mirror of
https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
synced 2024-12-28 16:53:49 +00:00
8373147ce4
Now that we got the kernel `Box` type in place, convert all existing `Box` users to make use of it. Reviewed-by: Alice Ryhl <aliceryhl@google.com> Reviewed-by: Benno Lossin <benno.lossin@proton.me> Reviewed-by: Gary Guo <gary@garyguo.net> Signed-off-by: Danilo Krummrich <dakr@kernel.org> Link: https://lore.kernel.org/r/20241004154149.93856-13-dakr@kernel.org Signed-off-by: Miguel Ojeda <ojeda@kernel.org>
1287 lines
48 KiB
Rust
1287 lines
48 KiB
Rust
// SPDX-License-Identifier: GPL-2.0
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//! Red-black trees.
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//!
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//! C header: [`include/linux/rbtree.h`](srctree/include/linux/rbtree.h)
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//!
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//! Reference: <https://docs.kernel.org/core-api/rbtree.html>
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use crate::{alloc::Flags, bindings, container_of, error::Result, prelude::*};
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use core::{
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cmp::{Ord, Ordering},
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marker::PhantomData,
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mem::MaybeUninit,
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ptr::{addr_of_mut, from_mut, NonNull},
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};
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/// A red-black tree with owned nodes.
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///
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/// It is backed by the kernel C red-black trees.
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///
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/// # Examples
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///
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/// In the example below we do several operations on a tree. We note that insertions may fail if
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/// the system is out of memory.
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///
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/// ```
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/// use kernel::{alloc::flags, rbtree::{RBTree, RBTreeNode, RBTreeNodeReservation}};
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///
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/// // Create a new tree.
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/// let mut tree = RBTree::new();
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///
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/// // Insert three elements.
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/// tree.try_create_and_insert(20, 200, flags::GFP_KERNEL)?;
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/// tree.try_create_and_insert(10, 100, flags::GFP_KERNEL)?;
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/// tree.try_create_and_insert(30, 300, flags::GFP_KERNEL)?;
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///
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/// // Check the nodes we just inserted.
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/// {
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/// assert_eq!(tree.get(&10).unwrap(), &100);
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/// assert_eq!(tree.get(&20).unwrap(), &200);
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/// assert_eq!(tree.get(&30).unwrap(), &300);
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/// }
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///
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/// // Iterate over the nodes we just inserted.
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/// {
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/// let mut iter = tree.iter();
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/// assert_eq!(iter.next().unwrap(), (&10, &100));
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/// assert_eq!(iter.next().unwrap(), (&20, &200));
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/// assert_eq!(iter.next().unwrap(), (&30, &300));
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/// assert!(iter.next().is_none());
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/// }
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///
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/// // Print all elements.
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/// for (key, value) in &tree {
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/// pr_info!("{} = {}\n", key, value);
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/// }
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///
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/// // Replace one of the elements.
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/// tree.try_create_and_insert(10, 1000, flags::GFP_KERNEL)?;
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///
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/// // Check that the tree reflects the replacement.
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/// {
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/// let mut iter = tree.iter();
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/// assert_eq!(iter.next().unwrap(), (&10, &1000));
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/// assert_eq!(iter.next().unwrap(), (&20, &200));
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/// assert_eq!(iter.next().unwrap(), (&30, &300));
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/// assert!(iter.next().is_none());
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/// }
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///
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/// // Change the value of one of the elements.
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/// *tree.get_mut(&30).unwrap() = 3000;
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///
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/// // Check that the tree reflects the update.
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/// {
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/// let mut iter = tree.iter();
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/// assert_eq!(iter.next().unwrap(), (&10, &1000));
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/// assert_eq!(iter.next().unwrap(), (&20, &200));
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/// assert_eq!(iter.next().unwrap(), (&30, &3000));
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/// assert!(iter.next().is_none());
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/// }
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///
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/// // Remove an element.
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/// tree.remove(&10);
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///
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/// // Check that the tree reflects the removal.
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/// {
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/// let mut iter = tree.iter();
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/// assert_eq!(iter.next().unwrap(), (&20, &200));
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/// assert_eq!(iter.next().unwrap(), (&30, &3000));
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/// assert!(iter.next().is_none());
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/// }
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///
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/// # Ok::<(), Error>(())
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/// ```
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///
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/// In the example below, we first allocate a node, acquire a spinlock, then insert the node into
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/// the tree. This is useful when the insertion context does not allow sleeping, for example, when
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/// holding a spinlock.
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///
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/// ```
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/// use kernel::{alloc::flags, rbtree::{RBTree, RBTreeNode}, sync::SpinLock};
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///
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/// fn insert_test(tree: &SpinLock<RBTree<u32, u32>>) -> Result {
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/// // Pre-allocate node. This may fail (as it allocates memory).
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/// let node = RBTreeNode::new(10, 100, flags::GFP_KERNEL)?;
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///
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/// // Insert node while holding the lock. It is guaranteed to succeed with no allocation
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/// // attempts.
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/// let mut guard = tree.lock();
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/// guard.insert(node);
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/// Ok(())
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/// }
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/// ```
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///
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/// In the example below, we reuse an existing node allocation from an element we removed.
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///
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/// ```
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/// use kernel::{alloc::flags, rbtree::{RBTree, RBTreeNodeReservation}};
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///
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/// // Create a new tree.
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/// let mut tree = RBTree::new();
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///
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/// // Insert three elements.
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/// tree.try_create_and_insert(20, 200, flags::GFP_KERNEL)?;
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/// tree.try_create_and_insert(10, 100, flags::GFP_KERNEL)?;
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/// tree.try_create_and_insert(30, 300, flags::GFP_KERNEL)?;
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///
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/// // Check the nodes we just inserted.
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/// {
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/// let mut iter = tree.iter();
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/// assert_eq!(iter.next().unwrap(), (&10, &100));
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/// assert_eq!(iter.next().unwrap(), (&20, &200));
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/// assert_eq!(iter.next().unwrap(), (&30, &300));
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/// assert!(iter.next().is_none());
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/// }
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///
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/// // Remove a node, getting back ownership of it.
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/// let existing = tree.remove(&30).unwrap();
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///
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/// // Check that the tree reflects the removal.
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/// {
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/// let mut iter = tree.iter();
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/// assert_eq!(iter.next().unwrap(), (&10, &100));
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/// assert_eq!(iter.next().unwrap(), (&20, &200));
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/// assert!(iter.next().is_none());
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/// }
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///
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/// // Create a preallocated reservation that we can re-use later.
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/// let reservation = RBTreeNodeReservation::new(flags::GFP_KERNEL)?;
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///
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/// // Insert a new node into the tree, reusing the previous allocation. This is guaranteed to
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/// // succeed (no memory allocations).
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/// tree.insert(reservation.into_node(15, 150));
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///
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/// // Check that the tree reflect the new insertion.
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/// {
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/// let mut iter = tree.iter();
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/// assert_eq!(iter.next().unwrap(), (&10, &100));
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/// assert_eq!(iter.next().unwrap(), (&15, &150));
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/// assert_eq!(iter.next().unwrap(), (&20, &200));
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/// assert!(iter.next().is_none());
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/// }
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///
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/// # Ok::<(), Error>(())
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/// ```
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///
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/// # Invariants
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///
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/// Non-null parent/children pointers stored in instances of the `rb_node` C struct are always
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/// valid, and pointing to a field of our internal representation of a node.
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pub struct RBTree<K, V> {
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root: bindings::rb_root,
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_p: PhantomData<Node<K, V>>,
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}
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// SAFETY: An [`RBTree`] allows the same kinds of access to its values that a struct allows to its
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// fields, so we use the same Send condition as would be used for a struct with K and V fields.
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unsafe impl<K: Send, V: Send> Send for RBTree<K, V> {}
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// SAFETY: An [`RBTree`] allows the same kinds of access to its values that a struct allows to its
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// fields, so we use the same Sync condition as would be used for a struct with K and V fields.
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unsafe impl<K: Sync, V: Sync> Sync for RBTree<K, V> {}
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impl<K, V> RBTree<K, V> {
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/// Creates a new and empty tree.
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pub fn new() -> Self {
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Self {
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// INVARIANT: There are no nodes in the tree, so the invariant holds vacuously.
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root: bindings::rb_root::default(),
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_p: PhantomData,
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}
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}
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/// Returns an iterator over the tree nodes, sorted by key.
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pub fn iter(&self) -> Iter<'_, K, V> {
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Iter {
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_tree: PhantomData,
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// INVARIANT:
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// - `self.root` is a valid pointer to a tree root.
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// - `bindings::rb_first` produces a valid pointer to a node given `root` is valid.
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iter_raw: IterRaw {
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// SAFETY: by the invariants, all pointers are valid.
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next: unsafe { bindings::rb_first(&self.root) },
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_phantom: PhantomData,
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},
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}
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}
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/// Returns a mutable iterator over the tree nodes, sorted by key.
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pub fn iter_mut(&mut self) -> IterMut<'_, K, V> {
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IterMut {
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_tree: PhantomData,
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// INVARIANT:
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// - `self.root` is a valid pointer to a tree root.
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// - `bindings::rb_first` produces a valid pointer to a node given `root` is valid.
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iter_raw: IterRaw {
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// SAFETY: by the invariants, all pointers are valid.
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next: unsafe { bindings::rb_first(from_mut(&mut self.root)) },
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_phantom: PhantomData,
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},
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}
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}
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/// Returns an iterator over the keys of the nodes in the tree, in sorted order.
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pub fn keys(&self) -> impl Iterator<Item = &'_ K> {
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self.iter().map(|(k, _)| k)
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}
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/// Returns an iterator over the values of the nodes in the tree, sorted by key.
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pub fn values(&self) -> impl Iterator<Item = &'_ V> {
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self.iter().map(|(_, v)| v)
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}
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/// Returns a mutable iterator over the values of the nodes in the tree, sorted by key.
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pub fn values_mut(&mut self) -> impl Iterator<Item = &'_ mut V> {
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self.iter_mut().map(|(_, v)| v)
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}
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/// Returns a cursor over the tree nodes, starting with the smallest key.
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pub fn cursor_front(&mut self) -> Option<Cursor<'_, K, V>> {
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let root = addr_of_mut!(self.root);
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// SAFETY: `self.root` is always a valid root node
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let current = unsafe { bindings::rb_first(root) };
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NonNull::new(current).map(|current| {
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// INVARIANT:
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// - `current` is a valid node in the [`RBTree`] pointed to by `self`.
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Cursor {
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current,
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tree: self,
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}
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})
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}
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/// Returns a cursor over the tree nodes, starting with the largest key.
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pub fn cursor_back(&mut self) -> Option<Cursor<'_, K, V>> {
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let root = addr_of_mut!(self.root);
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// SAFETY: `self.root` is always a valid root node
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let current = unsafe { bindings::rb_last(root) };
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NonNull::new(current).map(|current| {
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// INVARIANT:
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// - `current` is a valid node in the [`RBTree`] pointed to by `self`.
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Cursor {
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current,
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tree: self,
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}
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})
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}
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}
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impl<K, V> RBTree<K, V>
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where
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K: Ord,
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{
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/// Tries to insert a new value into the tree.
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///
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/// It overwrites a node if one already exists with the same key and returns it (containing the
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/// key/value pair). Returns [`None`] if a node with the same key didn't already exist.
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///
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/// Returns an error if it cannot allocate memory for the new node.
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pub fn try_create_and_insert(
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&mut self,
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key: K,
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value: V,
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flags: Flags,
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) -> Result<Option<RBTreeNode<K, V>>> {
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Ok(self.insert(RBTreeNode::new(key, value, flags)?))
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}
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/// Inserts a new node into the tree.
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///
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/// It overwrites a node if one already exists with the same key and returns it (containing the
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/// key/value pair). Returns [`None`] if a node with the same key didn't already exist.
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///
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/// This function always succeeds.
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pub fn insert(&mut self, node: RBTreeNode<K, V>) -> Option<RBTreeNode<K, V>> {
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match self.raw_entry(&node.node.key) {
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RawEntry::Occupied(entry) => Some(entry.replace(node)),
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RawEntry::Vacant(entry) => {
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entry.insert(node);
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None
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}
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}
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}
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fn raw_entry(&mut self, key: &K) -> RawEntry<'_, K, V> {
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let raw_self: *mut RBTree<K, V> = self;
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// The returned `RawEntry` is used to call either `rb_link_node` or `rb_replace_node`.
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// The parameters of `bindings::rb_link_node` are as follows:
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// - `node`: A pointer to an uninitialized node being inserted.
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// - `parent`: A pointer to an existing node in the tree. One of its child pointers must be
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// null, and `node` will become a child of `parent` by replacing that child pointer
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// with a pointer to `node`.
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// - `rb_link`: A pointer to either the left-child or right-child field of `parent`. This
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// specifies which child of `parent` should hold `node` after this call. The
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// value of `*rb_link` must be null before the call to `rb_link_node`. If the
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// red/black tree is empty, then it’s also possible for `parent` to be null. In
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// this case, `rb_link` is a pointer to the `root` field of the red/black tree.
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//
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// We will traverse the tree looking for a node that has a null pointer as its child,
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// representing an empty subtree where we can insert our new node. We need to make sure
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// that we preserve the ordering of the nodes in the tree. In each iteration of the loop
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// we store `parent` and `child_field_of_parent`, and the new `node` will go somewhere
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// in the subtree of `parent` that `child_field_of_parent` points at. Once
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// we find an empty subtree, we can insert the new node using `rb_link_node`.
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let mut parent = core::ptr::null_mut();
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let mut child_field_of_parent: &mut *mut bindings::rb_node =
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// SAFETY: `raw_self` is a valid pointer to the `RBTree` (created from `self` above).
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unsafe { &mut (*raw_self).root.rb_node };
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while !(*child_field_of_parent).is_null() {
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let curr = *child_field_of_parent;
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// SAFETY: All links fields we create are in a `Node<K, V>`.
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let node = unsafe { container_of!(curr, Node<K, V>, links) };
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// SAFETY: `node` is a non-null node so it is valid by the type invariants.
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match key.cmp(unsafe { &(*node).key }) {
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// SAFETY: `curr` is a non-null node so it is valid by the type invariants.
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Ordering::Less => child_field_of_parent = unsafe { &mut (*curr).rb_left },
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// SAFETY: `curr` is a non-null node so it is valid by the type invariants.
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Ordering::Greater => child_field_of_parent = unsafe { &mut (*curr).rb_right },
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Ordering::Equal => {
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return RawEntry::Occupied(OccupiedEntry {
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rbtree: self,
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node_links: curr,
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})
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}
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}
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parent = curr;
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}
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RawEntry::Vacant(RawVacantEntry {
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rbtree: raw_self,
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parent,
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child_field_of_parent,
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_phantom: PhantomData,
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})
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}
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/// Gets the given key's corresponding entry in the map for in-place manipulation.
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pub fn entry(&mut self, key: K) -> Entry<'_, K, V> {
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match self.raw_entry(&key) {
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RawEntry::Occupied(entry) => Entry::Occupied(entry),
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RawEntry::Vacant(entry) => Entry::Vacant(VacantEntry { raw: entry, key }),
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}
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}
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/// Used for accessing the given node, if it exists.
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pub fn find_mut(&mut self, key: &K) -> Option<OccupiedEntry<'_, K, V>> {
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match self.raw_entry(key) {
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RawEntry::Occupied(entry) => Some(entry),
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RawEntry::Vacant(_entry) => None,
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}
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}
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/// Returns a reference to the value corresponding to the key.
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pub fn get(&self, key: &K) -> Option<&V> {
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let mut node = self.root.rb_node;
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while !node.is_null() {
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// SAFETY: By the type invariant of `Self`, all non-null `rb_node` pointers stored in `self`
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// point to the links field of `Node<K, V>` objects.
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let this = unsafe { container_of!(node, Node<K, V>, links) };
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// SAFETY: `this` is a non-null node so it is valid by the type invariants.
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node = match key.cmp(unsafe { &(*this).key }) {
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// SAFETY: `node` is a non-null node so it is valid by the type invariants.
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Ordering::Less => unsafe { (*node).rb_left },
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// SAFETY: `node` is a non-null node so it is valid by the type invariants.
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Ordering::Greater => unsafe { (*node).rb_right },
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// SAFETY: `node` is a non-null node so it is valid by the type invariants.
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Ordering::Equal => return Some(unsafe { &(*this).value }),
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}
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}
|
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None
|
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}
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|
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/// Returns a mutable reference to the value corresponding to the key.
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pub fn get_mut(&mut self, key: &K) -> Option<&mut V> {
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self.find_mut(key).map(|node| node.into_mut())
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}
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/// Removes the node with the given key from the tree.
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///
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/// It returns the node that was removed if one exists, or [`None`] otherwise.
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pub fn remove_node(&mut self, key: &K) -> Option<RBTreeNode<K, V>> {
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self.find_mut(key).map(OccupiedEntry::remove_node)
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}
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/// Removes the node with the given key from the tree.
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///
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/// It returns the value that was removed if one exists, or [`None`] otherwise.
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pub fn remove(&mut self, key: &K) -> Option<V> {
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self.find_mut(key).map(OccupiedEntry::remove)
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}
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/// Returns a cursor over the tree nodes based on the given key.
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///
|
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/// If the given key exists, the cursor starts there.
|
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/// Otherwise it starts with the first larger key in sort order.
|
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/// If there is no larger key, it returns [`None`].
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pub fn cursor_lower_bound(&mut self, key: &K) -> Option<Cursor<'_, K, V>>
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where
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K: Ord,
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{
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let mut node = self.root.rb_node;
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let mut best_match: Option<NonNull<Node<K, V>>> = None;
|
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while !node.is_null() {
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// SAFETY: By the type invariant of `Self`, all non-null `rb_node` pointers stored in `self`
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// point to the links field of `Node<K, V>` objects.
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let this = unsafe { container_of!(node, Node<K, V>, links) }.cast_mut();
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// SAFETY: `this` is a non-null node so it is valid by the type invariants.
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let this_key = unsafe { &(*this).key };
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// SAFETY: `node` is a non-null node so it is valid by the type invariants.
|
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let left_child = unsafe { (*node).rb_left };
|
||
// SAFETY: `node` is a non-null node so it is valid by the type invariants.
|
||
let right_child = unsafe { (*node).rb_right };
|
||
match key.cmp(this_key) {
|
||
Ordering::Equal => {
|
||
best_match = NonNull::new(this);
|
||
break;
|
||
}
|
||
Ordering::Greater => {
|
||
node = right_child;
|
||
}
|
||
Ordering::Less => {
|
||
let is_better_match = match best_match {
|
||
None => true,
|
||
Some(best) => {
|
||
// SAFETY: `best` is a non-null node so it is valid by the type invariants.
|
||
let best_key = unsafe { &(*best.as_ptr()).key };
|
||
best_key > this_key
|
||
}
|
||
};
|
||
if is_better_match {
|
||
best_match = NonNull::new(this);
|
||
}
|
||
node = left_child;
|
||
}
|
||
};
|
||
}
|
||
|
||
let best = best_match?;
|
||
|
||
// SAFETY: `best` is a non-null node so it is valid by the type invariants.
|
||
let links = unsafe { addr_of_mut!((*best.as_ptr()).links) };
|
||
|
||
NonNull::new(links).map(|current| {
|
||
// INVARIANT:
|
||
// - `current` is a valid node in the [`RBTree`] pointed to by `self`.
|
||
Cursor {
|
||
current,
|
||
tree: self,
|
||
}
|
||
})
|
||
}
|
||
}
|
||
|
||
impl<K, V> Default for RBTree<K, V> {
|
||
fn default() -> Self {
|
||
Self::new()
|
||
}
|
||
}
|
||
|
||
impl<K, V> Drop for RBTree<K, V> {
|
||
fn drop(&mut self) {
|
||
// SAFETY: `root` is valid as it's embedded in `self` and we have a valid `self`.
|
||
let mut next = unsafe { bindings::rb_first_postorder(&self.root) };
|
||
|
||
// INVARIANT: The loop invariant is that all tree nodes from `next` in postorder are valid.
|
||
while !next.is_null() {
|
||
// SAFETY: All links fields we create are in a `Node<K, V>`.
|
||
let this = unsafe { container_of!(next, Node<K, V>, links) };
|
||
|
||
// Find out what the next node is before disposing of the current one.
|
||
// SAFETY: `next` and all nodes in postorder are still valid.
|
||
next = unsafe { bindings::rb_next_postorder(next) };
|
||
|
||
// INVARIANT: This is the destructor, so we break the type invariant during clean-up,
|
||
// but it is not observable. The loop invariant is still maintained.
|
||
|
||
// SAFETY: `this` is valid per the loop invariant.
|
||
unsafe { drop(KBox::from_raw(this.cast_mut())) };
|
||
}
|
||
}
|
||
}
|
||
|
||
/// A bidirectional cursor over the tree nodes, sorted by key.
|
||
///
|
||
/// # Examples
|
||
///
|
||
/// In the following example, we obtain a cursor to the first element in the tree.
|
||
/// The cursor allows us to iterate bidirectionally over key/value pairs in the tree.
|
||
///
|
||
/// ```
|
||
/// use kernel::{alloc::flags, rbtree::RBTree};
|
||
///
|
||
/// // Create a new tree.
|
||
/// let mut tree = RBTree::new();
|
||
///
|
||
/// // Insert three elements.
|
||
/// tree.try_create_and_insert(10, 100, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(20, 200, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(30, 300, flags::GFP_KERNEL)?;
|
||
///
|
||
/// // Get a cursor to the first element.
|
||
/// let mut cursor = tree.cursor_front().unwrap();
|
||
/// let mut current = cursor.current();
|
||
/// assert_eq!(current, (&10, &100));
|
||
///
|
||
/// // Move the cursor, updating it to the 2nd element.
|
||
/// cursor = cursor.move_next().unwrap();
|
||
/// current = cursor.current();
|
||
/// assert_eq!(current, (&20, &200));
|
||
///
|
||
/// // Peek at the next element without impacting the cursor.
|
||
/// let next = cursor.peek_next().unwrap();
|
||
/// assert_eq!(next, (&30, &300));
|
||
/// current = cursor.current();
|
||
/// assert_eq!(current, (&20, &200));
|
||
///
|
||
/// // Moving past the last element causes the cursor to return [`None`].
|
||
/// cursor = cursor.move_next().unwrap();
|
||
/// current = cursor.current();
|
||
/// assert_eq!(current, (&30, &300));
|
||
/// let cursor = cursor.move_next();
|
||
/// assert!(cursor.is_none());
|
||
///
|
||
/// # Ok::<(), Error>(())
|
||
/// ```
|
||
///
|
||
/// A cursor can also be obtained at the last element in the tree.
|
||
///
|
||
/// ```
|
||
/// use kernel::{alloc::flags, rbtree::RBTree};
|
||
///
|
||
/// // Create a new tree.
|
||
/// let mut tree = RBTree::new();
|
||
///
|
||
/// // Insert three elements.
|
||
/// tree.try_create_and_insert(10, 100, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(20, 200, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(30, 300, flags::GFP_KERNEL)?;
|
||
///
|
||
/// let mut cursor = tree.cursor_back().unwrap();
|
||
/// let current = cursor.current();
|
||
/// assert_eq!(current, (&30, &300));
|
||
///
|
||
/// # Ok::<(), Error>(())
|
||
/// ```
|
||
///
|
||
/// Obtaining a cursor returns [`None`] if the tree is empty.
|
||
///
|
||
/// ```
|
||
/// use kernel::rbtree::RBTree;
|
||
///
|
||
/// let mut tree: RBTree<u16, u16> = RBTree::new();
|
||
/// assert!(tree.cursor_front().is_none());
|
||
///
|
||
/// # Ok::<(), Error>(())
|
||
/// ```
|
||
///
|
||
/// [`RBTree::cursor_lower_bound`] can be used to start at an arbitrary node in the tree.
|
||
///
|
||
/// ```
|
||
/// use kernel::{alloc::flags, rbtree::RBTree};
|
||
///
|
||
/// // Create a new tree.
|
||
/// let mut tree = RBTree::new();
|
||
///
|
||
/// // Insert five elements.
|
||
/// tree.try_create_and_insert(10, 100, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(20, 200, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(30, 300, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(40, 400, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(50, 500, flags::GFP_KERNEL)?;
|
||
///
|
||
/// // If the provided key exists, a cursor to that key is returned.
|
||
/// let cursor = tree.cursor_lower_bound(&20).unwrap();
|
||
/// let current = cursor.current();
|
||
/// assert_eq!(current, (&20, &200));
|
||
///
|
||
/// // If the provided key doesn't exist, a cursor to the first larger element in sort order is returned.
|
||
/// let cursor = tree.cursor_lower_bound(&25).unwrap();
|
||
/// let current = cursor.current();
|
||
/// assert_eq!(current, (&30, &300));
|
||
///
|
||
/// // If there is no larger key, [`None`] is returned.
|
||
/// let cursor = tree.cursor_lower_bound(&55);
|
||
/// assert!(cursor.is_none());
|
||
///
|
||
/// # Ok::<(), Error>(())
|
||
/// ```
|
||
///
|
||
/// The cursor allows mutation of values in the tree.
|
||
///
|
||
/// ```
|
||
/// use kernel::{alloc::flags, rbtree::RBTree};
|
||
///
|
||
/// // Create a new tree.
|
||
/// let mut tree = RBTree::new();
|
||
///
|
||
/// // Insert three elements.
|
||
/// tree.try_create_and_insert(10, 100, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(20, 200, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(30, 300, flags::GFP_KERNEL)?;
|
||
///
|
||
/// // Retrieve a cursor.
|
||
/// let mut cursor = tree.cursor_front().unwrap();
|
||
///
|
||
/// // Get a mutable reference to the current value.
|
||
/// let (k, v) = cursor.current_mut();
|
||
/// *v = 1000;
|
||
///
|
||
/// // The updated value is reflected in the tree.
|
||
/// let updated = tree.get(&10).unwrap();
|
||
/// assert_eq!(updated, &1000);
|
||
///
|
||
/// # Ok::<(), Error>(())
|
||
/// ```
|
||
///
|
||
/// It also allows node removal. The following examples demonstrate the behavior of removing the current node.
|
||
///
|
||
/// ```
|
||
/// use kernel::{alloc::flags, rbtree::RBTree};
|
||
///
|
||
/// // Create a new tree.
|
||
/// let mut tree = RBTree::new();
|
||
///
|
||
/// // Insert three elements.
|
||
/// tree.try_create_and_insert(10, 100, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(20, 200, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(30, 300, flags::GFP_KERNEL)?;
|
||
///
|
||
/// // Remove the first element.
|
||
/// let mut cursor = tree.cursor_front().unwrap();
|
||
/// let mut current = cursor.current();
|
||
/// assert_eq!(current, (&10, &100));
|
||
/// cursor = cursor.remove_current().0.unwrap();
|
||
///
|
||
/// // If a node exists after the current element, it is returned.
|
||
/// current = cursor.current();
|
||
/// assert_eq!(current, (&20, &200));
|
||
///
|
||
/// // Get a cursor to the last element, and remove it.
|
||
/// cursor = tree.cursor_back().unwrap();
|
||
/// current = cursor.current();
|
||
/// assert_eq!(current, (&30, &300));
|
||
///
|
||
/// // Since there is no next node, the previous node is returned.
|
||
/// cursor = cursor.remove_current().0.unwrap();
|
||
/// current = cursor.current();
|
||
/// assert_eq!(current, (&20, &200));
|
||
///
|
||
/// // Removing the last element in the tree returns [`None`].
|
||
/// assert!(cursor.remove_current().0.is_none());
|
||
///
|
||
/// # Ok::<(), Error>(())
|
||
/// ```
|
||
///
|
||
/// Nodes adjacent to the current node can also be removed.
|
||
///
|
||
/// ```
|
||
/// use kernel::{alloc::flags, rbtree::RBTree};
|
||
///
|
||
/// // Create a new tree.
|
||
/// let mut tree = RBTree::new();
|
||
///
|
||
/// // Insert three elements.
|
||
/// tree.try_create_and_insert(10, 100, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(20, 200, flags::GFP_KERNEL)?;
|
||
/// tree.try_create_and_insert(30, 300, flags::GFP_KERNEL)?;
|
||
///
|
||
/// // Get a cursor to the first element.
|
||
/// let mut cursor = tree.cursor_front().unwrap();
|
||
/// let mut current = cursor.current();
|
||
/// assert_eq!(current, (&10, &100));
|
||
///
|
||
/// // Calling `remove_prev` from the first element returns [`None`].
|
||
/// assert!(cursor.remove_prev().is_none());
|
||
///
|
||
/// // Get a cursor to the last element.
|
||
/// cursor = tree.cursor_back().unwrap();
|
||
/// current = cursor.current();
|
||
/// assert_eq!(current, (&30, &300));
|
||
///
|
||
/// // Calling `remove_prev` removes and returns the middle element.
|
||
/// assert_eq!(cursor.remove_prev().unwrap().to_key_value(), (20, 200));
|
||
///
|
||
/// // Calling `remove_next` from the last element returns [`None`].
|
||
/// assert!(cursor.remove_next().is_none());
|
||
///
|
||
/// // Move to the first element
|
||
/// cursor = cursor.move_prev().unwrap();
|
||
/// current = cursor.current();
|
||
/// assert_eq!(current, (&10, &100));
|
||
///
|
||
/// // Calling `remove_next` removes and returns the last element.
|
||
/// assert_eq!(cursor.remove_next().unwrap().to_key_value(), (30, 300));
|
||
///
|
||
/// # Ok::<(), Error>(())
|
||
///
|
||
/// ```
|
||
///
|
||
/// # Invariants
|
||
/// - `current` points to a node that is in the same [`RBTree`] as `tree`.
|
||
pub struct Cursor<'a, K, V> {
|
||
tree: &'a mut RBTree<K, V>,
|
||
current: NonNull<bindings::rb_node>,
|
||
}
|
||
|
||
// SAFETY: The [`Cursor`] has exclusive access to both `K` and `V`, so it is sufficient to require them to be `Send`.
|
||
// The cursor only gives out immutable references to the keys, but since it has excusive access to those same
|
||
// keys, `Send` is sufficient. `Sync` would be okay, but it is more restrictive to the user.
|
||
unsafe impl<'a, K: Send, V: Send> Send for Cursor<'a, K, V> {}
|
||
|
||
// SAFETY: The [`Cursor`] gives out immutable references to K and mutable references to V,
|
||
// so it has the same thread safety requirements as mutable references.
|
||
unsafe impl<'a, K: Sync, V: Sync> Sync for Cursor<'a, K, V> {}
|
||
|
||
impl<'a, K, V> Cursor<'a, K, V> {
|
||
/// The current node
|
||
pub fn current(&self) -> (&K, &V) {
|
||
// SAFETY:
|
||
// - `self.current` is a valid node by the type invariants.
|
||
// - We have an immutable reference by the function signature.
|
||
unsafe { Self::to_key_value(self.current) }
|
||
}
|
||
|
||
/// The current node, with a mutable value
|
||
pub fn current_mut(&mut self) -> (&K, &mut V) {
|
||
// SAFETY:
|
||
// - `self.current` is a valid node by the type invariants.
|
||
// - We have an mutable reference by the function signature.
|
||
unsafe { Self::to_key_value_mut(self.current) }
|
||
}
|
||
|
||
/// Remove the current node from the tree.
|
||
///
|
||
/// Returns a tuple where the first element is a cursor to the next node, if it exists,
|
||
/// else the previous node, else [`None`] (if the tree becomes empty). The second element
|
||
/// is the removed node.
|
||
pub fn remove_current(self) -> (Option<Self>, RBTreeNode<K, V>) {
|
||
let prev = self.get_neighbor_raw(Direction::Prev);
|
||
let next = self.get_neighbor_raw(Direction::Next);
|
||
// SAFETY: By the type invariant of `Self`, all non-null `rb_node` pointers stored in `self`
|
||
// point to the links field of `Node<K, V>` objects.
|
||
let this = unsafe { container_of!(self.current.as_ptr(), Node<K, V>, links) }.cast_mut();
|
||
// SAFETY: `this` is valid by the type invariants as described above.
|
||
let node = unsafe { KBox::from_raw(this) };
|
||
let node = RBTreeNode { node };
|
||
// SAFETY: The reference to the tree used to create the cursor outlives the cursor, so
|
||
// the tree cannot change. By the tree invariant, all nodes are valid.
|
||
unsafe { bindings::rb_erase(&mut (*this).links, addr_of_mut!(self.tree.root)) };
|
||
|
||
let current = match (prev, next) {
|
||
(_, Some(next)) => next,
|
||
(Some(prev), None) => prev,
|
||
(None, None) => {
|
||
return (None, node);
|
||
}
|
||
};
|
||
|
||
(
|
||
// INVARIANT:
|
||
// - `current` is a valid node in the [`RBTree`] pointed to by `self.tree`.
|
||
Some(Self {
|
||
current,
|
||
tree: self.tree,
|
||
}),
|
||
node,
|
||
)
|
||
}
|
||
|
||
/// Remove the previous node, returning it if it exists.
|
||
pub fn remove_prev(&mut self) -> Option<RBTreeNode<K, V>> {
|
||
self.remove_neighbor(Direction::Prev)
|
||
}
|
||
|
||
/// Remove the next node, returning it if it exists.
|
||
pub fn remove_next(&mut self) -> Option<RBTreeNode<K, V>> {
|
||
self.remove_neighbor(Direction::Next)
|
||
}
|
||
|
||
fn remove_neighbor(&mut self, direction: Direction) -> Option<RBTreeNode<K, V>> {
|
||
if let Some(neighbor) = self.get_neighbor_raw(direction) {
|
||
let neighbor = neighbor.as_ptr();
|
||
// SAFETY: The reference to the tree used to create the cursor outlives the cursor, so
|
||
// the tree cannot change. By the tree invariant, all nodes are valid.
|
||
unsafe { bindings::rb_erase(neighbor, addr_of_mut!(self.tree.root)) };
|
||
// SAFETY: By the type invariant of `Self`, all non-null `rb_node` pointers stored in `self`
|
||
// point to the links field of `Node<K, V>` objects.
|
||
let this = unsafe { container_of!(neighbor, Node<K, V>, links) }.cast_mut();
|
||
// SAFETY: `this` is valid by the type invariants as described above.
|
||
let node = unsafe { KBox::from_raw(this) };
|
||
return Some(RBTreeNode { node });
|
||
}
|
||
None
|
||
}
|
||
|
||
/// Move the cursor to the previous node, returning [`None`] if it doesn't exist.
|
||
pub fn move_prev(self) -> Option<Self> {
|
||
self.mv(Direction::Prev)
|
||
}
|
||
|
||
/// Move the cursor to the next node, returning [`None`] if it doesn't exist.
|
||
pub fn move_next(self) -> Option<Self> {
|
||
self.mv(Direction::Next)
|
||
}
|
||
|
||
fn mv(self, direction: Direction) -> Option<Self> {
|
||
// INVARIANT:
|
||
// - `neighbor` is a valid node in the [`RBTree`] pointed to by `self.tree`.
|
||
self.get_neighbor_raw(direction).map(|neighbor| Self {
|
||
tree: self.tree,
|
||
current: neighbor,
|
||
})
|
||
}
|
||
|
||
/// Access the previous node without moving the cursor.
|
||
pub fn peek_prev(&self) -> Option<(&K, &V)> {
|
||
self.peek(Direction::Prev)
|
||
}
|
||
|
||
/// Access the previous node without moving the cursor.
|
||
pub fn peek_next(&self) -> Option<(&K, &V)> {
|
||
self.peek(Direction::Next)
|
||
}
|
||
|
||
fn peek(&self, direction: Direction) -> Option<(&K, &V)> {
|
||
self.get_neighbor_raw(direction).map(|neighbor| {
|
||
// SAFETY:
|
||
// - `neighbor` is a valid tree node.
|
||
// - By the function signature, we have an immutable reference to `self`.
|
||
unsafe { Self::to_key_value(neighbor) }
|
||
})
|
||
}
|
||
|
||
/// Access the previous node mutably without moving the cursor.
|
||
pub fn peek_prev_mut(&mut self) -> Option<(&K, &mut V)> {
|
||
self.peek_mut(Direction::Prev)
|
||
}
|
||
|
||
/// Access the next node mutably without moving the cursor.
|
||
pub fn peek_next_mut(&mut self) -> Option<(&K, &mut V)> {
|
||
self.peek_mut(Direction::Next)
|
||
}
|
||
|
||
fn peek_mut(&mut self, direction: Direction) -> Option<(&K, &mut V)> {
|
||
self.get_neighbor_raw(direction).map(|neighbor| {
|
||
// SAFETY:
|
||
// - `neighbor` is a valid tree node.
|
||
// - By the function signature, we have a mutable reference to `self`.
|
||
unsafe { Self::to_key_value_mut(neighbor) }
|
||
})
|
||
}
|
||
|
||
fn get_neighbor_raw(&self, direction: Direction) -> Option<NonNull<bindings::rb_node>> {
|
||
// SAFETY: `self.current` is valid by the type invariants.
|
||
let neighbor = unsafe {
|
||
match direction {
|
||
Direction::Prev => bindings::rb_prev(self.current.as_ptr()),
|
||
Direction::Next => bindings::rb_next(self.current.as_ptr()),
|
||
}
|
||
};
|
||
|
||
NonNull::new(neighbor)
|
||
}
|
||
|
||
/// # Safety
|
||
///
|
||
/// - `node` must be a valid pointer to a node in an [`RBTree`].
|
||
/// - The caller has immutable access to `node` for the duration of 'b.
|
||
unsafe fn to_key_value<'b>(node: NonNull<bindings::rb_node>) -> (&'b K, &'b V) {
|
||
// SAFETY: the caller guarantees that `node` is a valid pointer in an `RBTree`.
|
||
let (k, v) = unsafe { Self::to_key_value_raw(node) };
|
||
// SAFETY: the caller guarantees immutable access to `node`.
|
||
(k, unsafe { &*v })
|
||
}
|
||
|
||
/// # Safety
|
||
///
|
||
/// - `node` must be a valid pointer to a node in an [`RBTree`].
|
||
/// - The caller has mutable access to `node` for the duration of 'b.
|
||
unsafe fn to_key_value_mut<'b>(node: NonNull<bindings::rb_node>) -> (&'b K, &'b mut V) {
|
||
// SAFETY: the caller guarantees that `node` is a valid pointer in an `RBTree`.
|
||
let (k, v) = unsafe { Self::to_key_value_raw(node) };
|
||
// SAFETY: the caller guarantees mutable access to `node`.
|
||
(k, unsafe { &mut *v })
|
||
}
|
||
|
||
/// # Safety
|
||
///
|
||
/// - `node` must be a valid pointer to a node in an [`RBTree`].
|
||
/// - The caller has immutable access to the key for the duration of 'b.
|
||
unsafe fn to_key_value_raw<'b>(node: NonNull<bindings::rb_node>) -> (&'b K, *mut V) {
|
||
// SAFETY: By the type invariant of `Self`, all non-null `rb_node` pointers stored in `self`
|
||
// point to the links field of `Node<K, V>` objects.
|
||
let this = unsafe { container_of!(node.as_ptr(), Node<K, V>, links) }.cast_mut();
|
||
// SAFETY: The passed `node` is the current node or a non-null neighbor,
|
||
// thus `this` is valid by the type invariants.
|
||
let k = unsafe { &(*this).key };
|
||
// SAFETY: The passed `node` is the current node or a non-null neighbor,
|
||
// thus `this` is valid by the type invariants.
|
||
let v = unsafe { addr_of_mut!((*this).value) };
|
||
(k, v)
|
||
}
|
||
}
|
||
|
||
/// Direction for [`Cursor`] operations.
|
||
enum Direction {
|
||
/// the node immediately before, in sort order
|
||
Prev,
|
||
/// the node immediately after, in sort order
|
||
Next,
|
||
}
|
||
|
||
impl<'a, K, V> IntoIterator for &'a RBTree<K, V> {
|
||
type Item = (&'a K, &'a V);
|
||
type IntoIter = Iter<'a, K, V>;
|
||
|
||
fn into_iter(self) -> Self::IntoIter {
|
||
self.iter()
|
||
}
|
||
}
|
||
|
||
/// An iterator over the nodes of a [`RBTree`].
|
||
///
|
||
/// Instances are created by calling [`RBTree::iter`].
|
||
pub struct Iter<'a, K, V> {
|
||
_tree: PhantomData<&'a RBTree<K, V>>,
|
||
iter_raw: IterRaw<K, V>,
|
||
}
|
||
|
||
// SAFETY: The [`Iter`] gives out immutable references to K and V, so it has the same
|
||
// thread safety requirements as immutable references.
|
||
unsafe impl<'a, K: Sync, V: Sync> Send for Iter<'a, K, V> {}
|
||
|
||
// SAFETY: The [`Iter`] gives out immutable references to K and V, so it has the same
|
||
// thread safety requirements as immutable references.
|
||
unsafe impl<'a, K: Sync, V: Sync> Sync for Iter<'a, K, V> {}
|
||
|
||
impl<'a, K, V> Iterator for Iter<'a, K, V> {
|
||
type Item = (&'a K, &'a V);
|
||
|
||
fn next(&mut self) -> Option<Self::Item> {
|
||
// SAFETY: Due to `self._tree`, `k` and `v` are valid for the lifetime of `'a`.
|
||
self.iter_raw.next().map(|(k, v)| unsafe { (&*k, &*v) })
|
||
}
|
||
}
|
||
|
||
impl<'a, K, V> IntoIterator for &'a mut RBTree<K, V> {
|
||
type Item = (&'a K, &'a mut V);
|
||
type IntoIter = IterMut<'a, K, V>;
|
||
|
||
fn into_iter(self) -> Self::IntoIter {
|
||
self.iter_mut()
|
||
}
|
||
}
|
||
|
||
/// A mutable iterator over the nodes of a [`RBTree`].
|
||
///
|
||
/// Instances are created by calling [`RBTree::iter_mut`].
|
||
pub struct IterMut<'a, K, V> {
|
||
_tree: PhantomData<&'a mut RBTree<K, V>>,
|
||
iter_raw: IterRaw<K, V>,
|
||
}
|
||
|
||
// SAFETY: The [`IterMut`] has exclusive access to both `K` and `V`, so it is sufficient to require them to be `Send`.
|
||
// The iterator only gives out immutable references to the keys, but since the iterator has excusive access to those same
|
||
// keys, `Send` is sufficient. `Sync` would be okay, but it is more restrictive to the user.
|
||
unsafe impl<'a, K: Send, V: Send> Send for IterMut<'a, K, V> {}
|
||
|
||
// SAFETY: The [`IterMut`] gives out immutable references to K and mutable references to V, so it has the same
|
||
// thread safety requirements as mutable references.
|
||
unsafe impl<'a, K: Sync, V: Sync> Sync for IterMut<'a, K, V> {}
|
||
|
||
impl<'a, K, V> Iterator for IterMut<'a, K, V> {
|
||
type Item = (&'a K, &'a mut V);
|
||
|
||
fn next(&mut self) -> Option<Self::Item> {
|
||
self.iter_raw.next().map(|(k, v)|
|
||
// SAFETY: Due to `&mut self`, we have exclusive access to `k` and `v`, for the lifetime of `'a`.
|
||
unsafe { (&*k, &mut *v) })
|
||
}
|
||
}
|
||
|
||
/// A raw iterator over the nodes of a [`RBTree`].
|
||
///
|
||
/// # Invariants
|
||
/// - `self.next` is a valid pointer.
|
||
/// - `self.next` points to a node stored inside of a valid `RBTree`.
|
||
struct IterRaw<K, V> {
|
||
next: *mut bindings::rb_node,
|
||
_phantom: PhantomData<fn() -> (K, V)>,
|
||
}
|
||
|
||
impl<K, V> Iterator for IterRaw<K, V> {
|
||
type Item = (*mut K, *mut V);
|
||
|
||
fn next(&mut self) -> Option<Self::Item> {
|
||
if self.next.is_null() {
|
||
return None;
|
||
}
|
||
|
||
// SAFETY: By the type invariant of `IterRaw`, `self.next` is a valid node in an `RBTree`,
|
||
// and by the type invariant of `RBTree`, all nodes point to the links field of `Node<K, V>` objects.
|
||
let cur = unsafe { container_of!(self.next, Node<K, V>, links) }.cast_mut();
|
||
|
||
// SAFETY: `self.next` is a valid tree node by the type invariants.
|
||
self.next = unsafe { bindings::rb_next(self.next) };
|
||
|
||
// SAFETY: By the same reasoning above, it is safe to dereference the node.
|
||
Some(unsafe { (addr_of_mut!((*cur).key), addr_of_mut!((*cur).value)) })
|
||
}
|
||
}
|
||
|
||
/// A memory reservation for a red-black tree node.
|
||
///
|
||
///
|
||
/// It contains the memory needed to hold a node that can be inserted into a red-black tree. One
|
||
/// can be obtained by directly allocating it ([`RBTreeNodeReservation::new`]).
|
||
pub struct RBTreeNodeReservation<K, V> {
|
||
node: KBox<MaybeUninit<Node<K, V>>>,
|
||
}
|
||
|
||
impl<K, V> RBTreeNodeReservation<K, V> {
|
||
/// Allocates memory for a node to be eventually initialised and inserted into the tree via a
|
||
/// call to [`RBTree::insert`].
|
||
pub fn new(flags: Flags) -> Result<RBTreeNodeReservation<K, V>> {
|
||
Ok(RBTreeNodeReservation {
|
||
node: KBox::new_uninit(flags)?,
|
||
})
|
||
}
|
||
}
|
||
|
||
// SAFETY: This doesn't actually contain K or V, and is just a memory allocation. Those can always
|
||
// be moved across threads.
|
||
unsafe impl<K, V> Send for RBTreeNodeReservation<K, V> {}
|
||
|
||
// SAFETY: This doesn't actually contain K or V, and is just a memory allocation.
|
||
unsafe impl<K, V> Sync for RBTreeNodeReservation<K, V> {}
|
||
|
||
impl<K, V> RBTreeNodeReservation<K, V> {
|
||
/// Initialises a node reservation.
|
||
///
|
||
/// It then becomes an [`RBTreeNode`] that can be inserted into a tree.
|
||
pub fn into_node(self, key: K, value: V) -> RBTreeNode<K, V> {
|
||
let node = KBox::write(
|
||
self.node,
|
||
Node {
|
||
key,
|
||
value,
|
||
links: bindings::rb_node::default(),
|
||
},
|
||
);
|
||
RBTreeNode { node }
|
||
}
|
||
}
|
||
|
||
/// A red-black tree node.
|
||
///
|
||
/// The node is fully initialised (with key and value) and can be inserted into a tree without any
|
||
/// extra allocations or failure paths.
|
||
pub struct RBTreeNode<K, V> {
|
||
node: KBox<Node<K, V>>,
|
||
}
|
||
|
||
impl<K, V> RBTreeNode<K, V> {
|
||
/// Allocates and initialises a node that can be inserted into the tree via
|
||
/// [`RBTree::insert`].
|
||
pub fn new(key: K, value: V, flags: Flags) -> Result<RBTreeNode<K, V>> {
|
||
Ok(RBTreeNodeReservation::new(flags)?.into_node(key, value))
|
||
}
|
||
|
||
/// Get the key and value from inside the node.
|
||
pub fn to_key_value(self) -> (K, V) {
|
||
let node = KBox::into_inner(self.node);
|
||
|
||
(node.key, node.value)
|
||
}
|
||
}
|
||
|
||
// SAFETY: If K and V can be sent across threads, then it's also okay to send [`RBTreeNode`] across
|
||
// threads.
|
||
unsafe impl<K: Send, V: Send> Send for RBTreeNode<K, V> {}
|
||
|
||
// SAFETY: If K and V can be accessed without synchronization, then it's also okay to access
|
||
// [`RBTreeNode`] without synchronization.
|
||
unsafe impl<K: Sync, V: Sync> Sync for RBTreeNode<K, V> {}
|
||
|
||
impl<K, V> RBTreeNode<K, V> {
|
||
/// Drop the key and value, but keep the allocation.
|
||
///
|
||
/// It then becomes a reservation that can be re-initialised into a different node (i.e., with
|
||
/// a different key and/or value).
|
||
///
|
||
/// The existing key and value are dropped in-place as part of this operation, that is, memory
|
||
/// may be freed (but only for the key/value; memory for the node itself is kept for reuse).
|
||
pub fn into_reservation(self) -> RBTreeNodeReservation<K, V> {
|
||
RBTreeNodeReservation {
|
||
node: KBox::drop_contents(self.node),
|
||
}
|
||
}
|
||
}
|
||
|
||
/// A view into a single entry in a map, which may either be vacant or occupied.
|
||
///
|
||
/// This enum is constructed from the [`RBTree::entry`].
|
||
///
|
||
/// [`entry`]: fn@RBTree::entry
|
||
pub enum Entry<'a, K, V> {
|
||
/// This [`RBTree`] does not have a node with this key.
|
||
Vacant(VacantEntry<'a, K, V>),
|
||
/// This [`RBTree`] already has a node with this key.
|
||
Occupied(OccupiedEntry<'a, K, V>),
|
||
}
|
||
|
||
/// Like [`Entry`], except that it doesn't have ownership of the key.
|
||
enum RawEntry<'a, K, V> {
|
||
Vacant(RawVacantEntry<'a, K, V>),
|
||
Occupied(OccupiedEntry<'a, K, V>),
|
||
}
|
||
|
||
/// A view into a vacant entry in a [`RBTree`]. It is part of the [`Entry`] enum.
|
||
pub struct VacantEntry<'a, K, V> {
|
||
key: K,
|
||
raw: RawVacantEntry<'a, K, V>,
|
||
}
|
||
|
||
/// Like [`VacantEntry`], but doesn't hold on to the key.
|
||
///
|
||
/// # Invariants
|
||
/// - `parent` may be null if the new node becomes the root.
|
||
/// - `child_field_of_parent` is a valid pointer to the left-child or right-child of `parent`. If `parent` is
|
||
/// null, it is a pointer to the root of the [`RBTree`].
|
||
struct RawVacantEntry<'a, K, V> {
|
||
rbtree: *mut RBTree<K, V>,
|
||
/// The node that will become the parent of the new node if we insert one.
|
||
parent: *mut bindings::rb_node,
|
||
/// This points to the left-child or right-child field of `parent`, or `root` if `parent` is
|
||
/// null.
|
||
child_field_of_parent: *mut *mut bindings::rb_node,
|
||
_phantom: PhantomData<&'a mut RBTree<K, V>>,
|
||
}
|
||
|
||
impl<'a, K, V> RawVacantEntry<'a, K, V> {
|
||
/// Inserts the given node into the [`RBTree`] at this entry.
|
||
///
|
||
/// The `node` must have a key such that inserting it here does not break the ordering of this
|
||
/// [`RBTree`].
|
||
fn insert(self, node: RBTreeNode<K, V>) -> &'a mut V {
|
||
let node = KBox::into_raw(node.node);
|
||
|
||
// SAFETY: `node` is valid at least until we call `Box::from_raw`, which only happens when
|
||
// the node is removed or replaced.
|
||
let node_links = unsafe { addr_of_mut!((*node).links) };
|
||
|
||
// INVARIANT: We are linking in a new node, which is valid. It remains valid because we
|
||
// "forgot" it with `Box::into_raw`.
|
||
// SAFETY: The type invariants of `RawVacantEntry` are exactly the safety requirements of `rb_link_node`.
|
||
unsafe { bindings::rb_link_node(node_links, self.parent, self.child_field_of_parent) };
|
||
|
||
// SAFETY: All pointers are valid. `node` has just been inserted into the tree.
|
||
unsafe { bindings::rb_insert_color(node_links, addr_of_mut!((*self.rbtree).root)) };
|
||
|
||
// SAFETY: The node is valid until we remove it from the tree.
|
||
unsafe { &mut (*node).value }
|
||
}
|
||
}
|
||
|
||
impl<'a, K, V> VacantEntry<'a, K, V> {
|
||
/// Inserts the given node into the [`RBTree`] at this entry.
|
||
pub fn insert(self, value: V, reservation: RBTreeNodeReservation<K, V>) -> &'a mut V {
|
||
self.raw.insert(reservation.into_node(self.key, value))
|
||
}
|
||
}
|
||
|
||
/// A view into an occupied entry in a [`RBTree`]. It is part of the [`Entry`] enum.
|
||
///
|
||
/// # Invariants
|
||
/// - `node_links` is a valid, non-null pointer to a tree node in `self.rbtree`
|
||
pub struct OccupiedEntry<'a, K, V> {
|
||
rbtree: &'a mut RBTree<K, V>,
|
||
/// The node that this entry corresponds to.
|
||
node_links: *mut bindings::rb_node,
|
||
}
|
||
|
||
impl<'a, K, V> OccupiedEntry<'a, K, V> {
|
||
/// Gets a reference to the value in the entry.
|
||
pub fn get(&self) -> &V {
|
||
// SAFETY:
|
||
// - `self.node_links` is a valid pointer to a node in the tree.
|
||
// - We have shared access to the underlying tree, and can thus give out a shared reference.
|
||
unsafe { &(*container_of!(self.node_links, Node<K, V>, links)).value }
|
||
}
|
||
|
||
/// Gets a mutable reference to the value in the entry.
|
||
pub fn get_mut(&mut self) -> &mut V {
|
||
// SAFETY:
|
||
// - `self.node_links` is a valid pointer to a node in the tree.
|
||
// - We have exclusive access to the underlying tree, and can thus give out a mutable reference.
|
||
unsafe { &mut (*(container_of!(self.node_links, Node<K, V>, links).cast_mut())).value }
|
||
}
|
||
|
||
/// Converts the entry into a mutable reference to its value.
|
||
///
|
||
/// If you need multiple references to the `OccupiedEntry`, see [`self#get_mut`].
|
||
pub fn into_mut(self) -> &'a mut V {
|
||
// SAFETY:
|
||
// - `self.node_links` is a valid pointer to a node in the tree.
|
||
// - This consumes the `&'a mut RBTree<K, V>`, therefore it can give out a mutable reference that lives for `'a`.
|
||
unsafe { &mut (*(container_of!(self.node_links, Node<K, V>, links).cast_mut())).value }
|
||
}
|
||
|
||
/// Remove this entry from the [`RBTree`].
|
||
pub fn remove_node(self) -> RBTreeNode<K, V> {
|
||
// SAFETY: The node is a node in the tree, so it is valid.
|
||
unsafe { bindings::rb_erase(self.node_links, &mut self.rbtree.root) };
|
||
|
||
// INVARIANT: The node is being returned and the caller may free it, however, it was
|
||
// removed from the tree. So the invariants still hold.
|
||
RBTreeNode {
|
||
// SAFETY: The node was a node in the tree, but we removed it, so we can convert it
|
||
// back into a box.
|
||
node: unsafe {
|
||
KBox::from_raw(container_of!(self.node_links, Node<K, V>, links).cast_mut())
|
||
},
|
||
}
|
||
}
|
||
|
||
/// Takes the value of the entry out of the map, and returns it.
|
||
pub fn remove(self) -> V {
|
||
let rb_node = self.remove_node();
|
||
let node = KBox::into_inner(rb_node.node);
|
||
|
||
node.value
|
||
}
|
||
|
||
/// Swap the current node for the provided node.
|
||
///
|
||
/// The key of both nodes must be equal.
|
||
fn replace(self, node: RBTreeNode<K, V>) -> RBTreeNode<K, V> {
|
||
let node = KBox::into_raw(node.node);
|
||
|
||
// SAFETY: `node` is valid at least until we call `Box::from_raw`, which only happens when
|
||
// the node is removed or replaced.
|
||
let new_node_links = unsafe { addr_of_mut!((*node).links) };
|
||
|
||
// SAFETY: This updates the pointers so that `new_node_links` is in the tree where
|
||
// `self.node_links` used to be.
|
||
unsafe {
|
||
bindings::rb_replace_node(self.node_links, new_node_links, &mut self.rbtree.root)
|
||
};
|
||
|
||
// SAFETY:
|
||
// - `self.node_ptr` produces a valid pointer to a node in the tree.
|
||
// - Now that we removed this entry from the tree, we can convert the node to a box.
|
||
let old_node =
|
||
unsafe { KBox::from_raw(container_of!(self.node_links, Node<K, V>, links).cast_mut()) };
|
||
|
||
RBTreeNode { node: old_node }
|
||
}
|
||
}
|
||
|
||
struct Node<K, V> {
|
||
links: bindings::rb_node,
|
||
key: K,
|
||
value: V,
|
||
}
|