src/tuple_impl.rs - platform/external/rust/crates/itertools - Git at Google

 //! Some iterator that produces tuples

 use std::iter::Fuse;
 use std::iter::FusedIterator;
 use std::iter::Take;
 use std::iter::Cycle;
 use std::marker::PhantomData;

 // `HomogeneousTuple` is a public facade for `TupleCollect`, allowing
 // tuple-related methods to be used by clients in generic contexts, while
 // hiding the implementation details of `TupleCollect`.
 // See https://github.com/rust-itertools/itertools/issues/387

 /// Implemented for homogeneous tuples of size up to 12.
 pub trait HomogeneousTuple
     : TupleCollect
 {}

 impl<T: TupleCollect> HomogeneousTuple for T {}

 /// An iterator over a incomplete tuple.
 ///
 /// See [`.tuples()`](crate::Itertools::tuples) and
 /// [`Tuples::into_buffer()`].
 #[derive(Clone, Debug)]
 pub struct TupleBuffer<T>
     where T: HomogeneousTuple
 {
     cur: usize,
     buf: T::Buffer,
 }

 impl<T> TupleBuffer<T>
     where T: HomogeneousTuple
 {
     fn new(buf: T::Buffer) -> Self {
         TupleBuffer {
             cur: 0,
             buf,
         }
     }
 }

 impl<T> Iterator for TupleBuffer<T>
     where T: HomogeneousTuple
 {
     type Item = T::Item;

     fn next(&mut self) -> Option<Self::Item> {
         let s = self.buf.as_mut();
         if let Some(ref mut item) = s.get_mut(self.cur) {
             self.cur += 1;
             item.take()
         } else {
             None
         }
     }

     fn size_hint(&self) -> (usize, Option<usize>) {
         let buffer = &self.buf.as_ref()[self.cur..];
         let len = if buffer.is_empty() {
             0
         } else {
             buffer.iter()
                   .position(|x| x.is_none())
                   .unwrap_or_else(|| buffer.len())
         };
         (len, Some(len))
     }
 }

 impl<T> ExactSizeIterator for TupleBuffer<T>
     where T: HomogeneousTuple
 {
 }

 /// An iterator that groups the items in tuples of a specific size.
 ///
 /// See [`.tuples()`](crate::Itertools::tuples) for more information.
 #[derive(Clone, Debug)]
 #[must_use = "iterator adaptors are lazy and do nothing unless consumed"]
 pub struct Tuples<I, T>
     where I: Iterator<Item = T::Item>,
           T: HomogeneousTuple
 {
     iter: Fuse<I>,
     buf: T::Buffer,
 }

 /// Create a new tuples iterator.
 pub fn tuples<I, T>(iter: I) -> Tuples<I, T>
     where I: Iterator<Item = T::Item>,
           T: HomogeneousTuple
 {
     Tuples {
         iter: iter.fuse(),
         buf: Default::default(),
     }
 }

 impl<I, T> Iterator for Tuples<I, T>
     where I: Iterator<Item = T::Item>,
           T: HomogeneousTuple
 {
     type Item = T;

     fn next(&mut self) -> Option<Self::Item> {
         T::collect_from_iter(&mut self.iter, &mut self.buf)
     }
 }

 impl<I, T> Tuples<I, T>
     where I: Iterator<Item = T::Item>,
           T: HomogeneousTuple
 {
     /// Return a buffer with the produced items that was not enough to be grouped in a tuple.
     ///
     /// ```
     /// use itertools::Itertools;
     ///
     /// let mut iter = (0..5).tuples();
     /// assert_eq!(Some((0, 1, 2)), iter.next());
     /// assert_eq!(None, iter.next());
     /// itertools::assert_equal(vec![3, 4], iter.into_buffer());
     /// ```
     pub fn into_buffer(self) -> TupleBuffer<T> {
         TupleBuffer::new(self.buf)
     }
 }


 /// An iterator over all contiguous windows that produces tuples of a specific size.
 ///
 /// See [`.tuple_windows()`](crate::Itertools::tuple_windows) for more
 /// information.
 #[must_use = "iterator adaptors are lazy and do nothing unless consumed"]
 #[derive(Clone, Debug)]
 pub struct TupleWindows<I, T>
     where I: Iterator<Item = T::Item>,
           T: HomogeneousTuple
 {
     iter: I,
     last: Option<T>,
 }

 /// Create a new tuple windows iterator.
 pub fn tuple_windows<I, T>(mut iter: I) -> TupleWindows<I, T>
     where I: Iterator<Item = T::Item>,
           T: HomogeneousTuple,
           T::Item: Clone
 {
     use std::iter::once;

     let mut last = None;
     if T::num_items() != 1 {
         // put in a duplicate item in front of the tuple; this simplifies
         // .next() function.
         if let Some(item) = iter.next() {
             let iter = once(item.clone()).chain(once(item)).chain(&mut iter);
             last = T::collect_from_iter_no_buf(iter);
         }
     }

     TupleWindows {
         iter,
         last,
     }
 }

 impl<I, T> Iterator for TupleWindows<I, T>
     where I: Iterator<Item = T::Item>,
           T: HomogeneousTuple + Clone,
           T::Item: Clone
 {
     type Item = T;

     fn next(&mut self) -> Option<Self::Item> {
         if T::num_items() == 1 {
             return T::collect_from_iter_no_buf(&mut self.iter)
         }
         if let Some(ref mut last) = self.last {
             if let Some(new) = self.iter.next() {
                 last.left_shift_push(new);
                 return Some(last.clone());
             }
         }
         None
     }
 }

 impl<I, T> FusedIterator for TupleWindows<I, T>
     where I: FusedIterator<Item = T::Item>,
           T: HomogeneousTuple + Clone,
           T::Item: Clone
 {}

 /// An iterator over all windows,wrapping back to the first elements when the
 /// window would otherwise exceed the length of the iterator, producing tuples
 /// of a specific size.
 ///
 /// See [`.circular_tuple_windows()`](crate::Itertools::circular_tuple_windows) for more
 /// information.
 #[must_use = "iterator adaptors are lazy and do nothing unless consumed"]
 #[derive(Debug)]
 pub struct CircularTupleWindows<I, T: Clone>
     where I: Iterator<Item = T::Item> + Clone,
           T: TupleCollect + Clone
 {
     iter: Take<TupleWindows<Cycle<I>, T>>,
     phantom_data: PhantomData<T>
 }

 pub fn circular_tuple_windows<I, T>(iter: I) -> CircularTupleWindows<I, T>
     where I: Iterator<Item = T::Item> + Clone + ExactSizeIterator,
           T: TupleCollect + Clone,
           T::Item: Clone
 {
     let len = iter.len();
     let iter = tuple_windows(iter.cycle()).take(len);

     CircularTupleWindows {
         iter,
         phantom_data: PhantomData{}
     }
 }

 impl<I, T> Iterator for CircularTupleWindows<I, T>
     where I: Iterator<Item = T::Item> + Clone,
           T: TupleCollect + Clone,
           T::Item: Clone
 {
     type Item = T;

     fn next(&mut self) -> Option<Self::Item> {
         self.iter.next()
     }
 }

 pub trait TupleCollect: Sized {
     type Item;
     type Buffer: Default + AsRef<[Option<Self::Item>]> + AsMut<[Option<Self::Item>]>;

     fn collect_from_iter<I>(iter: I, buf: &mut Self::Buffer) -> Option<Self>
         where I: IntoIterator<Item = Self::Item>;

     fn collect_from_iter_no_buf<I>(iter: I) -> Option<Self>
         where I: IntoIterator<Item = Self::Item>;

     fn num_items() -> usize;

     fn left_shift_push(&mut self, item: Self::Item);
 }

 macro_rules! count_ident{
     () => {0};
     ($i0:ident, $($i:ident,)*) => {1 + count_ident!($($i,)*)};
 }
 macro_rules! rev_for_each_ident{
     ($m:ident, ) => {};
     ($m:ident, $i0:ident, $($i:ident,)*) => {
         rev_for_each_ident!($m, $($i,)*);
         $m!($i0);
     };
 }

 macro_rules! impl_tuple_collect {
     ($dummy:ident,) => {}; // stop
     ($dummy:ident, $($Y:ident,)*) => (
         impl_tuple_collect!($($Y,)*);
         impl<A> TupleCollect for ($(ignore_ident!($Y, A),)*) {
             type Item = A;
             type Buffer = [Option<A>; count_ident!($($Y,)*) - 1];

             #[allow(unused_assignments, unused_mut)]
             fn collect_from_iter<I>(iter: I, buf: &mut Self::Buffer) -> Option<Self>
                 where I: IntoIterator<Item = A>
             {
                 let mut iter = iter.into_iter();
                 $(
                     let mut $Y = None;
                 )*

                 loop {
                     $(
                         $Y = iter.next();
                         if $Y.is_none() {
                             break
                         }
                     )*
                     return Some(($($Y.unwrap()),*,))
                 }

                 let mut i = 0;
                 let mut s = buf.as_mut();
                 $(
                     if i < s.len() {
                         s[i] = $Y;
                         i += 1;
                     }
                 )*
                 return None;
             }

             fn collect_from_iter_no_buf<I>(iter: I) -> Option<Self>
                 where I: IntoIterator<Item = A>
             {
                 let mut iter = iter.into_iter();

                 Some(($(
                     { let $Y = iter.next()?; $Y },
                 )*))
             }

             fn num_items() -> usize {
                 count_ident!($($Y,)*)
             }

             fn left_shift_push(&mut self, mut item: A) {
                 use std::mem::replace;

                 let &mut ($(ref mut $Y),*,) = self;
                 macro_rules! replace_item{($i:ident) => {
                     item = replace($i, item);
                 }}
                 rev_for_each_ident!(replace_item, $($Y,)*);
                 drop(item);
             }
         }
     )
 }
 impl_tuple_collect!(dummy, a, b, c, d, e, f, g, h, i, j, k, l,);
	//! Some iterator that produces tuples

	use std::iter::Fuse;
	use std::iter::FusedIterator;
	use std::iter::Take;
	use std::iter::Cycle;
	use std::marker::PhantomData;

	// `HomogeneousTuple` is a public facade for `TupleCollect`, allowing
	// tuple-related methods to be used by clients in generic contexts, while
	// hiding the implementation details of `TupleCollect`.
	// See https://github.com/rust-itertools/itertools/issues/387

	/// Implemented for homogeneous tuples of size up to 12.
	pub trait HomogeneousTuple
	: TupleCollect
	{}

	impl<T: TupleCollect> HomogeneousTuple for T {}

	/// An iterator over a incomplete tuple.
	///
	/// See [`.tuples()`](crate::Itertools::tuples) and
	/// [`Tuples::into_buffer()`].
	#[derive(Clone, Debug)]
	pub struct TupleBuffer<T>
	where T: HomogeneousTuple
	{
	cur: usize,
	buf: T::Buffer,
	}

	impl<T> TupleBuffer<T>
	where T: HomogeneousTuple
	{
	fn new(buf: T::Buffer) -> Self {
	TupleBuffer {
	cur: 0,
	buf,
	}
	}
	}

	impl<T> Iterator for TupleBuffer<T>
	where T: HomogeneousTuple
	{
	type Item = T::Item;

	fn next(&mut self) -> Option<Self::Item> {
	let s = self.buf.as_mut();
	if let Some(ref mut item) = s.get_mut(self.cur) {
	self.cur += 1;
	item.take()
	} else {
	None
	}
	}

	fn size_hint(&self) -> (usize, Option<usize>) {
	let buffer = &self.buf.as_ref()[self.cur..];
	let len = if buffer.is_empty() {
	0
	} else {
	buffer.iter()
	.position(\|x\| x.is_none())
	.unwrap_or_else(\|\| buffer.len())
	};
	(len, Some(len))
	}
	}

	impl<T> ExactSizeIterator for TupleBuffer<T>
	where T: HomogeneousTuple
	{
	}

	/// An iterator that groups the items in tuples of a specific size.
	///
	/// See [`.tuples()`](crate::Itertools::tuples) for more information.
	#[derive(Clone, Debug)]
	#[must_use = "iterator adaptors are lazy and do nothing unless consumed"]
	pub struct Tuples<I, T>
	where I: Iterator<Item = T::Item>,
	T: HomogeneousTuple
	{
	iter: Fuse<I>,
	buf: T::Buffer,
	}

	/// Create a new tuples iterator.
	pub fn tuples<I, T>(iter: I) -> Tuples<I, T>
	where I: Iterator<Item = T::Item>,
	T: HomogeneousTuple
	{
	Tuples {
	iter: iter.fuse(),
	buf: Default::default(),
	}
	}

	impl<I, T> Iterator for Tuples<I, T>
	where I: Iterator<Item = T::Item>,
	T: HomogeneousTuple
	{
	type Item = T;

	fn next(&mut self) -> Option<Self::Item> {
	T::collect_from_iter(&mut self.iter, &mut self.buf)
	}
	}

	impl<I, T> Tuples<I, T>
	where I: Iterator<Item = T::Item>,
	T: HomogeneousTuple
	{
	/// Return a buffer with the produced items that was not enough to be grouped in a tuple.
	///
	/// ```
	/// use itertools::Itertools;
	///
	/// let mut iter = (0..5).tuples();
	/// assert_eq!(Some((0, 1, 2)), iter.next());
	/// assert_eq!(None, iter.next());
	/// itertools::assert_equal(vec![3, 4], iter.into_buffer());
	/// ```
	pub fn into_buffer(self) -> TupleBuffer<T> {
	TupleBuffer::new(self.buf)
	}
	}


	/// An iterator over all contiguous windows that produces tuples of a specific size.
	///
	/// See [`.tuple_windows()`](crate::Itertools::tuple_windows) for more
	/// information.
	#[must_use = "iterator adaptors are lazy and do nothing unless consumed"]
	#[derive(Clone, Debug)]
	pub struct TupleWindows<I, T>
	where I: Iterator<Item = T::Item>,
	T: HomogeneousTuple
	{
	iter: I,
	last: Option<T>,
	}

	/// Create a new tuple windows iterator.
	pub fn tuple_windows<I, T>(mut iter: I) -> TupleWindows<I, T>
	where I: Iterator<Item = T::Item>,
	T: HomogeneousTuple,
	T::Item: Clone
	{
	use std::iter::once;

	let mut last = None;
	if T::num_items() != 1 {
	// put in a duplicate item in front of the tuple; this simplifies
	// .next() function.
	if let Some(item) = iter.next() {
	let iter = once(item.clone()).chain(once(item)).chain(&mut iter);
	last = T::collect_from_iter_no_buf(iter);
	}
	}

	TupleWindows {
	iter,
	last,
	}
	}

	impl<I, T> Iterator for TupleWindows<I, T>
	where I: Iterator<Item = T::Item>,
	T: HomogeneousTuple + Clone,
	T::Item: Clone
	{
	type Item = T;

	fn next(&mut self) -> Option<Self::Item> {
	if T::num_items() == 1 {
	return T::collect_from_iter_no_buf(&mut self.iter)
	}
	if let Some(ref mut last) = self.last {
	if let Some(new) = self.iter.next() {
	last.left_shift_push(new);
	return Some(last.clone());
	}
	}
	None
	}
	}

	impl<I, T> FusedIterator for TupleWindows<I, T>
	where I: FusedIterator<Item = T::Item>,
	T: HomogeneousTuple + Clone,
	T::Item: Clone
	{}

	/// An iterator over all windows,wrapping back to the first elements when the
	/// window would otherwise exceed the length of the iterator, producing tuples
	/// of a specific size.
	///
	/// See [`.circular_tuple_windows()`](crate::Itertools::circular_tuple_windows) for more
	/// information.
	#[must_use = "iterator adaptors are lazy and do nothing unless consumed"]
	#[derive(Debug)]
	pub struct CircularTupleWindows<I, T: Clone>
	where I: Iterator<Item = T::Item> + Clone,
	T: TupleCollect + Clone
	{
	iter: Take<TupleWindows<Cycle<I>, T>>,
	phantom_data: PhantomData<T>
	}

	pub fn circular_tuple_windows<I, T>(iter: I) -> CircularTupleWindows<I, T>
	where I: Iterator<Item = T::Item> + Clone + ExactSizeIterator,
	T: TupleCollect + Clone,
	T::Item: Clone
	{
	let len = iter.len();
	let iter = tuple_windows(iter.cycle()).take(len);

	CircularTupleWindows {
	iter,
	phantom_data: PhantomData{}
	}
	}

	impl<I, T> Iterator for CircularTupleWindows<I, T>
	where I: Iterator<Item = T::Item> + Clone,
	T: TupleCollect + Clone,
	T::Item: Clone
	{
	type Item = T;

	fn next(&mut self) -> Option<Self::Item> {
	self.iter.next()
	}
	}

	pub trait TupleCollect: Sized {
	type Item;
	type Buffer: Default + AsRef<[Option<Self::Item>]> + AsMut<[Option<Self::Item>]>;

	fn collect_from_iter<I>(iter: I, buf: &mut Self::Buffer) -> Option<Self>
	where I: IntoIterator<Item = Self::Item>;

	fn collect_from_iter_no_buf<I>(iter: I) -> Option<Self>
	where I: IntoIterator<Item = Self::Item>;

	fn num_items() -> usize;

	fn left_shift_push(&mut self, item: Self::Item);
	}

	macro_rules! count_ident{
	() => {0};
	($i0:ident, $($i:ident,)) => {1 + count_ident!($($i,))};
	}
	macro_rules! rev_for_each_ident{
	($m:ident, ) => {};
	($m:ident, $i0:ident, $($i:ident,)*) => {
	rev_for_each_ident!($m, $($i,)*);
	$m!($i0);
	};
	}

	macro_rules! impl_tuple_collect {
	($dummy:ident,) => {}; // stop
	($dummy:ident, $($Y:ident,)*) => (
	impl_tuple_collect!($($Y,)*);
	impl<A> TupleCollect for ($(ignore_ident!($Y, A),)*) {
	type Item = A;
	type Buffer = [Option<A>; count_ident!($($Y,)*) - 1];

	#[allow(unused_assignments, unused_mut)]
	fn collect_from_iter<I>(iter: I, buf: &mut Self::Buffer) -> Option<Self>
	where I: IntoIterator<Item = A>
	{
	let mut iter = iter.into_iter();
	$(
	let mut $Y = None;
	)*

	loop {
	$(
	$Y = iter.next();
	if $Y.is_none() {
	break
	}
	)*
	return Some(($($Y.unwrap()),*,))
	}

	let mut i = 0;
	let mut s = buf.as_mut();
	$(
	if i < s.len() {
	s[i] = $Y;
	i += 1;
	}
	)*
	return None;
	}

	fn collect_from_iter_no_buf<I>(iter: I) -> Option<Self>
	where I: IntoIterator<Item = A>
	{
	let mut iter = iter.into_iter();

	Some(($(
	{ let $Y = iter.next()?; $Y },
	)*))
	}

	fn num_items() -> usize {
	count_ident!($($Y,)*)
	}

	fn left_shift_push(&mut self, mut item: A) {
	use std::mem::replace;

	let &mut ($(ref mut $Y),*,) = self;
	macro_rules! replace_item{($i:ident) => {
	item = replace($i, item);
	}}
	rev_for_each_ident!(replace_item, $($Y,)*);
	drop(item);
	}
	}
	)
	}
	impl_tuple_collect!(dummy, a, b, c, d, e, f, g, h, i, j, k, l,);