;
 use std::rc::Rc;
 use std::cell::RefCell;

 /// A wrapper for `Rc<RefCell<I>>`, that implements the `Iterator` trait.
 #[derive(Debug)]
 pub struct RcIter<I> {
     /// The boxed iterator.
     pub rciter: Rc<RefCell<I>>,
 }

 /// Return an iterator inside a `Rc<RefCell<_>>` wrapper.
 ///
 /// The returned `RcIter` can be cloned, and each clone will refer back to the
 /// same original iterator.
 ///
 /// `RcIter` allows doing interesting things like using `.zip()` on an iterator with
 /// itself, at the cost of runtime borrow checking which may have a performance
 /// penalty.
 ///
 /// Iterator element type is `Self::Item`.
 ///
 /// ```
 /// use itertools::rciter;
 /// use itertools::zip;
 ///
 /// // In this example a range iterator is created and we iterate it using
 /// // three separate handles (two of them given to zip).
 /// // We also use the IntoIterator implementation for `&RcIter`.
 ///
 /// let mut iter = rciter(0..9);
 /// let mut z = zip(&iter, &iter);
 ///
 /// assert_eq!(z.next(), Some((0, 1)));
 /// assert_eq!(z.next(), Some((2, 3)));
 /// assert_eq!(z.next(), Some((4, 5)));
 /// assert_eq!(iter.next(), Some(6));
 /// assert_eq!(z.next(), Some((7, 8)));
 /// assert_eq!(z.next(), None);
 /// ```
 ///
 /// **Panics** in iterator methods if a borrow error is encountered in the
 /// iterator methods. It can only happen if the `RcIter` is reentered in
 /// `.next()`, i.e. if it somehow participates in an “iterator knot”
 /// where it is an adaptor of itself.
 pub fn rciter<I>(iterable: I) -> RcIter<I::IntoIter>
     where I: IntoIterator
 {
     RcIter { rciter: Rc::new(RefCell::new(iterable.into_iter())) }
 }

 impl<I> Clone for RcIter<I> {
     #[inline]
     fn clone(&self) -> RcIter<I> {
         RcIter { rciter: self.rciter.clone() }
     }
 }

 impl<A, I> Iterator for RcIter<I>
     where I: Iterator<Item = A>
 {
     type Item = A;
     #[inline]
     fn next(&mut self) -> Option<A> {
         self.rciter.borrow_mut().next()
     }

     #[inline]
     fn size_hint(&self) -> (usize, Option<usize>) {
         // To work sanely with other API that assume they own an iterator,
         // so it can't change in other places, we can't guarantee as much
         // in our size_hint. Other clones may drain values under our feet.
         let (_, hi) = self.rciter.borrow().size_hint();
         (0, hi)
     }
 }

 impl<I> DoubleEndedIterator for RcIter<I>
     where I: DoubleEndedIterator
 {
     #[inline]
     fn next_back(&mut self) -> Option<I::Item> {
         self.rciter.borrow_mut().next_back()
     }
 }

 /// Return an iterator from `&RcIter<I>` (by simply cloning it).
 impl<'a, I> IntoIterator for &'a RcIter<I>
     where I: Iterator
 {
     type Item = I::Item;
     type IntoIter = RcIter<I>;

     fn into_iter(self) -> RcIter<I> {
         self.clone()
     }
 }

	use std::iter::IntoIterator;
	use std::rc::Rc;
	use std::cell::RefCell;

	/// A wrapper for `Rc<RefCell<I>>`, that implements the `Iterator` trait.
	#[derive(Debug)]
	pub struct RcIter<I> {
	/// The boxed iterator.
	pub rciter: Rc<RefCell<I>>,
	}

	/// Return an iterator inside a `Rc<RefCell<_>>` wrapper.
	///
	/// The returned `RcIter` can be cloned, and each clone will refer back to the
	/// same original iterator.
	///
	/// `RcIter` allows doing interesting things like using `.zip()` on an iterator with
	/// itself, at the cost of runtime borrow checking which may have a performance
	/// penalty.
	///
	/// Iterator element type is `Self::Item`.
	///
	/// ```
	/// use itertools::rciter;
	/// use itertools::zip;
	///
	/// // In this example a range iterator is created and we iterate it using
	/// // three separate handles (two of them given to zip).
	/// // We also use the IntoIterator implementation for `&RcIter`.
	///
	/// let mut iter = rciter(0..9);
	/// let mut z = zip(&iter, &iter);
	///
	/// assert_eq!(z.next(), Some((0, 1)));
	/// assert_eq!(z.next(), Some((2, 3)));
	/// assert_eq!(z.next(), Some((4, 5)));
	/// assert_eq!(iter.next(), Some(6));
	/// assert_eq!(z.next(), Some((7, 8)));
	/// assert_eq!(z.next(), None);
	/// ```
	///
	/// Panics in iterator methods if a borrow error is encountered in the
	/// iterator methods. It can only happen if the `RcIter` is reentered in
	/// `.next()`, i.e. if it somehow participates in an “iterator knot”
	/// where it is an adaptor of itself.
	pub fn rciter<I>(iterable: I) -> RcIter<I::IntoIter>
	where I: IntoIterator
	{
	RcIter { rciter: Rc::new(RefCell::new(iterable.into_iter())) }
	}

	impl<I> Clone for RcIter<I> {
	#[inline]
	fn clone(&self) -> RcIter<I> {
	RcIter { rciter: self.rciter.clone() }
	}
	}

	impl<A, I> Iterator for RcIter<I>
	where I: Iterator<Item = A>
	{
	type Item = A;
	#[inline]
	fn next(&mut self) -> Option<A> {
	self.rciter.borrow_mut().next()
	}

	#[inline]
	fn size_hint(&self) -> (usize, Option<usize>) {
	// To work sanely with other API that assume they own an iterator,
	// so it can't change in other places, we can't guarantee as much
	// in our size_hint. Other clones may drain values under our feet.
	let (_, hi) = self.rciter.borrow().size_hint();
	(0, hi)
	}
	}

	impl<I> DoubleEndedIterator for RcIter<I>
	where I: DoubleEndedIterator
	{
	#[inline]
	fn next_back(&mut self) -> Option<I::Item> {
	self.rciter.borrow_mut().next_back()
	}
	}

	/// Return an iterator from `&RcIter<I>` (by simply cloning it).
	impl<'a, I> IntoIterator for &'a RcIter<I>
	where I: Iterator
	{
	type Item = I::Item;
	type IntoIter = RcIter<I>;

	fn into_iter(self) -> RcIter<I> {
	self.clone()
	}
	}