aarch64/usr/lib/rustlib/src/rust/library/alloc/src/collections/btree/append.rs - manifest_repos/toolchain - Git at Google

 use super::merge_iter::MergeIterInner;
 use super::node::{self, Root};
 use core::alloc::Allocator;
 use core::iter::FusedIterator;

 impl<K, V> Root<K, V> {
     /// Appends all key-value pairs from the union of two ascending iterators,
     /// incrementing a `length` variable along the way. The latter makes it
     /// easier for the caller to avoid a leak when a drop handler panicks.
     ///
     /// If both iterators produce the same key, this method drops the pair from
     /// the left iterator and appends the pair from the right iterator.
     ///
     /// If you want the tree to end up in a strictly ascending order, like for
     /// a `BTreeMap`, both iterators should produce keys in strictly ascending
     /// order, each greater than all keys in the tree, including any keys
     /// already in the tree upon entry.
     pub fn append_from_sorted_iters<I, A: Allocator + Clone>(
         &mut self,
         left: I,
         right: I,
         length: &mut usize,
         alloc: A,
     ) where
         K: Ord,
         I: Iterator<Item = (K, V)> + FusedIterator,
     {
         // We prepare to merge `left` and `right` into a sorted sequence in linear time.
         let iter = MergeIter(MergeIterInner::new(left, right));

         // Meanwhile, we build a tree from the sorted sequence in linear time.
         self.bulk_push(iter, length, alloc)
     }

     /// Pushes all key-value pairs to the end of the tree, incrementing a
     /// `length` variable along the way. The latter makes it easier for the
     /// caller to avoid a leak when the iterator panicks.
     pub fn bulk_push<I, A: Allocator + Clone>(&mut self, iter: I, length: &mut usize, alloc: A)
     where
         I: Iterator<Item = (K, V)>,
     {
         let mut cur_node = self.borrow_mut().last_leaf_edge().into_node();
         // Iterate through all key-value pairs, pushing them into nodes at the right level.
         for (key, value) in iter {
             // Try to push key-value pair into the current leaf node.
             if cur_node.len() < node::CAPACITY {
                 cur_node.push(key, value);
             } else {
                 // No space left, go up and push there.
                 let mut open_node;
                 let mut test_node = cur_node.forget_type();
                 loop {
                     match test_node.ascend() {
                         Ok(parent) => {
                             let parent = parent.into_node();
                             if parent.len() < node::CAPACITY {
                                 // Found a node with space left, push here.
                                 open_node = parent;
                                 break;
                             } else {
                                 // Go up again.
                                 test_node = parent.forget_type();
                             }
                         }
                         Err(_) => {
                             // We are at the top, create a new root node and push there.
                             open_node = self.push_internal_level(alloc.clone());
                             break;
                         }
                     }
                 }

                 // Push key-value pair and new right subtree.
                 let tree_height = open_node.height() - 1;
                 let mut right_tree = Root::new(alloc.clone());
                 for _ in 0..tree_height {
                     right_tree.push_internal_level(alloc.clone());
                 }
                 open_node.push(key, value, right_tree);

                 // Go down to the right-most leaf again.
                 cur_node = open_node.forget_type().last_leaf_edge().into_node();
             }

             // Increment length every iteration, to make sure the map drops
             // the appended elements even if advancing the iterator panicks.
             *length += 1;
         }
         self.fix_right_border_of_plentiful();
     }
 }

 // An iterator for merging two sorted sequences into one
 struct MergeIter<K, V, I: Iterator<Item = (K, V)>>(MergeIterInner<I>);

 impl<K: Ord, V, I> Iterator for MergeIter<K, V, I>
 where
     I: Iterator<Item = (K, V)> + FusedIterator,
 {
     type Item = (K, V);

     /// If two keys are equal, returns the key-value pair from the right source.
     fn next(&mut self) -> Option<(K, V)> {
         let (a_next, b_next) = self.0.nexts(|a: &(K, V), b: &(K, V)| K::cmp(&a.0, &b.0));
         b_next.or(a_next)
     }
 }
	use super::merge_iter::MergeIterInner;
	use super::node::{self, Root};
	use core::alloc::Allocator;
	use core::iter::FusedIterator;

	impl<K, V> Root<K, V> {
	/// Appends all key-value pairs from the union of two ascending iterators,
	/// incrementing a `length` variable along the way. The latter makes it
	/// easier for the caller to avoid a leak when a drop handler panicks.
	///
	/// If both iterators produce the same key, this method drops the pair from
	/// the left iterator and appends the pair from the right iterator.
	///
	/// If you want the tree to end up in a strictly ascending order, like for
	/// a `BTreeMap`, both iterators should produce keys in strictly ascending
	/// order, each greater than all keys in the tree, including any keys
	/// already in the tree upon entry.
	pub fn append_from_sorted_iters<I, A: Allocator + Clone>(
	&mut self,
	left: I,
	right: I,
	length: &mut usize,
	alloc: A,
	) where
	K: Ord,
	I: Iterator<Item = (K, V)> + FusedIterator,
	{
	// We prepare to merge `left` and `right` into a sorted sequence in linear time.
	let iter = MergeIter(MergeIterInner::new(left, right));

	// Meanwhile, we build a tree from the sorted sequence in linear time.
	self.bulk_push(iter, length, alloc)
	}

	/// Pushes all key-value pairs to the end of the tree, incrementing a
	/// `length` variable along the way. The latter makes it easier for the
	/// caller to avoid a leak when the iterator panicks.
	pub fn bulk_push<I, A: Allocator + Clone>(&mut self, iter: I, length: &mut usize, alloc: A)
	where
	I: Iterator<Item = (K, V)>,
	{
	let mut cur_node = self.borrow_mut().last_leaf_edge().into_node();
	// Iterate through all key-value pairs, pushing them into nodes at the right level.
	for (key, value) in iter {
	// Try to push key-value pair into the current leaf node.
	if cur_node.len() < node::CAPACITY {
	cur_node.push(key, value);
	} else {
	// No space left, go up and push there.
	let mut open_node;
	let mut test_node = cur_node.forget_type();
	loop {
	match test_node.ascend() {
	Ok(parent) => {
	let parent = parent.into_node();
	if parent.len() < node::CAPACITY {
	// Found a node with space left, push here.
	open_node = parent;
	break;
	} else {
	// Go up again.
	test_node = parent.forget_type();
	}
	}
	Err(_) => {
	// We are at the top, create a new root node and push there.
	open_node = self.push_internal_level(alloc.clone());
	break;
	}
	}
	}

	// Push key-value pair and new right subtree.
	let tree_height = open_node.height() - 1;
	let mut right_tree = Root::new(alloc.clone());
	for _ in 0..tree_height {
	right_tree.push_internal_level(alloc.clone());
	}
	open_node.push(key, value, right_tree);

	// Go down to the right-most leaf again.
	cur_node = open_node.forget_type().last_leaf_edge().into_node();
	}

	// Increment length every iteration, to make sure the map drops
	// the appended elements even if advancing the iterator panicks.
	*length += 1;
	}
	self.fix_right_border_of_plentiful();
	}
	}

	// An iterator for merging two sorted sequences into one
	struct MergeIter<K, V, I: Iterator<Item = (K, V)>>(MergeIterInner<I>);

	impl<K: Ord, V, I> Iterator for MergeIter<K, V, I>
	where
	I: Iterator<Item = (K, V)> + FusedIterator,
	{
	type Item = (K, V);

	/// If two keys are equal, returns the key-value pair from the right source.
	fn next(&mut self) -> Option<(K, V)> {
	let (a_next, b_next) = self.0.nexts(\|a: &(K, V), b: &(K, V)\| K::cmp(&a.0, &b.0));
	b_next.or(a_next)
	}
	}