// This is an attempt at an implementation following the ideal // // ``` // struct BTreeMap { // height: usize, // root: Option>> // } // // struct Node { // keys: [K; 2 * B - 1], // vals: [V; 2 * B - 1], // edges: [if height > 0 { Box> } else { () }; 2 * B], // parent: Option<(NonNull>, u16)>, // len: u16, // } // ``` // // Since Rust doesn't actually have dependent types and polymorphic recursion, // we make do with lots of unsafety. // A major goal of this module is to avoid complexity by treating the tree as a generic (if // weirdly shaped) container and avoiding dealing with most of the B-Tree invariants. As such, // this module doesn't care whether the entries are sorted, which nodes can be underfull, or // even what underfull means. However, we do rely on a few invariants: // // - Trees must have uniform depth/height. This means that every path down to a leaf from a // given node has exactly the same length. // - A node of length `n` has `n` keys, `n` values, and `n + 1` edges. // This implies that even an empty node has at least one edge. use core::cmp::Ordering; use core::marker::PhantomData; use core::mem::{self, MaybeUninit}; use core::ptr::{self, NonNull, Unique}; use core::slice; use crate::alloc::{AllocRef, Global, Layout}; use crate::boxed::Box; const B: usize = 6; pub const CAPACITY: usize = 2 * B - 1; pub const MIN_LEN_AFTER_SPLIT: usize = B - 1; const KV_IDX_CENTER: usize = B - 1; const EDGE_IDX_LEFT_OF_CENTER: usize = B - 1; const EDGE_IDX_RIGHT_OF_CENTER: usize = B; /// The underlying representation of leaf nodes and part of the representation of internal nodes. struct LeafNode { /// We want to be covariant in `K` and `V`. parent: Option>>, /// This node's index into the parent node's `edges` array. /// `*node.parent.edges[node.parent_idx]` should be the same thing as `node`. /// This is only guaranteed to be initialized when `parent` is non-null. parent_idx: MaybeUninit, /// The number of keys and values this node stores. len: u16, /// The arrays storing the actual data of the node. Only the first `len` elements of each /// array are initialized and valid. keys: [MaybeUninit; CAPACITY], vals: [MaybeUninit; CAPACITY], } impl LeafNode { /// Creates a new `LeafNode`. Unsafe because all nodes should really be hidden behind /// `BoxedNode`, preventing accidental dropping of uninitialized keys and values. unsafe fn new() -> Self { LeafNode { // As a general policy, we leave fields uninitialized if they can be, as this should // be both slightly faster and easier to track in Valgrind. keys: MaybeUninit::uninit_array(), vals: MaybeUninit::uninit_array(), parent: None, parent_idx: MaybeUninit::uninit(), len: 0, } } } /// The underlying representation of internal nodes. As with `LeafNode`s, these should be hidden /// behind `BoxedNode`s to prevent dropping uninitialized keys and values. Any pointer to an /// `InternalNode` can be directly casted to a pointer to the underlying `LeafNode` portion of the /// node, allowing code to act on leaf and internal nodes generically without having to even check /// which of the two a pointer is pointing at. This property is enabled by the use of `repr(C)`. #[repr(C)] // gdb_providers.py uses this type name for introspection. struct InternalNode { data: LeafNode, /// The pointers to the children of this node. `len + 1` of these are considered /// initialized and valid. Although during the process of `into_iter` or `drop`, /// some pointers are dangling while others still need to be traversed. edges: [MaybeUninit>; 2 * B], } impl InternalNode { /// Creates a new `InternalNode`. /// /// This is unsafe for two reasons. First, it returns an `InternalNode` by value, risking /// dropping of uninitialized fields. Second, an invariant of internal nodes is that `len + 1` /// edges are initialized and valid, meaning that even when the node is empty (having a /// `len` of 0), there must be one initialized and valid edge. This function does not set up /// such an edge. unsafe fn new() -> Self { InternalNode { data: unsafe { LeafNode::new() }, edges: MaybeUninit::uninit_array() } } } /// A managed, non-null pointer to a node. This is either an owned pointer to /// `LeafNode` or an owned pointer to `InternalNode`. /// /// However, `BoxedNode` contains no information as to which of the two types /// of nodes it actually contains, and, partially due to this lack of information, /// has no destructor. struct BoxedNode { ptr: Unique>, } impl BoxedNode { fn from_leaf(node: Box>) -> Self { BoxedNode { ptr: Box::into_unique(node).0 } } fn from_internal(node: Box>) -> Self { BoxedNode { ptr: Unique::from(&mut Box::leak(node).data) } } fn as_ptr(&self) -> NonNull> { NonNull::from(self.ptr) } } /// An owned tree. /// /// Note that this does not have a destructor, and must be cleaned up manually. pub struct Root { node: BoxedNode, /// The number of levels below the root node. height: usize, } unsafe impl Sync for Root {} unsafe impl Send for Root {} impl Root { /// Returns the number of levels below the root. pub fn height(&self) -> usize { self.height } /// Returns a new owned tree, with its own root node that is initially empty. pub fn new_leaf() -> Self { Root { node: BoxedNode::from_leaf(Box::new(unsafe { LeafNode::new() })), height: 0 } } /// Borrows and returns an immutable reference to the node owned by the root. pub fn node_as_ref(&self) -> NodeRef, K, V, marker::LeafOrInternal> { NodeRef { height: self.height, node: self.node.as_ptr(), _marker: PhantomData } } /// Borrows and returns a mutable reference to the node owned by the root. pub fn node_as_mut(&mut self) -> NodeRef, K, V, marker::LeafOrInternal> { NodeRef { height: self.height, node: self.node.as_ptr(), _marker: PhantomData } } /// Borrows and returns a mutable reference to the leaf node owned by the root. /// # Safety /// The root node is a leaf. unsafe fn leaf_node_as_mut(&mut self) -> NodeRef, K, V, marker::Leaf> { debug_assert!(self.height == 0); NodeRef { height: self.height, node: self.node.as_ptr(), _marker: PhantomData } } /// Borrows and returns a mutable reference to the internal node owned by the root. /// # Safety /// The root node is not a leaf. unsafe fn internal_node_as_mut(&mut self) -> NodeRef, K, V, marker::Internal> { debug_assert!(self.height > 0); NodeRef { height: self.height, node: self.node.as_ptr(), _marker: PhantomData } } pub fn node_as_valmut(&mut self) -> NodeRef, K, V, marker::LeafOrInternal> { NodeRef { height: self.height, node: self.node.as_ptr(), _marker: PhantomData } } pub fn into_ref(self) -> NodeRef { NodeRef { height: self.height, node: self.node.as_ptr(), _marker: PhantomData } } /// Adds a new internal node with a single edge pointing to the previous root node, /// make that new node the root node, and return it. This increases the height by 1 /// and is the opposite of `pop_internal_level`. pub fn push_internal_level(&mut self) -> NodeRef, K, V, marker::Internal> { let mut new_node = Box::new(unsafe { InternalNode::new() }); new_node.edges[0].write(unsafe { ptr::read(&mut self.node) }); self.node = BoxedNode::from_internal(new_node); self.height += 1; unsafe { let mut ret = self.internal_node_as_mut(); ret.reborrow_mut().first_edge().correct_parent_link(); ret } } /// Removes the internal root node, using its first child as the new root node. /// As it is intended only to be called when the root node has only one child, /// no cleanup is done on any of the other children. /// This decreases the height by 1 and is the opposite of `push_internal_level`. /// /// Requires exclusive access to the `Root` object but not to the root node; /// it will not invalidate existing handles or references to the root node. /// /// Panics if there is no internal level, i.e., if the root node is a leaf. pub fn pop_internal_level(&mut self) { assert!(self.height > 0); let top = self.node.ptr; let mut internal_node = unsafe { self.internal_node_as_mut() }; self.node = unsafe { internal_node.as_internal_mut().edges[0].assume_init_read() }; self.height -= 1; self.node_as_mut().as_leaf_mut().parent = None; unsafe { Global.dealloc(NonNull::from(top).cast(), Layout::new::>()); } } } // N.B. `NodeRef` is always covariant in `K` and `V`, even when the `BorrowType` // is `Mut`. This is technically wrong, but cannot result in any unsafety due to // internal use of `NodeRef` because we stay completely generic over `K` and `V`. // However, whenever a public type wraps `NodeRef`, make sure that it has the // correct variance. /// A reference to a node. /// /// This type has a number of parameters that controls how it acts: /// - `BorrowType`: This can be `Immut<'a>`, `Mut<'a>` or `ValMut<'a>' for some `'a` /// or `Owned`. /// When this is `Immut<'a>`, the `NodeRef` acts roughly like `&'a Node`, /// when this is `Mut<'a>`, the `NodeRef` acts roughly like `&'a mut Node`, /// when this is `ValMut<'a>`, the `NodeRef` acts as immutable with respect /// to keys and tree structure, but allows mutable references to values, /// and when this is `Owned`, the `NodeRef` acts roughly like `Box`. /// - `K` and `V`: These control what types of things are stored in the nodes. /// - `Type`: This can be `Leaf`, `Internal`, or `LeafOrInternal`. When this is /// `Leaf`, the `NodeRef` points to a leaf node, when this is `Internal` the /// `NodeRef` points to an internal node, and when this is `LeafOrInternal` the /// `NodeRef` could be pointing to either type of node. pub struct NodeRef { /// The number of levels below the node, a property of the node that cannot be /// entirely described by `Type` and that the node does not store itself either. /// Unconstrained if `Type` is `LeafOrInternal`, must be zero if `Type` is `Leaf`, /// and must be non-zero if `Type` is `Internal`. height: usize, /// The pointer to the leaf or internal node. The definition of `InternalNode` /// ensures that the pointer is valid either way. node: NonNull>, _marker: PhantomData<(BorrowType, Type)>, } impl<'a, K: 'a, V: 'a, Type> Copy for NodeRef, K, V, Type> {} impl<'a, K: 'a, V: 'a, Type> Clone for NodeRef, K, V, Type> { fn clone(&self) -> Self { *self } } unsafe impl Sync for NodeRef {} unsafe impl<'a, K: Sync + 'a, V: Sync + 'a, Type> Send for NodeRef, K, V, Type> {} unsafe impl<'a, K: Send + 'a, V: Send + 'a, Type> Send for NodeRef, K, V, Type> {} unsafe impl<'a, K: Send + 'a, V: Send + 'a, Type> Send for NodeRef, K, V, Type> {} unsafe impl Send for NodeRef {} impl NodeRef { /// Exposes the data of an internal node for reading. /// /// Returns a raw ptr to avoid invalidating other references to this node, /// which is possible when BorrowType is marker::ValMut. fn as_internal_ptr(&self) -> *const InternalNode { self.node.as_ptr() as *const InternalNode } } impl<'a, K, V> NodeRef, K, V, marker::Internal> { /// Exposes the data of an internal node for reading, /// when we know we have exclusive access. fn as_internal(&mut self) -> &InternalNode { unsafe { &*self.as_internal_ptr() } } } impl<'a, K, V> NodeRef, K, V, marker::Internal> { /// Exposes the data of an internal node for writing. /// /// We don't need to return a raw ptr because we have unique access to the entire node. fn as_internal_mut(&mut self) -> &mut InternalNode { unsafe { &mut *(self.node.as_ptr() as *mut InternalNode) } } } impl NodeRef { /// Finds the length of the node. This is the number of keys or values. /// The number of edges is `len() + 1`. /// Note that, despite being safe, calling this function can have the side effect /// of invalidating mutable references that unsafe code has created. pub fn len(&self) -> usize { // Crucially, we only access the `len` field here. If BorrowType is marker::ValMut, // there might be outstanding mutable references to values that we must not invalidate. unsafe { usize::from((*self.as_leaf_ptr()).len) } } /// Returns the height of this node with respect to the leaf level. Zero height means the /// node is a leaf itself. pub fn height(&self) -> usize { self.height } /// Temporarily takes out another, immutable reference to the same node. fn reborrow(&self) -> NodeRef, K, V, Type> { NodeRef { height: self.height, node: self.node, _marker: PhantomData } } /// Exposes the leaf portion of any leaf or internal node. /// /// Returns a raw ptr to avoid invalidating other references to this node, /// which is possible when BorrowType is marker::ValMut. fn as_leaf_ptr(&self) -> *const LeafNode { // The node must be valid for at least the LeafNode portion. // This is not a reference in the NodeRef type because we don't know if // it should be unique or shared. self.node.as_ptr() } /// Borrows a reference to one of the keys stored in the node. /// /// # Safety /// The node has more than `idx` initialized elements. pub unsafe fn key_at(&self, idx: usize) -> &K { unsafe { self.reborrow().into_key_at(idx) } } /// Borrows a reference to one of the values stored in the node. /// /// # Safety /// The node has more than `idx` initialized elements. unsafe fn val_at(&self, idx: usize) -> &V { unsafe { self.reborrow().into_val_at(idx) } } } impl NodeRef { /// Borrows a reference to the contents of one of the edges that delimit /// the elements of the node, without invalidating other references. /// /// # Safety /// The node has more than `idx` initialized elements. unsafe fn edge_at(&self, idx: usize) -> &BoxedNode { debug_assert!(idx <= self.len()); let node = self.as_internal_ptr(); unsafe { (*node).edges.get_unchecked(idx).assume_init_ref() } } } impl NodeRef { /// Finds the parent of the current node. Returns `Ok(handle)` if the current /// node actually has a parent, where `handle` points to the edge of the parent /// that points to the current node. Returns `Err(self)` if the current node has /// no parent, giving back the original `NodeRef`. /// /// `edge.descend().ascend().unwrap()` and `node.ascend().unwrap().descend()` should /// both, upon success, do nothing. pub fn ascend( self, ) -> Result, marker::Edge>, Self> { // We need to use raw pointers to nodes because, if BorrowType is marker::ValMut, // there might be outstanding mutable references to values that we must not invalidate. let leaf_ptr = self.as_leaf_ptr(); unsafe { (*leaf_ptr).parent } .as_ref() .map(|parent| Handle { node: NodeRef { height: self.height + 1, node: parent.cast(), _marker: PhantomData, }, idx: unsafe { usize::from((*leaf_ptr).parent_idx.assume_init()) }, _marker: PhantomData, }) .ok_or(self) } pub fn first_edge(self) -> Handle { unsafe { Handle::new_edge(self, 0) } } pub fn last_edge(self) -> Handle { let len = self.len(); unsafe { Handle::new_edge(self, len) } } /// Note that `self` must be nonempty. pub fn first_kv(self) -> Handle { let len = self.len(); assert!(len > 0); unsafe { Handle::new_kv(self, 0) } } /// Note that `self` must be nonempty. pub fn last_kv(self) -> Handle { let len = self.len(); assert!(len > 0); unsafe { Handle::new_kv(self, len - 1) } } } impl<'a, K: 'a, V: 'a, Type> NodeRef, K, V, Type> { /// Exposes the data of a leaf node for reading in an immutable tree. fn into_leaf(self) -> &'a LeafNode { // SAFETY: we can access the entire node freely and do no need raw pointers, // because there can be no mutable references to this Immut tree. unsafe { &(*self.as_leaf_ptr()) } } } impl NodeRef { /// Similar to `ascend`, gets a reference to a node's parent node, but also /// deallocate the current node in the process. This is unsafe because the /// current node will still be accessible despite being deallocated. pub unsafe fn deallocate_and_ascend( self, ) -> Option, marker::Edge>> { let height = self.height; let node = self.node; let ret = self.ascend().ok(); unsafe { Global.dealloc( node.cast(), if height > 0 { Layout::new::>() } else { Layout::new::>() }, ); } ret } } impl<'a, K, V, Type> NodeRef, K, V, Type> { /// Unsafely asserts to the compiler the static information that this node is an `Internal`. unsafe fn cast_to_internal_unchecked(self) -> NodeRef, K, V, marker::Internal> { debug_assert!(self.height > 0); NodeRef { height: self.height, node: self.node, _marker: PhantomData } } /// Temporarily takes out another, mutable reference to the same node. Beware, as /// this method is very dangerous, doubly so since it may not immediately appear /// dangerous. /// /// Because mutable pointers can roam anywhere around the tree, the returned /// pointer can easily be used to make the original pointer dangling, out of /// bounds, or invalid under stacked borrow rules. // FIXME(@gereeter) consider adding yet another type parameter to `NodeRef` // that restricts the use of navigation methods on reborrowed pointers, // preventing this unsafety. unsafe fn reborrow_mut(&mut self) -> NodeRef, K, V, Type> { NodeRef { height: self.height, node: self.node, _marker: PhantomData } } /// Exposes the leaf portion of any leaf or internal node for writing. /// /// We don't need to return a raw ptr because we have unique access to the entire node. fn as_leaf_mut(&mut self) -> &'a mut LeafNode { unsafe { &mut (*self.node.as_ptr()) } } /// Borrows a mutable reference to one of the keys stored in the node. /// /// # Safety /// The node has more than `idx` initialized elements. unsafe fn key_mut_at(&mut self, idx: usize) -> &mut K { unsafe { self.reborrow_mut().into_key_mut_at(idx) } } /// Borrows a mutable reference to one of the values stored in the node. /// /// # Safety /// The node has more than `idx` initialized elements. unsafe fn val_mut_at(&mut self, idx: usize) -> &mut V { unsafe { self.reborrow_mut().into_val_mut_at(idx) } } fn keys_mut(&mut self) -> &mut [K] where K: 'a, V: 'a, { // SAFETY: the caller will not be able to call further methods on self // until the key slice reference is dropped, as we have unique access // for the lifetime of the borrow. // SAFETY: The keys of a node must always be initialized up to length. unsafe { slice::from_raw_parts_mut( MaybeUninit::slice_as_mut_ptr(&mut self.as_leaf_mut().keys), self.len(), ) } } fn vals_mut(&mut self) -> &mut [V] where K: 'a, V: 'a, { // SAFETY: the caller will not be able to call further methods on self // until the value slice reference is dropped, as we have unique access // for the lifetime of the borrow. // SAFETY: The values of a node must always be initialized up to length. unsafe { slice::from_raw_parts_mut( MaybeUninit::slice_as_mut_ptr(&mut self.as_leaf_mut().vals), self.len(), ) } } } impl<'a, K, V> NodeRef, K, V, marker::Internal> { fn edges_mut(&mut self) -> &mut [BoxedNode] { unsafe { slice::from_raw_parts_mut( MaybeUninit::slice_as_mut_ptr(&mut self.as_internal_mut().edges), self.len() + 1, ) } } } impl<'a, K: 'a, V: 'a, Type> NodeRef, K, V, Type> { /// # Safety /// The node has more than `idx` initialized elements. unsafe fn into_key_at(self, idx: usize) -> &'a K { unsafe { self.into_leaf().keys.get_unchecked(idx).assume_init_ref() } } /// # Safety /// The node has more than `idx` initialized elements. unsafe fn into_val_at(self, idx: usize) -> &'a V { unsafe { self.into_leaf().vals.get_unchecked(idx).assume_init_ref() } } } impl<'a, K: 'a, V: 'a, Type> NodeRef, K, V, Type> { /// # Safety /// The node has more than `idx` initialized elements. unsafe fn into_key_mut_at(mut self, idx: usize) -> &'a mut K { debug_assert!(idx < self.len()); let leaf = self.as_leaf_mut(); unsafe { leaf.keys.get_unchecked_mut(idx).assume_init_mut() } } /// # Safety /// The node has more than `idx` initialized elements. unsafe fn into_val_mut_at(mut self, idx: usize) -> &'a mut V { debug_assert!(idx < self.len()); let leaf = self.as_leaf_mut(); unsafe { leaf.vals.get_unchecked_mut(idx).assume_init_mut() } } } impl<'a, K, V, Type> NodeRef, K, V, Type> { /// # Safety /// The node has more than `idx` initialized elements. unsafe fn into_key_val_mut_at(self, idx: usize) -> (&'a K, &'a mut V) { // We only create a reference to the one element we are interested in, // to avoid aliasing with outstanding references to other elements, // in particular, those returned to the caller in earlier iterations. let leaf = self.node.as_ptr(); let keys = unsafe { &raw const (*leaf).keys }; let vals = unsafe { &raw mut (*leaf).vals }; // We must coerce to unsized array pointers because of Rust issue #74679. let keys: *const [_] = keys; let vals: *mut [_] = vals; // SAFETY: The keys and values of a node must always be initialized up to length. let key = unsafe { (&*keys.get_unchecked(idx)).assume_init_ref() }; let val = unsafe { (&mut *vals.get_unchecked_mut(idx)).assume_init_mut() }; (key, val) } } impl<'a, K: 'a, V: 'a> NodeRef, K, V, marker::Leaf> { /// Adds a key/value pair to the end of the node. pub fn push(&mut self, key: K, val: V) { let len = &mut self.as_leaf_mut().len; let idx = usize::from(*len); assert!(idx < CAPACITY); *len += 1; unsafe { ptr::write(self.key_mut_at(idx), key); ptr::write(self.val_mut_at(idx), val); } } /// Adds a key/value pair to the beginning of the node. fn push_front(&mut self, key: K, val: V) { assert!(self.len() < CAPACITY); unsafe { slice_insert(self.keys_mut(), 0, key); slice_insert(self.vals_mut(), 0, val); } self.as_leaf_mut().len += 1; } } impl<'a, K, V> NodeRef, K, V, marker::Internal> { /// # Safety /// Every item returned by `range` is a valid edge index for the node. unsafe fn correct_childrens_parent_links>(&mut self, range: R) { for i in range { debug_assert!(i <= self.len()); unsafe { Handle::new_edge(self.reborrow_mut(), i) }.correct_parent_link(); } } fn correct_all_childrens_parent_links(&mut self) { let len = self.len(); unsafe { self.correct_childrens_parent_links(0..=len) }; } } impl<'a, K: 'a, V: 'a> NodeRef, K, V, marker::Internal> { /// Adds a key/value pair, and an edge to go to the right of that pair, /// to the end of the node. pub fn push(&mut self, key: K, val: V, edge: Root) { assert!(edge.height == self.height - 1); let len = &mut self.as_leaf_mut().len; let idx = usize::from(*len); assert!(idx < CAPACITY); *len += 1; unsafe { ptr::write(self.key_mut_at(idx), key); ptr::write(self.val_mut_at(idx), val); self.as_internal_mut().edges.get_unchecked_mut(idx + 1).write(edge.node); Handle::new_edge(self.reborrow_mut(), idx + 1).correct_parent_link(); } } /// Adds a key/value pair, and an edge to go to the left of that pair, /// to the beginning of the node. fn push_front(&mut self, key: K, val: V, edge: Root) { assert!(edge.height == self.height - 1); assert!(self.len() < CAPACITY); unsafe { slice_insert(self.keys_mut(), 0, key); slice_insert(self.vals_mut(), 0, val); slice_insert(self.edges_mut(), 0, edge.node); } self.as_leaf_mut().len += 1; self.correct_all_childrens_parent_links(); } } impl<'a, K: 'a, V: 'a> NodeRef, K, V, marker::LeafOrInternal> { /// Removes a key/value pair from the end of the node and returns the pair. /// Also removes the edge that was to the right of that pair and, if the node /// is internal, returns the orphaned subtree that this edge owned. fn pop(&mut self) -> (K, V, Option>) { debug_assert!(self.len() > 0); let idx = self.len() - 1; unsafe { let key = ptr::read(self.key_at(idx)); let val = ptr::read(self.val_at(idx)); let edge = match self.reborrow_mut().force() { ForceResult::Leaf(_) => None, ForceResult::Internal(internal) => { let edge = ptr::read(internal.edge_at(idx + 1)); let mut new_root = Root { node: edge, height: internal.height - 1 }; new_root.node_as_mut().as_leaf_mut().parent = None; Some(new_root) } }; self.as_leaf_mut().len -= 1; (key, val, edge) } } /// Removes a key/value pair from the beginning of the node and returns the pair. /// Also removes the edge that was to the left of that pair and, if the node is /// internal, returns the orphaned subtree that this edge owned. fn pop_front(&mut self) -> (K, V, Option>) { debug_assert!(self.len() > 0); let old_len = self.len(); unsafe { let key = slice_remove(self.keys_mut(), 0); let val = slice_remove(self.vals_mut(), 0); let edge = match self.reborrow_mut().force() { ForceResult::Leaf(_) => None, ForceResult::Internal(mut internal) => { let edge = slice_remove(internal.edges_mut(), 0); let mut new_root = Root { node: edge, height: internal.height - 1 }; new_root.node_as_mut().as_leaf_mut().parent = None; internal.correct_childrens_parent_links(0..old_len); Some(new_root) } }; self.as_leaf_mut().len -= 1; (key, val, edge) } } fn into_kv_pointers_mut(mut self) -> (*mut K, *mut V) { (self.keys_mut().as_mut_ptr(), self.vals_mut().as_mut_ptr()) } } impl NodeRef { /// Checks whether a node is an `Internal` node or a `Leaf` node. pub fn force( self, ) -> ForceResult< NodeRef, NodeRef, > { if self.height == 0 { ForceResult::Leaf(NodeRef { height: self.height, node: self.node, _marker: PhantomData, }) } else { ForceResult::Internal(NodeRef { height: self.height, node: self.node, _marker: PhantomData, }) } } } /// A reference to a specific key/value pair or edge within a node. The `Node` parameter /// must be a `NodeRef`, while the `Type` can either be `KV` (signifying a handle on a key/value /// pair) or `Edge` (signifying a handle on an edge). /// /// Note that even `Leaf` nodes can have `Edge` handles. Instead of representing a pointer to /// a child node, these represent the spaces where child pointers would go between the key/value /// pairs. For example, in a node with length 2, there would be 3 possible edge locations - one /// to the left of the node, one between the two pairs, and one at the right of the node. pub struct Handle { node: Node, idx: usize, _marker: PhantomData, } impl Copy for Handle {} // We don't need the full generality of `#[derive(Clone)]`, as the only time `Node` will be // `Clone`able is when it is an immutable reference and therefore `Copy`. impl Clone for Handle { fn clone(&self) -> Self { *self } } impl Handle { /// Retrieves the node that contains the edge or key/value pair this handle points to. pub fn into_node(self) -> Node { self.node } /// Returns the position of this handle in the node. pub fn idx(&self) -> usize { self.idx } } impl Handle, marker::KV> { /// Creates a new handle to a key/value pair in `node`. /// Unsafe because the caller must ensure that `idx < node.len()`. pub unsafe fn new_kv(node: NodeRef, idx: usize) -> Self { debug_assert!(idx < node.len()); Handle { node, idx, _marker: PhantomData } } pub fn left_edge(self) -> Handle, marker::Edge> { unsafe { Handle::new_edge(self.node, self.idx) } } pub fn right_edge(self) -> Handle, marker::Edge> { unsafe { Handle::new_edge(self.node, self.idx + 1) } } } impl NodeRef { /// Could be a public implementation of PartialEq, but only used in this module. fn eq(&self, other: &Self) -> bool { let Self { node, height, _marker: _ } = self; if *node == other.node { debug_assert_eq!(*height, other.height); true } else { false } } } impl PartialEq for Handle, HandleType> { fn eq(&self, other: &Self) -> bool { let Self { node, idx, _marker: _ } = self; node.eq(&other.node) && *idx == other.idx } } impl PartialOrd for Handle, HandleType> { fn partial_cmp(&self, other: &Self) -> Option { let Self { node, idx, _marker: _ } = self; if node.eq(&other.node) { Some(idx.cmp(&other.idx)) } else { None } } } impl Handle, HandleType> { /// Temporarily takes out another, immutable handle on the same location. pub fn reborrow(&self) -> Handle, K, V, NodeType>, HandleType> { // We can't use Handle::new_kv or Handle::new_edge because we don't know our type Handle { node: self.node.reborrow(), idx: self.idx, _marker: PhantomData } } } impl<'a, K, V, NodeType, HandleType> Handle, K, V, NodeType>, HandleType> { /// Temporarily takes out another, mutable handle on the same location. Beware, as /// this method is very dangerous, doubly so since it may not immediately appear /// dangerous. /// /// For details, see `NodeRef::reborrow_mut`. pub unsafe fn reborrow_mut( &mut self, ) -> Handle, K, V, NodeType>, HandleType> { // We can't use Handle::new_kv or Handle::new_edge because we don't know our type Handle { node: unsafe { self.node.reborrow_mut() }, idx: self.idx, _marker: PhantomData } } } impl Handle, marker::Edge> { /// Creates a new handle to an edge in `node`. /// Unsafe because the caller must ensure that `idx <= node.len()`. pub unsafe fn new_edge(node: NodeRef, idx: usize) -> Self { debug_assert!(idx <= node.len()); Handle { node, idx, _marker: PhantomData } } pub fn left_kv(self) -> Result, marker::KV>, Self> { if self.idx > 0 { Ok(unsafe { Handle::new_kv(self.node, self.idx - 1) }) } else { Err(self) } } pub fn right_kv(self) -> Result, marker::KV>, Self> { if self.idx < self.node.len() { Ok(unsafe { Handle::new_kv(self.node, self.idx) }) } else { Err(self) } } } enum InsertionPlace { Left(usize), Right(usize), } /// Given an edge index where we want to insert into a node filled to capacity, /// computes a sensible KV index of a split point and where to perform the insertion. /// The goal of the split point is for its key and value to end up in a parent node; /// the keys, values and edges to the left of the split point become the left child; /// the keys, values and edges to the right of the split point become the right child. fn splitpoint(edge_idx: usize) -> (usize, InsertionPlace) { debug_assert!(edge_idx <= CAPACITY); // Rust issue #74834 tries to explain these symmetric rules. match edge_idx { 0..EDGE_IDX_LEFT_OF_CENTER => (KV_IDX_CENTER - 1, InsertionPlace::Left(edge_idx)), EDGE_IDX_LEFT_OF_CENTER => (KV_IDX_CENTER, InsertionPlace::Left(edge_idx)), EDGE_IDX_RIGHT_OF_CENTER => (KV_IDX_CENTER, InsertionPlace::Right(0)), _ => (KV_IDX_CENTER + 1, InsertionPlace::Right(edge_idx - (KV_IDX_CENTER + 1 + 1))), } } impl<'a, K: 'a, V: 'a> Handle, K, V, marker::Leaf>, marker::Edge> { /// Inserts a new key/value pair between the key/value pairs to the right and left of /// this edge. This method assumes that there is enough space in the node for the new /// pair to fit. /// /// The returned pointer points to the inserted value. fn insert_fit(&mut self, key: K, val: V) -> *mut V { debug_assert!(self.node.len() < CAPACITY); unsafe { slice_insert(self.node.keys_mut(), self.idx, key); slice_insert(self.node.vals_mut(), self.idx, val); self.node.as_leaf_mut().len += 1; self.node.val_mut_at(self.idx) } } } impl<'a, K: 'a, V: 'a> Handle, K, V, marker::Leaf>, marker::Edge> { /// Inserts a new key/value pair between the key/value pairs to the right and left of /// this edge. This method splits the node if there isn't enough room. /// /// The returned pointer points to the inserted value. fn insert(mut self, key: K, val: V) -> (InsertResult<'a, K, V, marker::Leaf>, *mut V) { if self.node.len() < CAPACITY { let val_ptr = self.insert_fit(key, val); let kv = unsafe { Handle::new_kv(self.node, self.idx) }; (InsertResult::Fit(kv), val_ptr) } else { let (middle_kv_idx, insertion) = splitpoint(self.idx); let middle = unsafe { Handle::new_kv(self.node, middle_kv_idx) }; let (mut left, k, v, mut right) = middle.split(); let mut insertion_edge = match insertion { InsertionPlace::Left(insert_idx) => unsafe { Handle::new_edge(left.reborrow_mut(), insert_idx) }, InsertionPlace::Right(insert_idx) => unsafe { Handle::new_edge(right.leaf_node_as_mut(), insert_idx) }, }; let val_ptr = insertion_edge.insert_fit(key, val); (InsertResult::Split(SplitResult { left: left.forget_type(), k, v, right }), val_ptr) } } } impl<'a, K, V> Handle, K, V, marker::Internal>, marker::Edge> { /// Fixes the parent pointer and index in the child node below this edge. This is useful /// when the ordering of edges has been changed, such as in the various `insert` methods. fn correct_parent_link(mut self) { let idx = self.idx as u16; let ptr = NonNull::new(self.node.as_internal_mut()); let mut child = self.descend(); child.as_leaf_mut().parent = ptr; child.as_leaf_mut().parent_idx.write(idx); } } impl<'a, K: 'a, V: 'a> Handle, K, V, marker::Internal>, marker::Edge> { /// Inserts a new key/value pair and an edge that will go to the right of that new pair /// between this edge and the key/value pair to the right of this edge. This method assumes /// that there is enough space in the node for the new pair to fit. fn insert_fit(&mut self, key: K, val: V, edge: Root) { debug_assert!(self.node.len() < CAPACITY); debug_assert!(edge.height == self.node.height - 1); unsafe { slice_insert(self.node.keys_mut(), self.idx, key); slice_insert(self.node.vals_mut(), self.idx, val); slice_insert(self.node.edges_mut(), self.idx + 1, edge.node); self.node.as_leaf_mut().len += 1; self.node.correct_childrens_parent_links((self.idx + 1)..=self.node.len()); } } /// Inserts a new key/value pair and an edge that will go to the right of that new pair /// between this edge and the key/value pair to the right of this edge. This method splits /// the node if there isn't enough room. fn insert( mut self, key: K, val: V, edge: Root, ) -> InsertResult<'a, K, V, marker::Internal> { assert!(edge.height == self.node.height - 1); if self.node.len() < CAPACITY { self.insert_fit(key, val, edge); let kv = unsafe { Handle::new_kv(self.node, self.idx) }; InsertResult::Fit(kv) } else { let (middle_kv_idx, insertion) = splitpoint(self.idx); let middle = unsafe { Handle::new_kv(self.node, middle_kv_idx) }; let (mut left, k, v, mut right) = middle.split(); let mut insertion_edge = match insertion { InsertionPlace::Left(insert_idx) => unsafe { Handle::new_edge(left.reborrow_mut(), insert_idx) }, InsertionPlace::Right(insert_idx) => unsafe { Handle::new_edge(right.internal_node_as_mut(), insert_idx) }, }; insertion_edge.insert_fit(key, val, edge); InsertResult::Split(SplitResult { left: left.forget_type(), k, v, right }) } } } impl<'a, K: 'a, V: 'a> Handle, K, V, marker::Leaf>, marker::Edge> { /// Inserts a new key/value pair between the key/value pairs to the right and left of /// this edge. This method splits the node if there isn't enough room, and tries to /// insert the split off portion into the parent node recursively, until the root is reached. /// /// If the returned result is a `Fit`, its handle's node can be this edge's node or an ancestor. /// If the returned result is a `Split`, the `left` field will be the root node. /// The returned pointer points to the inserted value. pub fn insert_recursing( self, key: K, value: V, ) -> (InsertResult<'a, K, V, marker::LeafOrInternal>, *mut V) { let (mut split, val_ptr) = match self.insert(key, value) { (InsertResult::Fit(handle), ptr) => { return (InsertResult::Fit(handle.forget_node_type()), ptr); } (InsertResult::Split(split), val_ptr) => (split, val_ptr), }; loop { split = match split.left.ascend() { Ok(parent) => match parent.insert(split.k, split.v, split.right) { InsertResult::Fit(handle) => { return (InsertResult::Fit(handle.forget_node_type()), val_ptr); } InsertResult::Split(split) => split, }, Err(root) => { return (InsertResult::Split(SplitResult { left: root, ..split }), val_ptr); } }; } } } impl Handle, marker::Edge> { /// Finds the node pointed to by this edge. /// /// `edge.descend().ascend().unwrap()` and `node.ascend().unwrap().descend()` should /// both, upon success, do nothing. pub fn descend(self) -> NodeRef { // We need to use raw pointers to nodes because, if BorrowType is // marker::ValMut, there might be outstanding mutable references to // values that we must not invalidate. There's no worry accessing the // height field because that value is copied. Beware that, once the // node pointer is dereferenced, we access the edges array with a // reference (Rust issue #73987) and invalidate any other references // to or inside the array, should any be around. let internal_node = self.node.as_internal_ptr(); NodeRef { height: self.node.height - 1, node: unsafe { (&*(*internal_node).edges.get_unchecked(self.idx).as_ptr()).as_ptr() }, _marker: PhantomData, } } } impl<'a, K: 'a, V: 'a, NodeType> Handle, K, V, NodeType>, marker::KV> { pub fn into_kv(self) -> (&'a K, &'a V) { (unsafe { self.node.into_key_at(self.idx) }, unsafe { self.node.into_val_at(self.idx) }) } } impl<'a, K: 'a, V: 'a, NodeType> Handle, K, V, NodeType>, marker::KV> { pub fn into_key_mut(self) -> &'a mut K { unsafe { self.node.into_key_mut_at(self.idx) } } pub fn into_val_mut(self) -> &'a mut V { unsafe { self.node.into_val_mut_at(self.idx) } } } impl<'a, K, V, NodeType> Handle, K, V, NodeType>, marker::KV> { pub fn into_kv_valmut(self) -> (&'a K, &'a mut V) { unsafe { self.node.into_key_val_mut_at(self.idx) } } } impl<'a, K: 'a, V: 'a, NodeType> Handle, K, V, NodeType>, marker::KV> { pub fn kv_mut(&mut self) -> (&mut K, &mut V) { // We cannot call into_key_mut_at and into_val_mut_at, because calling the second one // invalidates the reference returned by the first. let leaf = self.node.as_leaf_mut(); let key = unsafe { leaf.keys.get_unchecked_mut(self.idx).assume_init_mut() }; let val = unsafe { leaf.vals.get_unchecked_mut(self.idx).assume_init_mut() }; (key, val) } } impl<'a, K: 'a, V: 'a, NodeType> Handle, K, V, NodeType>, marker::KV> { /// Helps implementations of `split` for a particular `NodeType`, /// by calculating the length of the new node. fn split_new_node_len(&self) -> usize { debug_assert!(self.idx < self.node.len()); self.node.len() - self.idx - 1 } /// Helps implementations of `split` for a particular `NodeType`, /// by taking care of leaf data. fn split_leaf_data(&mut self, new_node: &mut LeafNode) -> (K, V) { let new_len = self.split_new_node_len(); unsafe { let k = ptr::read(self.node.key_at(self.idx)); let v = ptr::read(self.node.val_at(self.idx)); ptr::copy_nonoverlapping( self.node.key_at(self.idx + 1), MaybeUninit::slice_as_mut_ptr(&mut new_node.keys), new_len, ); ptr::copy_nonoverlapping( self.node.val_at(self.idx + 1), MaybeUninit::slice_as_mut_ptr(&mut new_node.vals), new_len, ); self.node.as_leaf_mut().len = self.idx as u16; new_node.len = new_len as u16; (k, v) } } } impl<'a, K: 'a, V: 'a> Handle, K, V, marker::Leaf>, marker::KV> { /// Splits the underlying node into three parts: /// /// - The node is truncated to only contain the key/value pairs to the left of /// this handle. /// - The key and value pointed to by this handle are extracted. /// - All the key/value pairs to the right of this handle are put into a newly /// allocated node. pub fn split(mut self) -> (NodeRef, K, V, marker::Leaf>, K, V, Root) { unsafe { let mut new_node = Box::new(LeafNode::new()); let (k, v) = self.split_leaf_data(&mut new_node); let right = Root { node: BoxedNode::from_leaf(new_node), height: 0 }; (self.node, k, v, right) } } /// Removes the key/value pair pointed to by this handle and returns it, along with the edge /// that the key/value pair collapsed into. pub fn remove( mut self, ) -> ((K, V), Handle, K, V, marker::Leaf>, marker::Edge>) { unsafe { let k = slice_remove(self.node.keys_mut(), self.idx); let v = slice_remove(self.node.vals_mut(), self.idx); self.node.as_leaf_mut().len -= 1; ((k, v), self.left_edge()) } } } impl<'a, K, V> Handle, K, V, marker::Internal>, marker::KV> { /// Returns `true` if it is valid to call `.merge()`, i.e., whether there is enough room in /// a node to hold the combination of the nodes to the left and right of this handle along /// with the key/value pair at this handle. pub fn can_merge(&self) -> bool { (self.reborrow().left_edge().descend().len() + self.reborrow().right_edge().descend().len() + 1) <= CAPACITY } } impl<'a, K: 'a, V: 'a> Handle, K, V, marker::Internal>, marker::KV> { /// Splits the underlying node into three parts: /// /// - The node is truncated to only contain the edges and key/value pairs to the /// left of this handle. /// - The key and value pointed to by this handle are extracted. /// - All the edges and key/value pairs to the right of this handle are put into /// a newly allocated node. pub fn split(mut self) -> (NodeRef, K, V, marker::Internal>, K, V, Root) { unsafe { let mut new_node = Box::new(InternalNode::new()); // Move edges out before reducing length: let new_len = self.split_new_node_len(); ptr::copy_nonoverlapping( self.node.edge_at(self.idx + 1), MaybeUninit::slice_as_mut_ptr(&mut new_node.edges), new_len + 1, ); let (k, v) = self.split_leaf_data(&mut new_node.data); let height = self.node.height; let mut right = Root { node: BoxedNode::from_internal(new_node), height }; right.internal_node_as_mut().correct_childrens_parent_links(0..=new_len); (self.node, k, v, right) } } /// Combines the node immediately to the left of this handle, the key/value pair pointed /// to by this handle, and the node immediately to the right of this handle into one new /// child of the underlying node, returning an edge referencing that new child. /// /// Panics unless this edge `.can_merge()`. pub fn merge( mut self, ) -> Handle, K, V, marker::Internal>, marker::Edge> { let self1 = unsafe { ptr::read(&self) }; let self2 = unsafe { ptr::read(&self) }; let mut left_node = self1.left_edge().descend(); let left_len = left_node.len(); let right_node = self2.right_edge().descend(); let right_len = right_node.len(); assert!(left_len + right_len < CAPACITY); unsafe { ptr::write( left_node.keys_mut().get_unchecked_mut(left_len), slice_remove(self.node.keys_mut(), self.idx), ); ptr::copy_nonoverlapping( right_node.key_at(0), left_node.keys_mut().as_mut_ptr().add(left_len + 1), right_len, ); ptr::write( left_node.vals_mut().get_unchecked_mut(left_len), slice_remove(self.node.vals_mut(), self.idx), ); ptr::copy_nonoverlapping( right_node.val_at(0), left_node.vals_mut().as_mut_ptr().add(left_len + 1), right_len, ); slice_remove(&mut self.node.edges_mut(), self.idx + 1); let self_len = self.node.len(); self.node.correct_childrens_parent_links(self.idx + 1..self_len); self.node.as_leaf_mut().len -= 1; left_node.as_leaf_mut().len += right_len as u16 + 1; if self.node.height > 1 { // SAFETY: the height of the nodes being merged is one below the height // of the node of this edge, thus above zero, so they are internal. let mut left_node = left_node.cast_to_internal_unchecked(); let right_node = right_node.cast_to_internal_unchecked(); ptr::copy_nonoverlapping( right_node.edge_at(0), left_node.edges_mut().as_mut_ptr().add(left_len + 1), right_len + 1, ); left_node.correct_childrens_parent_links(left_len + 1..=left_len + 1 + right_len); Global.dealloc(right_node.node.cast(), Layout::new::>()); } else { Global.dealloc(right_node.node.cast(), Layout::new::>()); } Handle::new_edge(self.node, self.idx) } } /// This removes a key/value pair from the left child and places it in the key/value storage /// pointed to by this handle while pushing the old key/value pair of this handle into the right /// child. pub fn steal_left(&mut self) { unsafe { let (k, v, edge) = self.reborrow_mut().left_edge().descend().pop(); let k = mem::replace(self.kv_mut().0, k); let v = mem::replace(self.kv_mut().1, v); match self.reborrow_mut().right_edge().descend().force() { ForceResult::Leaf(mut leaf) => leaf.push_front(k, v), ForceResult::Internal(mut internal) => internal.push_front(k, v, edge.unwrap()), } } } /// This removes a key/value pair from the right child and places it in the key/value storage /// pointed to by this handle while pushing the old key/value pair of this handle into the left /// child. pub fn steal_right(&mut self) { unsafe { let (k, v, edge) = self.reborrow_mut().right_edge().descend().pop_front(); let k = mem::replace(self.kv_mut().0, k); let v = mem::replace(self.kv_mut().1, v); match self.reborrow_mut().left_edge().descend().force() { ForceResult::Leaf(mut leaf) => leaf.push(k, v), ForceResult::Internal(mut internal) => internal.push(k, v, edge.unwrap()), } } } /// This does stealing similar to `steal_left` but steals multiple elements at once. pub fn bulk_steal_left(&mut self, count: usize) { unsafe { let mut left_node = ptr::read(self).left_edge().descend(); let left_len = left_node.len(); let mut right_node = ptr::read(self).right_edge().descend(); let right_len = right_node.len(); // Make sure that we may steal safely. assert!(right_len + count <= CAPACITY); assert!(left_len >= count); let new_left_len = left_len - count; // Move data. { let left_kv = left_node.reborrow_mut().into_kv_pointers_mut(); let right_kv = right_node.reborrow_mut().into_kv_pointers_mut(); let parent_kv = { let kv = self.kv_mut(); (kv.0 as *mut K, kv.1 as *mut V) }; // Make room for stolen elements in the right child. ptr::copy(right_kv.0, right_kv.0.add(count), right_len); ptr::copy(right_kv.1, right_kv.1.add(count), right_len); // Move elements from the left child to the right one. move_kv(left_kv, new_left_len + 1, right_kv, 0, count - 1); // Move parent's key/value pair to the right child. move_kv(parent_kv, 0, right_kv, count - 1, 1); // Move the left-most stolen pair to the parent. move_kv(left_kv, new_left_len, parent_kv, 0, 1); } left_node.as_leaf_mut().len -= count as u16; right_node.as_leaf_mut().len += count as u16; match (left_node.force(), right_node.force()) { (ForceResult::Internal(left), ForceResult::Internal(mut right)) => { // Make room for stolen edges. let right_edges = right.reborrow_mut().as_internal_mut().edges.as_mut_ptr(); ptr::copy(right_edges, right_edges.add(count), right_len + 1); right.correct_childrens_parent_links(count..count + right_len + 1); move_edges(left, new_left_len + 1, right, 0, count); } (ForceResult::Leaf(_), ForceResult::Leaf(_)) => {} _ => unreachable!(), } } } /// The symmetric clone of `bulk_steal_left`. pub fn bulk_steal_right(&mut self, count: usize) { unsafe { let mut left_node = ptr::read(self).left_edge().descend(); let left_len = left_node.len(); let mut right_node = ptr::read(self).right_edge().descend(); let right_len = right_node.len(); // Make sure that we may steal safely. assert!(left_len + count <= CAPACITY); assert!(right_len >= count); let new_right_len = right_len - count; // Move data. { let left_kv = left_node.reborrow_mut().into_kv_pointers_mut(); let right_kv = right_node.reborrow_mut().into_kv_pointers_mut(); let parent_kv = { let kv = self.kv_mut(); (kv.0 as *mut K, kv.1 as *mut V) }; // Move parent's key/value pair to the left child. move_kv(parent_kv, 0, left_kv, left_len, 1); // Move elements from the right child to the left one. move_kv(right_kv, 0, left_kv, left_len + 1, count - 1); // Move the right-most stolen pair to the parent. move_kv(right_kv, count - 1, parent_kv, 0, 1); // Fix right indexing ptr::copy(right_kv.0.add(count), right_kv.0, new_right_len); ptr::copy(right_kv.1.add(count), right_kv.1, new_right_len); } left_node.as_leaf_mut().len += count as u16; right_node.as_leaf_mut().len -= count as u16; match (left_node.force(), right_node.force()) { (ForceResult::Internal(left), ForceResult::Internal(mut right)) => { move_edges(right.reborrow_mut(), 0, left, left_len + 1, count); // Fix right indexing. let right_edges = right.reborrow_mut().as_internal_mut().edges.as_mut_ptr(); ptr::copy(right_edges.add(count), right_edges, new_right_len + 1); right.correct_childrens_parent_links(0..=new_right_len); } (ForceResult::Leaf(_), ForceResult::Leaf(_)) => {} _ => unreachable!(), } } } } unsafe fn move_kv( source: (*mut K, *mut V), source_offset: usize, dest: (*mut K, *mut V), dest_offset: usize, count: usize, ) { unsafe { ptr::copy_nonoverlapping(source.0.add(source_offset), dest.0.add(dest_offset), count); ptr::copy_nonoverlapping(source.1.add(source_offset), dest.1.add(dest_offset), count); } } // Source and destination must have the same height. unsafe fn move_edges( mut source: NodeRef, K, V, marker::Internal>, source_offset: usize, mut dest: NodeRef, K, V, marker::Internal>, dest_offset: usize, count: usize, ) { let source_ptr = source.as_internal().edges.as_ptr(); let dest_ptr = dest.as_internal_mut().edges.as_mut_ptr(); unsafe { ptr::copy_nonoverlapping(source_ptr.add(source_offset), dest_ptr.add(dest_offset), count); dest.correct_childrens_parent_links(dest_offset..dest_offset + count); } } impl NodeRef { /// Removes any static information asserting that this node is a `Leaf` node. pub fn forget_type(self) -> NodeRef { NodeRef { height: self.height, node: self.node, _marker: PhantomData } } } impl NodeRef { /// Removes any static information asserting that this node is an `Internal` node. pub fn forget_type(self) -> NodeRef { NodeRef { height: self.height, node: self.node, _marker: PhantomData } } } impl Handle, marker::Edge> { pub fn forget_node_type( self, ) -> Handle, marker::Edge> { unsafe { Handle::new_edge(self.node.forget_type(), self.idx) } } } impl Handle, marker::Edge> { pub fn forget_node_type( self, ) -> Handle, marker::Edge> { unsafe { Handle::new_edge(self.node.forget_type(), self.idx) } } } impl Handle, marker::KV> { pub fn forget_node_type( self, ) -> Handle, marker::KV> { unsafe { Handle::new_kv(self.node.forget_type(), self.idx) } } } impl Handle, marker::KV> { pub fn forget_node_type( self, ) -> Handle, marker::KV> { unsafe { Handle::new_kv(self.node.forget_type(), self.idx) } } } impl Handle, HandleType> { /// Checks whether the underlying node is an `Internal` node or a `Leaf` node. pub fn force( self, ) -> ForceResult< Handle, HandleType>, Handle, HandleType>, > { match self.node.force() { ForceResult::Leaf(node) => { ForceResult::Leaf(Handle { node, idx: self.idx, _marker: PhantomData }) } ForceResult::Internal(node) => { ForceResult::Internal(Handle { node, idx: self.idx, _marker: PhantomData }) } } } } impl<'a, K, V> Handle, K, V, marker::LeafOrInternal>, marker::Edge> { /// Move the suffix after `self` from one node to another one. `right` must be empty. /// The first edge of `right` remains unchanged. pub fn move_suffix( &mut self, right: &mut NodeRef, K, V, marker::LeafOrInternal>, ) { unsafe { let left_new_len = self.idx; let mut left_node = self.reborrow_mut().into_node(); let right_new_len = left_node.len() - left_new_len; let mut right_node = right.reborrow_mut(); assert!(right_node.len() == 0); assert!(left_node.height == right_node.height); if right_new_len > 0 { let left_kv = left_node.reborrow_mut().into_kv_pointers_mut(); let right_kv = right_node.reborrow_mut().into_kv_pointers_mut(); move_kv(left_kv, left_new_len, right_kv, 0, right_new_len); left_node.as_leaf_mut().len = left_new_len as u16; right_node.as_leaf_mut().len = right_new_len as u16; match (left_node.force(), right_node.force()) { (ForceResult::Internal(left), ForceResult::Internal(right)) => { move_edges(left, left_new_len + 1, right, 1, right_new_len); } (ForceResult::Leaf(_), ForceResult::Leaf(_)) => {} _ => unreachable!(), } } } } } pub enum ForceResult { Leaf(Leaf), Internal(Internal), } /// Result of insertion, when a node needed to expand beyond its capacity. /// Does not distinguish between `Leaf` and `Internal` because `Root` doesn't. pub struct SplitResult<'a, K, V> { // Altered node in existing tree with elements and edges that belong to the left of `k`. pub left: NodeRef, K, V, marker::LeafOrInternal>, // Some key and value split off, to be inserted elsewhere. pub k: K, pub v: V, // Owned, unattached, new node with elements and edges that belong to the right of `k`. pub right: Root, } pub enum InsertResult<'a, K, V, Type> { Fit(Handle, K, V, Type>, marker::KV>), Split(SplitResult<'a, K, V>), } pub mod marker { use core::marker::PhantomData; pub enum Leaf {} pub enum Internal {} pub enum LeafOrInternal {} pub enum Owned {} pub struct Immut<'a>(PhantomData<&'a ()>); pub struct Mut<'a>(PhantomData<&'a mut ()>); pub struct ValMut<'a>(PhantomData<&'a mut ()>); pub enum KV {} pub enum Edge {} } unsafe fn slice_insert(slice: &mut [T], idx: usize, val: T) { unsafe { ptr::copy(slice.as_ptr().add(idx), slice.as_mut_ptr().add(idx + 1), slice.len() - idx); ptr::write(slice.get_unchecked_mut(idx), val); } } unsafe fn slice_remove(slice: &mut [T], idx: usize) -> T { unsafe { let ret = ptr::read(slice.get_unchecked(idx)); ptr::copy(slice.as_ptr().add(idx + 1), slice.as_mut_ptr().add(idx), slice.len() - idx - 1); ret } } #[cfg(test)] mod tests;