x86_64/usr/lib/rustlib/src/rust/library/alloc/src/collections/btree/split.rs - manifest_repos/toolchain - Git at Google

 use super::node::{ForceResult::*, Root};
 use super::search::SearchResult::*;
 use core::alloc::Allocator;
 use core::borrow::Borrow;

 impl<K, V> Root<K, V> {
     /// Calculates the length of both trees that result from splitting up
     /// a given number of distinct key-value pairs.
     pub fn calc_split_length(
         total_num: usize,
         root_a: &Root<K, V>,
         root_b: &Root<K, V>,
     ) -> (usize, usize) {
         let (length_a, length_b);
         if root_a.height() < root_b.height() {
             length_a = root_a.reborrow().calc_length();
             length_b = total_num - length_a;
             debug_assert_eq!(length_b, root_b.reborrow().calc_length());
         } else {
             length_b = root_b.reborrow().calc_length();
             length_a = total_num - length_b;
             debug_assert_eq!(length_a, root_a.reborrow().calc_length());
         }
         (length_a, length_b)
     }

     /// Split off a tree with key-value pairs at and after the given key.
     /// The result is meaningful only if the tree is ordered by key,
     /// and if the ordering of `Q` corresponds to that of `K`.
     /// If `self` respects all `BTreeMap` tree invariants, then both
     /// `self` and the returned tree will respect those invariants.
     pub fn split_off<Q: ?Sized + Ord, A: Allocator + Clone>(&mut self, key: &Q, alloc: A) -> Self
     where
         K: Borrow<Q>,
     {
         let left_root = self;
         let mut right_root = Root::new_pillar(left_root.height(), alloc.clone());
         let mut left_node = left_root.borrow_mut();
         let mut right_node = right_root.borrow_mut();

         loop {
             let mut split_edge = match left_node.search_node(key) {
                 // key is going to the right tree
                 Found(kv) => kv.left_edge(),
                 GoDown(edge) => edge,
             };

             split_edge.move_suffix(&mut right_node);

             match (split_edge.force(), right_node.force()) {
                 (Internal(edge), Internal(node)) => {
                     left_node = edge.descend();
                     right_node = node.first_edge().descend();
                 }
                 (Leaf(_), Leaf(_)) => break,
                 _ => unreachable!(),
             }
         }

         left_root.fix_right_border(alloc.clone());
         right_root.fix_left_border(alloc);
         right_root
     }

     /// Creates a tree consisting of empty nodes.
     fn new_pillar<A: Allocator + Clone>(height: usize, alloc: A) -> Self {
         let mut root = Root::new(alloc.clone());
         for _ in 0..height {
             root.push_internal_level(alloc.clone());
         }
         root
     }
 }
	use super::node::{ForceResult::*, Root};
	use super::search::SearchResult::*;
	use core::alloc::Allocator;
	use core::borrow::Borrow;

	impl<K, V> Root<K, V> {
	/// Calculates the length of both trees that result from splitting up
	/// a given number of distinct key-value pairs.
	pub fn calc_split_length(
	total_num: usize,
	root_a: &Root<K, V>,
	root_b: &Root<K, V>,
	) -> (usize, usize) {
	let (length_a, length_b);
	if root_a.height() < root_b.height() {
	length_a = root_a.reborrow().calc_length();
	length_b = total_num - length_a;
	debug_assert_eq!(length_b, root_b.reborrow().calc_length());
	} else {
	length_b = root_b.reborrow().calc_length();
	length_a = total_num - length_b;
	debug_assert_eq!(length_a, root_a.reborrow().calc_length());
	}
	(length_a, length_b)
	}

	/// Split off a tree with key-value pairs at and after the given key.
	/// The result is meaningful only if the tree is ordered by key,
	/// and if the ordering of `Q` corresponds to that of `K`.
	/// If `self` respects all `BTreeMap` tree invariants, then both
	/// `self` and the returned tree will respect those invariants.
	pub fn split_off<Q: ?Sized + Ord, A: Allocator + Clone>(&mut self, key: &Q, alloc: A) -> Self
	where
	K: Borrow<Q>,
	{
	let left_root = self;
	let mut right_root = Root::new_pillar(left_root.height(), alloc.clone());
	let mut left_node = left_root.borrow_mut();
	let mut right_node = right_root.borrow_mut();

	loop {
	let mut split_edge = match left_node.search_node(key) {
	// key is going to the right tree
	Found(kv) => kv.left_edge(),
	GoDown(edge) => edge,
	};

	split_edge.move_suffix(&mut right_node);

	match (split_edge.force(), right_node.force()) {
	(Internal(edge), Internal(node)) => {
	left_node = edge.descend();
	right_node = node.first_edge().descend();
	}
	(Leaf(_), Leaf(_)) => break,
	_ => unreachable!(),
	}
	}

	left_root.fix_right_border(alloc.clone());
	right_root.fix_left_border(alloc);
	right_root
	}

	/// Creates a tree consisting of empty nodes.
	fn new_pillar<A: Allocator + Clone>(height: usize, alloc: A) -> Self {
	let mut root = Root::new(alloc.clone());
	for _ in 0..height {
	root.push_internal_level(alloc.clone());
	}
	root
	}
	}